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Manuals and User Guides for Mitsubishi Electric FR-A840-00770 (30K). We have 2 Mitsubishi Electric FR-A840-00770 (30K) manuals available for free PDF download: Instruction Manual
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- FR-A840-00310 (11K)
Manuals and User Guides for Mitsubishi Electric FR-A840-00310 (11K). We have 2 Mitsubishi Electric FR-A840-00310 (11K) manuals available for free PDF download: Instruction Manual
Summary of Content for Mitsubishi Electric A800, FR-A840M Instruction Manual PDF
800 INSTRUCTION MANUAL (STARTUP) (ENGLISH)
( )( )
HEAD OFFICE: TOKYO BUILDING 2-7-3, MARUNOUCHI, CHIYODA-KU, TOKYO 100-8310, JAPAN
IN VER
TER A
800 FR
-A 840M
IN STR
U C
TIO N
M A
N U
A L (STA
R TU
P)
A
A800 FR-A840M-03630(160K)04540(200K)
CD-ROM CD-ROM
Thank you for choosing this Mitsubishi Electric Inverter. This Instruction Manual (Startup) and the enclosed CD-ROM give handling information and precautions for use of this product. Do not use this product until you have a full knowledge of the equipment, safety information and instructions. Please forward this Instruction Manual (Startup) and the enclosed CD-ROM to the end user.
()CD-ROM , ()CD-ROM
INVERTER
Specifications subject to change without notice.
IB()-0600932-A(2008)MEE Printed in Japan
1 ……………………………………………………………………………….. 3 2 …………………………………………………………………………………………………………. 13 3 ………………………………………………………………………………………………………………… 24 4 …………………………………….. 27 5 ………………………………………………………………………………………… 27 6 ………………………………………………………………………………………………….. 32 7 ………………………………………………………………………………………………………………………. 34
()CD-ROMPDF PDF
( : )
OFF
10
CEN
M
OFF 1s OFF
PM
P/+N/-
10 40
95RH 7
20 65
4000m 0.075mm 10 57Hz 1G 57 150Hz 7
UVW
PM PM UVW PM
PMPM (UVW) PM PM (UVW)
STOP/RESET
PM
3 PM
LXX13STFSTR 0
PTC
400V
1 PM PM PM
()PMPM
PM ON
Ethernet
Ethernet
PMPM
IM PM
PM PM PM
1
1.1
Ethernet FR-A8ETH C2 EMCON
NOTE FR-A840M-200K(04540)
Ethernet CD-ROM
EMC Pr.19
FM FM FM: AM: DC010V OFF 60Hz 9999
CACA CA: DC0 20mA AM: DC010V ON 50Hz 8888 95%
FR- M -A8 04 -160K
400V 4
M
FM RS-485 Ethernet
CA FM CA
1 2 E1 E2
EMC
—
C3 C2 C260
06
06B 60B
IEC60721-3-3 3C2/3S2
160200K 0363004540
ND(kW) SLD(A)
FR-A840M-200K-E1-60BC2
Ethernet
NOTE
No. 1 2 1
3 Ethernet Ethernet 0.33Nm 0.40Nm
4 1 1 0.33Nm 0.40Nm
1
FR-A8NC
Ethernet
Ethernet
1.2
RS-485
(a) PU RS-485 10 (b) RS-485 RS-485MODBUSRTU
(c) USBA USB (d) USBB FR Configurator2 (e) EMC EMCON/OFF (f) 1
(g) 2
(h) 3
(i) /(SW2) 24
(j) 4 (k) 17 (l) 18
(m) RS-485 / 10
(n) POWER (R1/L11 S1/L21) 17
(o) ALARM
(p) (FR-DU08) 24 (q) 18 (r)
10
(s) 10
(t) 32
(q)
(s)
(p)
(a) (b)
(c)
(e)
(l)
(k)
(j)
(g)
(f)
(d)
(h)
(i)
(t)
(m)
(n)
(k)
(l)
(o)
(r)
Ethernet
(a) PU 10 (b) Ethernet Ethernet
(c) USBA USB (d) USBB FR Congurator2 (e) EMC EMCON/OFF (f) 1
(g) 3
(h) 2 Ethernet 2 2Ethernet Ethernet
(i) /(SW2) 2 4
(j) 4
(k) 17 (l) 18
(m) RS-485 / 10
(n) POWER (R1/L11 S1/L21) 17
(o) ALARM
(p) (FR-DU08) 24 (q) 18 (r)
10
(s) 10
(t) 32
(q)
(s)
(p)
(a)
(b)
(c)
(e)
(l)
(k)
(j)
(h)
(f)
(d)
(g)
(i)
(m)
(n)
(k)
(l)
(o)
(r)
(t)
1.3
1000m500m 3 12
30cm32
10 40
IEC60721-3-3 3C2/3S2 : 95RH
20 65
4000m
10 57Hz 0.075mm 57 150Hz 1G
20cm
20cm
5cm
5cm 5cm
5cm 5cm
5cm
1.4
1.4.1
NOTE
AM EMC
PM PM ON
AC
R/L1 S/L2 T/L3 N/-P/+
P/+ PR
P/+ P/+ PR
PR
U V W U
V W
IM PM
(c) (NFB) (ELB)
(e) AC (FR-HAL)
(k)
(l) (FR-BLF)
(n) DSN
(o) IPM
(f) FR-HC2
(g) (MT-RC
(i) (MT-BR5
(h) (MT-BUFR-BU2
(d) (MC)
(a) (b) 3
(j) USB
(FR Congurator 2)
USB
USB A
USB B
LED USB
(m)
1.4.2
/ NFBELBNFNV
NOTE NFB 1 NFB1 38
NFB 1
NOTE AC-1 50 25 JEM1038-AC-3 JEM1038-AC-3
NFB 1
(a) (FR-A840M)
EMC
7 13
(b) 3 34
(c) (NFB) (ELB) 9
(d) (MC)
9
(e) AC (FR-HAL)
1000kVA ACFR-HAL
31
(f) (FR-HC2) 22 (g) (MT-RC) 23 (h) (MT-BUFR-BU2)
21 i) (MT-BR5
(j) USB USB(Ver1.1) USB
(k) 21
(l) (FR-BLF)
0.5MHz 5MHz 4T
(m)
(n) DSN
PM
(o) IPM
FR-A840M-[]
SLD ND 160K(03630) 400A 350A
200K(04540) 500A 400A
FR-A840M-[]
SLD ND
160K(03630) S-N400 S-N300 200K(04540) S-N600 S-N400
NFB INV
NFB INV
M
M
1.4.3
(a) (b) R/L1S/L2T/L3P/+N/-PR
(a) (b) UVW
2
PU 0.40 0.45Nm
(a) (b)
(a) (b)
(a) (b) (c)
(a)
(b) (c)
NOTE
(a) (b) (c)
(a)
(b)
(c)
1.4.4
NOTE 2kHz
FR-A840M-[]
W) SLD ND
160K(03630) 4175 3300 200K(04540) 5300 4175
2
2.1 FMRS-485
Pr.178 Pr.189 JOGJOG/ Pr.291 Pr.73 Pr.267 /OFFON
102 PTCPr.561 2W1k P/+ PR
21 Pr.195 Pr.196 Pr.190 Pr.194 F/C(FM) Pr.291 EMCC2 EMC ONOFF C2 R1/L11S1/L21 PR
NOTE 10cm
/
3
NFB R/L1 S/L2 T/L3
PCDC24V
JOG
2
4
10E(10V)
10(5V)
2
)
2 3
1
4
1
4
1/2W1k
F/C (FM)
SD
1
C1
B1
A1
U V W
()
()
() (DC010V)
AM
5
DC05V DC010V
1mA
DC05V DC010V
MC
C2
B2
A2 2
M
DC020mA
DC05V DC010V DC420mA
TXD+
TXD-
RXD+ RXD- GND (SG)
GND
RS-485
PU
USB A
USB B
S IN K
S O U R C E
STF
STR
STP(STOP)
RH
RM
RL
JOG
RT
MRS
RES
AU
CS
SD
RUN
SU
IPF
OL
FU
SE
(+) (-)
5
EMC
ON
OFF
VCC
(+) (-)
5V 100mA
1 2 3
N/-P/+
ON OFF
42
/
So (SO)
SOC
(1)
(2)
S1
S2
PC
SD SIC
+2424V
SD
R/L11 S/L21
24V
24V
R/L1 S/L2 T/L3
U V W
N/-P/+
PR
R
CARS-485
Pr.178 Pr.189 JOGJOG/ Pr.291 Pr.73 Pr.267 /OFFON
102 PTCPr.561 2W1k P/+ PR
21 Pr.195 Pr.196 Pr.190 Pr.194 EMCC2 EMC ONOFF C2 R1/L11S1/L21 PR
NOTE 10cm
/
1
C1
B1
A1
C2
B2
A2 2
S IN K
S O U R C E
STF
RUN
SU
IPF
OL
FU
SE
()
() (DC010V)
()
() (DC020mA)
AM
5
So (SO)
SOC
10E(10V)
10(5V)
2
)
2 3
1
4
1
4
1/2W1k
DC05V DC010V
DC05V DC010V DC020mA
DC05V DC010V DC420mA
(+) (-)
5
(+) (-)
1 2 3
/
PU
USB A
USB B
TXD+
TXD-
RXD+ RXD-
GND
RS-485
VCC 5V 100mA
(1)
(2)
S1
S2
PC
SD SIC
PC DC24V
JOG
2
4
STR
STP(STOP)
RH
RM
RL
JOG
RT
MRS
RES
AU
CS
SD
+2424V
SD
F/C (CA)
GND (SG)
24V
24V
ON OFF
42
3
NFB R/L1 S/L2 T/L3
U V W
MC
M
EMC
ON
OFF
N/-P/+
R/L11 S/L21
R/L1 S/L2 T/L3
U V W
N/-P/+
PR
R
FMEthernet
Pr.178 Pr.189 JOGJOG/ Pr.291 Pr.73 Pr.267 /OFFON
102 PTCPr.561 2W1k P/+ PR
21 Pr.195 Pr.196 Pr.190 Pr.194 F/C(FM) Pr.291 EMCC2 EMC ONOFF C2 Ethernet 2 2
Ethernet Ethernet R1/L11S1/L21 PR
NOTE 10cm
/
PCDC24V
JOG
2
4
10E(10V)
10(5V)
2
)
2 3
1
4
1
4
1/2W1k
F/C (FM)
SD
1
C1
B1
A1
()
()
() (DC010V)
AM
5
DC05V DC010V
1mA
DC05V DC010V
C2
B2
A2 2
DC020mA
DC05V DC010V DC420mA
PU
USB A
USB B
S IN K
S O U R C E
STF
STR
STP(STOP)
RH
RM
RL
JOG
RT
MRS
RES
AU
CS
SD
RUN
SU
IPF
OL
FU
SE
(+) (-)
5
(+) (-)
1 2 3
ON OFF
42
/
So (SO)
SOC
(1)
(2)
S1
S2
PC
SD SIC
+2424V
SD
Ethernet
24V
24V
3
NFB R/L1 S/L2 T/L3
U V W
MC
M
EMC
ON
OFF
N/-P/+
R/L11 S/L21
R/L1 S/L2 T/L3
U V W
N/-P/+
PR
R
CAEthernet
Pr.178 Pr.189 JOGJOG/ Pr.291 Pr.73 Pr.267 /OFFON
102 PTCPr.561 2W1k P/+ PR
21 Pr.195 Pr.196 Pr.190 Pr.194 EMCC2 EMC ONOFF C2 Ethernet 2 2
Ethernet Ethernet R1/L11S1/L21 PR
NOTE 10cm
/
1
C1
B1
A1
C2
B2
A2 2
S IN K
S O U R C E
STF
RUN
SU
IPF
OL
FU
SE
()
() (DC010V)
()
() (DC020mA)
AM
5
So (SO)
SOC
10E(10V)
10(5V)
2
)
2 3
1
4
1
4
1/2W1k
DC05V DC010V
DC05V DC010V DC020mA
DC05V DC010V DC420mA
(+) (-)
5
(+) (-)
1 2 3
/
PU
USB A
USB B
Ethernet
(1)
(2)
S1
S2
PC
SD SIC
PC DC24V
JOG
2
4
STR
STP(STOP)
RH
RM
RL
JOG
RT
MRS
RES
AU
CS
SD
+2424V
SD
F/C (CA)
24V
24V
ON OFF
42
3
NFB R/L1 S/L2 T/L3
U V W
MC
M
EMC
ON
OFF
N/-P/+
R/L11 S/L21
R/L1 S/L2 T/L3
U V W
N/-P/+
PR
R
2.2
2.2.1
PR
C2 C2
R/L1 S/L2 T/L3 N/- P/+ PR
U V W
M
U V W
R/L1 S/L2 T/L3
N/- P/+ PR R/L1 S/L2 T/L3
N/- P/+
M
PR
2.2.2 (1) 1010 (2)
(3)
(4)
(5) 2
(6) 1010
2.2.3 2 20m
ND
SLD
90LMFC 50
90THHN 40 39
90XLPE 40 R/L1S/L2T/L3UVWPRP/+N/-
PR
[V] [m/m] [m] [A] 1000
NOTE
1 100m
400V
400V Pr.72 PWM
MT-BSLMT-BSC
PM PM 100 PM 1 1 PM
NOTE Pr.156 FR-A800
MT-BSL/BSCV/F Pr.72 PWM FR-A800 400V FR-A800
FR-A840M-[]
Nm
HIV mm2 AWG/MCM PVCmm2 R/L1 S/L2 T/L3
U V W R/L1 S/L2 T/L3
UVW P/+ P1
R/L1 S/L2 T/L3
UVW R/L1 S/L2 T/L3
UVW
160K(03630) M12 M10 14.7 100-12 100-12 100 100 150 38 4/0 4/0 95 95 50
200K(04540) M12 M10 14.7 100-12 100-12 100 100 150 38 4/0 4/0 95 95 70
FR-A840M-[]
Nm
HIV mm2 AWG/MCM PVCmm2 R/L1 S/L2 T/L3
U V W R/L1 S/L2 T/L3
UVW P/+ P1
R/L1 S/L2 T/L3
UVW R/L1 S/L2 T/L3
UVW
160K(03630) M12M10 14.7 100-12 100-12 100 100 150 38 4/0 4/0 95 95 50
200K(04540) M12 M10 14.7 150-12 100-12 150 150 200 38 300 300 150 150 95
Pr.72 FR-A840M-160K(03630) FR-A840M-200K(04540)
22kHz 500m 500m
33kHz 500m 500m
100 44kHz
2.3
0.3 0.75 2 30m FM200m 2
200V PC
(A1 B1 C1A2 B2 C2) SD 0V
2019 4
MTW A1B1C1A2B2C2
mm2
UL
0.3 AI 0,34-10TQ
CRIMPFOX 6 052-589-3810
0.5 AI 0,5-10WH AI 0,5-10WH-GB
0.75 AI 0,75-10GY A 0,75-10 AI 0,75-10GY-GB
1 AI 1-10RD A 1-10 AI 1-10RD/1000GB
1.251.5 AI 1,5-10BK A 1,5-10 AI 1,5-10BK/1000GB
0.752 AI-TWIN 20,75-10GY
mm2
0.3 0.75 BT 0.75-11 VC 0.75 NH 69 052-857-2722
2.4
2.4.1 P/+ PR ( P/+ PR (17 )
Pr.30 1112110111112126 Pr.70
2.4.2 FR-BU2 (FR-BU2(H) Pr.30 1Pr.70 0 FR-BU2 Pr.0 2
(P/+N/-)(FR-BU2)
(FR-BU2) (MT-BR5)5m10m
TH1 TH2TH1 TH2 MT-BU5CN8
NOTE Pr.30 1Pr.70 0%FR-A800 oL
kW FR-A840M-160K(03630) 3.85 160
FR-A840M-200K(04540) 3 200
Pr.30Pr.70
MC
MC
R
PR
P/+
(OCR)
S/L2 T/L3
R/L1
ON OFF OCR
F T
<1>
MC
MC
T
R
PR
P/+
(OCR)
S/L2 T/L3
R/L1
ON OFF B
C OCR
F
<2> MC
MC
MC R/L1
M
S/L2 T/L3
U V
P/+ N/- P
PR
10m
W 3
NFB
TH1
TH2
MC
CR1
OFFON
MC
CR1
T 2
31
3
5
4
P N BUE SD
P PR A B C
FR-BU2
MT-BR5
2.4.3 FR-HC2 (FR-HC2) Pr.19 V/F Pr.83 V/F Pr.30 2 102 FR-A800
R/L1-R1/L11 S/L2-S1/L21 R1/L11 S1/L21 R/L1 S/L2 T/L3 E.OPT
P/+ N/- P P/+ NN/- NFB N/-P/+ X10 (X11) Pr.178 Pr.189
RS-485 1 X11 IPF FR-HC2 (FR-HC2 ) FR-HC2 RDY X10 MRS FR-HC2 SE SD
FR-HC2 FR-HC2 R/L1S/L2T/L3 FR-HC2 1 R/L1S/L2T/L3 FR-HC2 R4/L14S4/L24T4/L34 NFBMC
(FR-HC2 ) FR-HC2-H280K (FR-HC2
)
NOTE R/L1 S/L2 T/L3 R4/L14 S4/L24 T4/L34 / FR-A800
ROH2 ROH1
FR-HCB2
(FR-HC2)2
(FR-HCL22)
M
1 (FR-HCL21)
P/+P/+ N/-N/-
R1/L11 S1/L21
X10 X11
SD
RDY
RSO SE
R/L1
S/L2 T/L3
U V W
R1/L11 S1/L21
88R88R 88S88S
ROH SD
NFB MC R4/ L14 R4/L14 S4/ L24 S4/L24 T4/ L34 T4/L34
R3/ L13 R3/
L13 S3/ L23
S3/ L23
T3/ L33
T3/ L33
R2/ L12
R2/ L12
S2/ L22
S2/ L22
T2/ L32
T2/ L32
R/ L1 S/ L2 T/ L3
R/L1 S/L2 T/L3
RES IPF
*3
*5 *3
*2
*4
*8
*8
*7*7
*6
*8 *8
*7
*10
*7
*9
*1
*8
*2
2.4.4 MT-RC MT-RC Pr.30 1 Pr.70 0
NOTE MT-RC (MC) MT-RC 1s MT-RCMT-RC NFB
MT-RC
R/L1 S/L2 T/L3 R1/L11 S1/L21
R R2 RES
U V W
MT-RCL
P/+ N/-
P N
RDY
SE
MT-RC
3
NFB MC2MC1
M
STF SD
S
T
S2
T2
R2
S2
T2
R
S
T
R1
S1
C
B A
MT-RC(MC1)
(MC2) ON
ON
1s
3
3.1 (FR-DU08)
No.
(a) M
Pr.992
(b) MODE
[PU/EXT] 2sPr.1610
(c) SET Pr.52Pr.774 Pr.776
(d) ESC
(e) PU/EXT
PUPUJOG [MODE] PU
(a)
(b) (c) (d)
(e)
3.1.1
USBUSBUSB
/
PU PUJOG
()
8 .
()
() () ()
IPM
1 2 8
3.2 FR-A800
Pr.30
FR-A800
Pr.570
Pr.260 PWM PWM 3kHz Pr.72 3
FR-A800
FR-A800 15ms
NOTE FR-A800 FR-A800
Pr.30 Pr.70
RST 0100
PN 10110
RST/PN 20120
FR-BU2MT-BR5
RST 1101
0%PN 11111
RST/PN 21121
RST 1101
0PN 11111
RST/PN 21121
MT-RC RST 1101 0
FR-HC2 PN 2102
Pr.
570 2
0 SLD 110% 60s120 3s 40
2 ND 150% 60s200 3s 40
Pr.260 Pr.570
1 0(SLD) 50%
2(ND) 50%
0 0(SLD) 50%
2(ND) 2kHz 50%
E.IPF FR-LU08
10ms 100ms ON(10ms ) ( ) IPF
Pr.57FR-A800
4 (ALM)
RUN CPU RUN OFF
5 FR-A800
(U V W)
2 19
2
AM EMCEMCON 3
EMCON EMCOFF EMCON/OFF
FT-3KM F
ALM 5
RY 5
STF STR RUN 5
STF STR Y12 5
10 P/+ N/-
EV24VOFF
100 STFSTRON/OFF13
P/+ PR
10E 5
ON
PLGPLG PLG
(MC) MC2 JEM1038-AC-3
OFF ON MCMC PM
( ) ( ) ( : ZCAT3035-1330TDK )
2PM PM
MC1 MC2 SF-THYPM
MC2
MC1
U V W
R/L1 S/L2 T/L3
IM
5.1
5.1.1
NOTE
40 50 3kHz 10kHz 1GHz
FR-A840M DC
AC (FR-HAL)
NFB MC
R
S
T Z
Y
X U
V
W
R/L1
S/L2
T/L3
M
5.1.2 3 200V 3.7kW 2004 12004 9 6
1kW
5 7 11 13 17 19 23 23 6.6kV 3.5 2.5 1.6 1.3 1.0 0.9 0.76 0.70 22kV 1.8 1.3 0.82 0.69 0.53 0.47 0.39 0.36 33kV 1.2 0.86 0.55 0.46 0.35 0.32 0.26 0.24
Ki
3 ( )
K33=1.8 K34=1.4
5 K5=0
6.6kV 50kVA 22/33kV 300kVA 66kV 2000kVA
100%
P0 6 30
30 31
1kW
5 7 11 13 17 19 23 25 30 13 8.4 5.0 4.7 3.2 3.0 2.2 28 9.1 7.2 4.1 3.2 2.4 1.6 1.4
P0 KiPi[kVA]
Ki30 Pi [kVA] i
kW
(A) 6.6kV (mA)
(kVA)
6.6kV (mA) DC 100
200V 400V 5 7 11 13 17 19 23 25 75 245 123 7455 87.2 2237 969 626 373 350 239 224 164 90 293 147 8909 104 2673 1158 748 445 419 285 267 196 110 357 179 10848 127 3254 1410 911 542 510 347 325 239 132 216 13091 153 3927 1702 1100 655 615 419 393 288 160 258 15636 183 4691 2033 1313 782 735 500 469 344 220 355 21515 252 6455 2797 1807 1076 1011 688 645 473 250 403 24424 286 7327 3175 2052 1221 1148 782 733 537 280 450 27273 319 8182 3545 2291 1364 1282 873 818 600 315 506 30667 359 9200 3987 2576 1533 1441 981 920 675 355 571 34606 405 10382 4499 2907 1730 1627 1107 1038 761 400 643 38970 456 11691 5066 3274 1949 1832 1247 1169 857 450 723 43818 512 13146 5696 3681 2191 2060 1402 1315 964 500 804 48727 570 14618 6335 4093 2436 2290 1559 1462 1072 560 900 54545 638 16364 7091 4582 2727 2564 1746 1636 1200 630 1013 61394 718 18418 7981 5157 3070 2886 1965 1842 1351
No.
1 FR-HAL
DCAC (FR- HAL)
2 (FR-HC2)
(FR-HC2)
3
4 2 — — 3012
5 (AC )
6 ( )
6
6.1
NOTE 10 P/+ N/-
25cm
6.1.1 1)10 2)
3)
4) 0.730.1Nm
6.1.2 1)AIR FLOW
2)
NOTE
AIR FLOW
7
7.1
4 440V 100
ED Pr.70 21 ND FR-DU08: IP40PU 480VPr.977 1m 1.6m
FR-A840M-[] 160K 200K
03630 04540
(kW) SLD 200 250
ND 160 200
(kVA) SLD 200 250
ND 160 200
(A) SLD 363 454
ND 293 363
SLD 110% 60s 120% 3s ( ) 40
ND 150% 60s 200% 3s ( ) 40
3 380 500V
100
3 380 500V 50Hz/60Hz
323 550V 50Hz/60Hz
5%
(A) SLD 363 454
ND 293 363
(kVA) SLD 277 346
ND 223 277
(IEC 60529) IP20IP55
(dB) 73.4 73.4
(kg) 148 148
7.2 FR-A840M-160K03630FR-A840M-200K04540
4-12M10 4-24
408
25 6
45 (45) (1 5)
12 20
12 50
(1 5)
450
(1
12 14
18
3.2 22
5-42
36 0
85
mm
48
5-42
300 390
1 FR-A840
1000m500 3
FR-A840M FR-A840
10 40 10 50LDNDHD 10 40SLD
4000m 2500m
10 57Hz 0.075mm 57 150Hz 1G
2.9m/s2 10 55HzXYZ FR-A840- 160K(04320)
IP20IP55 (IP00)FR-A840-30K(00770)
FR-A840-0.4K(00023) 55K(03160)
EMC C3C2 C3
DC
dB 73.4 61.2FR-A840-185K(04810)
PWM
Pr.260 PWM 50
85
Pr.570
SLDND 02
SLDLDNDHD 0 3
E.IPF
10ms
15ms
2 EUEU 1996 EMC1997 EMCCE EU EU : Mitsubishi Electric Europe B.V. : Mitsubishi-Electric-Platz 1, 40882 Ratingen, Germany
EMCCE
EMC EMCCE EMC : 2014/30/EU : EN61800-3:2004+A1:2012 (First environment / PDS Category «C2», Second environment / PDS Category «C3»)
: First environment Second environment
EMC C3 EMCEMC EMC Installation ManualBCN-A21041-204 EMC 20m EMC C2EMC16AEN/IEC61000-3-2 1kW EN/IEC61000-3-2 16A 75A Ssc EN/IEC61000-3-12 Ssc 75A 100kVAIEC61000-3-4 Rsce
IEC61000-3-4
Ssc Rsce FR-A840M-03630160K
IEC61000-3-4 350 FR-A840M-04540200K
EN 61800-5-1CE
1 2 17 : 40
EN60204 17 PVC
EN IEC RCDRCM) B RCD RCM
IEC60664 II III 2 2IP2X 3IP54
EN60204 A1 B1 C1 A2 B2 C2DC30V 0.3A( )
13 3
1000m500m 3
100kA rms 500V
Pr.9
NOTE
1 (OCR)
10 40 20 65 20 65 95RH 95RH 95RH
4000m 4000m 10000m
FR-A840M-03630160K UL recognized semi-conductor fuse 170M6112 Bussmann 700V800A FR-A840M-04540200K UL recognized semi-conductor fuse 170M6114 Bussmann 700V1000A
Pr.9 50
150%
230
52.5 105
50 100 150
60
120
180
240
50
60
70
m in
m in
Pr. 9= 501, 2
Pr. 9= 1002
s
s
OFF (Pr.90(A)
6Hz
20Hz 10Hz 6Hz 0.5Hz
30Hz330Hz 3
20Hz 10Hz
0.5Hz
4
3 UL cUL UL61800-5-1, CSA C22.2No274-13
— — 10 10 P/+ N/-
7
A1 B1 C1 A2 B2 C2DC30V 0.3A ( )
National Electrical Code(Article 310) National Electrical Code(Article 430) 125% (R/L1 S/L2 T/L3) (U V W) UL 75
100kA rms 500V
Pr.9
NOTE
1 (OCR)
SF-V5RUPr.9 =0
FR-A840M-03630160K UL recognized semi-conductor fuse 170M6112 Bussmann 700V800A FR-A840M-04540200K UL recognized semi-conductor fuse 170M6114 Bussmann 700V1000A
(1) Pr.71 113 16505354
100 (2) Pr.9
Pr.9 50
6Hz
150%
230
52.5 105
50 100 150
60
120
180
240
50
60
70
m in
m in
Pr. 9= 501, 2
Pr. 9= 1002
s
s
OFF (Pr.90(A)
6Hz
20Hz 10Hz 6Hz 0.5Hz
30Hz330Hz 3
20Hz 10Hz
0.5Hz
4
4 EAC
EACEAC
EAC 2010 3 3CU-TRCustom-Union Technical RegulationEAC
CU
3 MADE IN JAPAN
3 SERIAL
CU CU Mitsubishi Electric (Russia) LLC 52, bld 1 Kosmodamianskaya Nab 115054, Moscow, Russia +7 (495) 721-2070 FAX +7 (495) 721-2071
SERIAL( )
SERIAL 1 2 6 11 9X10 Y11 Z12
5
SJ/T11364 GB/T26572 GB/T26572
(Pb)
(Hg)
(Cd)
(Cr(VI))
(PBB)
(PBDE)
6
GB/T 16855.1 GB/T 12668.502 GB 28526 GB/T 12668.3
GB/T 12668.501 EMC GB/T 12668.3
43
12 618
(1)
(2)
(3)
(1) 7
(2)
FAFA
(1) (2) (3) (4)
(1)
(2)
44
CD-ROM CD-ROM PDF
CD-ROM CD-ROM CD-ROM CD-ROM CD-ROM MicrosoftWindowsWindows Vista Internet Explorer Microsoft Corporation Adobe Adobe Reader Adobe Systems Incorporated Intel Pentium Intel Corporation
CD-ROM
NOTE CD-ROM
CD-ROM CD-ROM
CD-ROM 1. CD-ROM CD-ROM 2. 3. 4. 5. PDF
CD-ROM 1. CD-ROM CD-ROM 2. CD-ROMindex.html 3. 3
PDF CD-ROMMANUAL
OS Microsoft Windows 10Windows 8.1Windows 8Windows 7Windows Vista
CPU Intel Pentium
128MB RAM
90MB
CD-ROM 24
800×600
Adobe Reader 7.0 Internet Explorer 6.0
45
FR-A800 ()
()CD-ROMPDF FAPDF www.MitsubishiElectric.co.jp/fa FAX
2
1
1
FR-A800() (IB()-0600502)
2
MEE
FAX(FAX)
050-3737-0441
46
()FAX 050-3737-0441 FAX
2020 8 IB( )-0600932-A
1 BCN-C22005-957
FR-A800/FR-A800 Plus
1
IP55
*1 IP55 *2 Pr.524Pr.523 *3 Pr.523 100200300400 Pr.524
Pr. FM CA
523 H320*1
9999
100111112121 122123124 200211212221 222223224 300311312321 322323324 400411412421 422423424
9999
524 H321*1*2
9999
0 590Hz*3 Pr.523
0 100%*3 PID PID Pr.523 PID
9999*3
515 H322*1
1
1 200
9999*3
1013 H323*1
60Hz 50Hz 0 590Hz E.CPUE.1 E.3E.5 E.7
514 H324*1
9999 0.1 600s
9999 Pr.68 136 A001
MC 1s 0 100s MC2 MC3
139 A004
9999 0 60Hz
88889999
57 A702 9999
0
0.1 30s
9999
V/F PM
BCN-C22005-957_JPN.fm 1
2 BCN-C22005-957
*1 Pr.190 Pr.196 ( )
*2 DC ACFR-A8AR
*3 Pr.180 Pr.189 ( ) *4 Pr.190 Pr.196 ( )
NOTE MC2MC3
(RUNSUIPFOLFU) DC24V 0.1A
(A1-C1B1-C1A2-B2B2-C2) FR-A8AR)
AC230V 0.3A DC30V 0.3A
IM R/L1 S/L2 T/L3
X84
CS
RES SD
U V W
Y65
MC2
SE
*1
*1
*2
MC3
MC2 DC24V
MC3
NFB
MC2
MC3
MC2
MC3
ALM3 *4 *4
*3
BCN-C22005-957_JPN.fm 2
3 BCN-C22005-957
X84 3s ON Y65 ON ED ALM3 ON
X84 3s ON
Pr.523 2[][]3[][] X84 OFF OFF X51 ON
24V R1S1 12
X84 Pr.178 Pr.189 84
Y65 Pr.190 Pr.196 65165 ALM3 Pr.190 Pr.196 66166
X84 Pr.338Pr.339
Pr.502 0 E.SER
Pr.5239999 Pr.5249999Pr.523100200300400
Pr.80091020109110Pr.4511020110 9999 V/F PM PM
FR-A8NS R1,S1 Pr.30=2102
BCN-C22005-957_JPN.fm 3
4 BCN-C22005-957
Pr.523 211
(CS ) Pr.523 411
*1 CS
NOTE FR-A800-CRNB,B3
E.PUE
RES
X84
STF
ALM3
Pr.514
Y65
ALM
Pr.524
3s
ON
ON
ON
ON
ON
ON
ON
3s
STF
X84
CS*1
MC3
MC2
MC3
MC2
Pr.136
Y65
MC
MC
ON
ON
ON
ON
ON
ON
ON
ON
ON
ON
BCN-C22005-957_JPN.fm 4
5 BCN-C22005-957
Pr.523Pr.524 Pr.523 100 1 10
*1 PM
NOTE PID PU /PU
Pr.515Pr.514 Pr.515 Pr514
ALMPr.67
7
NOTE Pr.65
Pr.523 1[][]
2[][]
3[][]*1
Pr.515 9999 200
4[][]*1
[]00
[]11
Pr.524 []12
[]21
PID
Pr.524 PID Pr.128[]22
[]23 2PID Pr.524 PID
Pr.753 []24
2PID
9999
BCN-C22005-957_JPN.fm 5
6 BCN-C22005-957
Pr.136Pr.139Pr.57 Pr.523 3[][]4[][] Pr.136 MC Pr.139 MC2MC3 CS Pr.57 9999 CS ON CS CS V/F PM
CS OFF Pr.523=3[][] Pr.523=4[][]
Pr.139
Pr.523 3[][]4[][]
MC2MC3 Pr.190 Pr.196 ( ) 18 19
MC2MC3
*1 CS Pr.162=0 310 13 Pr.338=1 *2 ON *3 OFF *4 MC
NOTE Pr.135=1
MC2 MC3
MC *4 MC2 MC3
CS*1 ON OFF *2
X84
ON OFF *3
RES ON OFF
MC ON OFF
MC2-OFFMC3-ON MC2-ONMC3-OFF
ONOFF
BCN-C22005-957_JPN.fm 6
7 BCN-C22005-957
PID PID Pr.524 PID Pr.128 Pr.753
PID PID PID
PID Pr.523 22[]32[] E.CPUE.1E.3E.5E.7PID Pr.1013
*1 2
*2 Pr.523 200300 OFF
PID / PID
Pr.128Pr.753 4 4 /Pr.128Pr.753 Pr.129Pr.756 100 Pr.130Pr.757 1s Pr.134Pr.758 / Pr.128 Pr.753
PID
E.OC1 E.OP3 E.ECA E.OC2 E.16 E.MB1 E.OC3 E.17 E.MB2 E.OV1 E.18 E.MB3 E.OV2 E.19 E.MB4 E.OV3 E.20 E.MB5 E.THT E.PE E.MB6 E.THM E.PUE E.MB7 E.FIN E.RET E.EP E.IPF E.PE2 E.MP E.UVT E.CPU E.EF E.ILF E.CTE E.IAH E.OLT E.P24 E.LCI E.SOT E.CDO E.PCH E.LUP E.IOH E.PID E.LDN E.SER E.1 *2
E.BE *1 E.AIE E.2 *2
E.GF E.USB E.3 *2
E.LF E.SAF *1 E.5 *2 E.OHT E.PBT *1 E.6 *1*2 E.PTC E.OS E.7 *1*2 E.OPT E.OSD E.11 E.OP1 E.ECT E.13 E.OP2 E.OD
BCN-C22005-957_JPN.fm 7
8 BCN-C22005-957
PID
PID
*1 FR-A800-LC
Pr.52Pr.774 Pr.776Pr.992 68
*1 1 *2 7
Pr.190 Pr.196
ALM 99 199 ON
ALM3 66 166 3s ON OFF
PID
OHX31*1X32X41*1TRGTRCX51RES X70X71
OHX31*1X32X41*1TRGTRCX51RES X70X71
RTX9X17X18MCSQX84 RTX9X17X18MCSQX64X65X66 X67X79X84
ON X14X77X78X80
0
1
2
3 *2 4 5 11
12
13 *2 14 15 2[]*1 3[]*1 4[]*1
BCN-C22005-957_JPN.fm 8
9 BCN-C22005-957
2 Y30Y31 Y30Y31 PLG PLGY30Y31
NOTE Y30 Y31
BCN-C22005-957_JPN.fm 9
1 BCN-C22005-969
FR-A800 /FR-A800Plus
1 (E.PE6) E.PE6) Pr.890 7
*1 FR Congurator2
NOTE E.PE6 E.PE6 3(Y91) E.PE6 (SAFE) OFF E.PE6 (X51) E.PE6 E.PE6 172(HAC)
E.PE6 Pr.890
Pr.890 Pr.890No. No. 7No.1~3
E.PE6 FR-LU08
*1
E.PE6 Pr.8907
E.PE6 OFF/ON
Pr. 890 H325 0 (0 9999)
No.
1 1357 Ethernet
2 2367 3 4567 4 89999
Pr.890 Pr.890
BCN-C22005-969_JPN.fm 1
2 BCN-C22005-969
2 P3200V/400V P3
P3
P3PR FR-A820-15K(00770)22K(01250) FR-A840-18.5K(00470)55K(01800)
P3PR
P/+N/-
FR-BU2FR-BUBU (FR-CV)(MT-RC)(FR-HC2) (FR-XC) FR-A820-15K(00770)22K(01250)FR-A840-18.5K(00470) 55K(01800)FR-CVFR-HC2FR-XC P/+P3 P/+P3 P3N/- P/+N/-
P3N/- FR-A820-15K(00770)22K(01250) FR-A840-18.5K(00470)55K(01800)
P3PR FR-A820-15K(00770)22K(01250) FR-A840-18.5K(00470)55K(01800)
P3PR
P/+N/- FR-BU2FR-BUBU (FR-CV)(MT-RC)(FR-HC2) (FR-XC)
P1
R
P3 PR N/-P/+
DC FR-HEL
FR-A820-15K(00770)22K(01250) FR-A840-18.5K(00470)55K(01800)
P1
R
P3 PR N/-P/+
DC FR-HEL
FR-A820-15K(00770)22K(01250) FR-A840-18.5K(00470)55K(01800)
BCN-C22005-969_JPN.fm 2
3 BCN-C22005-969
FR-BU2FR-BUBU (FR-CV) (MT-RC) (FR-HC2) (FR-XC) P/+ P3 FR-BU2GRZG
U V W
P/+ N/-
R/L1 S/L2 T/L3
M
PR
N/- BUE SD
P/+ A B C
FR-BU2
GRZG
RR
3
NFB MC
OFFON
MC T
10m
OCR
MC
OCR
PR PX
FR-BU2GRZG
BCN-C22005-969_JPN.fm 3
24365
FA
24
2
983-0013 1-5-35 (022)353-7814
(052)719-4337
(022)353-7834
004-0041 2-1-18 (011)890-7515 (011)890-7516
108-0022 3-9-15 (03)3454-5521 (03)5440-7783
224-0053 3963-1 (045)938-5420 (045)935-0066
338-0822 2-21-10 (048)859-7521 (048)858-5601
950-0087 2-4-10 (025)241-7261 (025)241-7262
461-8675 5-1-14 (052)722-7601 (052)719-1270
422-8058 877-2 (054)287-8866 (054)287-8484
920-0811 255 (076)252-9519 (076)252-5458
531-0076 1-4-13 (06)6458-9728 (06)6458-6911
612-8444 8 (075)611-6211 (075)611-6330
670-0996 2-234-1 (079)269-8845 (079)294-4141
732-0802 4-3-26 (082)285-2111 (082)285-7773
700-0951 606-8 (086)242-1900 (086)242-5300
760-0072 1-9-38 (087)831-3186 (087)833-1240
812-0007 3-12-16 (092)483-8208 (092)483-8228
1 (052)719-4333
1 : 9:0019:00: 9:0017:30 2 : 19:00 9:00: 24
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1213 14
15 16
1
2
3
9
5
4
6
7 810
11
2
1
3
4
5
6
7
8
9
10
11
12
13
14
15
16
FA
FA FA
FA
FA FA
FA
FA FA
FA FA FA
FA FA
FA
FA
FA FA
FA FA
FA FA
FA
FA
FA
FA FA
FA FA
FA
FA
1 9:0019:00 9:0017:00
1: 2: 3: 17:00 4: 9:00 17:00 9:00 16:30 5: 9:00 17:00
FAX6 9:0016:00
FA 6: 7: 9:00 17:00 9:00 16:30
1008310 2-7-3() …… 110-0016 1-30-7() ……………………………………………………………(03)5812-1420 …………… 060-8693 4-1()………………………………………………………………………………(011)212-3793 ……………….. 980-0013 1-1-20()…………………………………………………………………….(022)216-4546 ……………….. 330-6034 11-2()……………………………….(048)600-5845 ……………….. 950-8504 1-4-1()…………………………………………………………………………..(025)241-7227 …………… 220-8118 2-2-1( ) …………………………………………….(045)224-2623 ……………….. 920-0031 3-1-1() ………………………………………………………………………………………(076)233-5502 ……………….. 450-6423 3-28-12()………………………………………………………….(052)565-3323 ……………….. 471-0034 1-5-10() ………………………………………………………………………………..(0565)34-4112 ……………….. 530-8206 4-20( A)…………………………………………………..(06)6486-4119 ……………….. 730-8657 7-32() ……………………………………………………………………………(082)248-5345 ……………….. 760-8654 1-1-8()…………………………………………………………………………..(087)825-0072 ……………….. 810-8686 2-12-1()…………………………………………………………………………………….(092)721-2236
FA, FAX
052-712-2444
PC MELIPCMI5000/2000/1000 052-712-23702Edgecross MTConnect
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/ / / / /
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INSTRUCTION MANUAL (STARTUP) (ENGLISH) CONTENTS
1 INVERTER INSTALLATION AND PRECAUTIONS ……………………………………………… 3 2 WIRING…………………………………………………………………………………………………………. 14 3 BASIC OPERATION ………………………………………………………………………………………. 25 4 FAILSAFE SYSTEM WHICH USES THE INVERTER …………………………………………. 28 5 PRECAUTIONS FOR USE OF THE INVERTER ………………………………………………… 28 6 REPLACEMENT OF PARTS …………………………………………………………………………… 33 7 SPECIFICATIONS………………………………………………………………………………………….. 35
This Instruction Manual provides handling information and precautions for use of this product. Please forward this Instruction Manual to the end user.
Electric shock prevention
Fire prevention
Injury prevention
Additional instructions The following instructions must be also followed. If this product is handled incorrectly, it may cause unexpected fault, an injury, or an electric shock.
Safety instructions Do not attempt to install, operate, maintain or inspect this product until you have read through this Instruction Manual and supplementary documents carefully and can use the equipment correctly. Do not use this product until you have a full knowledge of this product mechanism, safety information and instructions. Installation, operation, maintenance and inspection must be performed by qualified personnel. Here, qualified personnel means personnel who meets all the following conditions. A person who took a proper engineering training. Such training may be available at your local Mitsubishi Electric office. Contact your local sales office for schedules and locations.
A person who can access operating manuals for the protective devices (e.g. light curtain) connected to the safety control system. A person who has read and familiarized themselves with the manuals.
In this Instruction Manual, the safety instruction levels are classified into «WARNING» and «CAUTION»
Incorrect handling may cause hazardous conditions, resulting in death or severe injury. Incorrect handling may cause hazardous conditions, resulting in medium or slight injury, or may cause only material damage.
Note that even the level may lead to a serious consequence depending on conditions. Be sure to follow the instructions of both levels as they are critical to personnel safety.
WARNING Do not remove the front cover or the wiring cover while the power of this
product is ON. Do not operate this product with any cover or wiring cover removed, as accidental contact with exposed high-voltage terminals and internal components may occur, resulting in an electrical shock.
Even if power is OFF, do not remove the front cover except for wiring or periodic inspection as you may accidentally touch the charged circuits of this product and get an electric shock.
Before wiring or inspection, check that the display of the operation panel is OFF. Any person who is involved in wiring or inspection shall wait for 10 minutes or longer after power OFF and check that there are no residual voltage using a tester or the like. The capacitor is charged with high voltage for some time after power OFF, and it is dangerous.
This inverter must be earthed (grounded). Earthing (grounding) must conform to the requirements of national and local safety regulations and electrical code (NEC section 250, IEC 536 class 1 and other applicable standards). A neutral-point earthed (grounded) power supply in compliance with EN standard must be used.
Any person who is involved in wiring or inspection of this product shall be fully competent to do the work.
This product must be installed before wiring. Otherwise you may get an electric shock or be injured.
Do not touch the setting dial or keys with wet hands. Doing so may cause an electric shock.
Do not subject the cables to scratches, excessive stress, heavy loads or pinching. Doing so may cause an electric shock.
Do not change the cooling fan while power is ON as it is dangerous to change the cooling fan while power is ON.
Do not touch the printed circuit board or handle the cables with wet hands. Doing so may cause an electric shock.
WARNING
CAUTION
CAUTION
WARNING Never touch the motor terminals, etc. right after powering OFF as the DC
voltage is applied to the motor for 1 second at powering OFF if the main circuit capacitor capacity is measured. Doing so may cause an electric shock.
Before wiring or inspection for a PM motor, confirm that the PM motor is stopped as a PM motor is a synchronous motor with high-performance magnets embedded inside and high-voltage is generated at the motor terminals while the motor is running even after the power of this product is turned OFF. In an application, such as fan and blower, that the motor may be driven by the load, connect a low-voltage manual contactor at this product output side and keep it open during wiring and inspection of this product. Otherwise you may get an electric shock.
CAUTION This product must be installed on a nonflammable wall without holes in it
so that its components cannot be touched from behind. Installing it on or near flammable material may cause a fire.
If this product becomes faulty, the product power must be switched OFF. A continuous flow of large current may cause a fire.
When using a brake resistor, a sequence that will turn OFF power when a fault signal is output must be configured. Otherwise the brake resistor may overheat due to damage of the brake transistor and such, and possibly cause a fire.
Do not connect a resistor directly to the DC terminals P/+ and N/-. Doing so could cause a fire.
Be sure to perform daily and periodic inspections as specified in the Instruction Manual (Detailed). There is a possibility of explosion, damage, or fire if this product is used without inspection.
CAUTION The voltage applied to each terminal must be as specified in the Instruction
Manual (Detailed). Otherwise an explosion or damage may occur. The cables must be connected to the correct terminals. Otherwise an
explosion or damage may occur. The polarity (+ and -) must be correct. Otherwise an explosion or damage
may occur. While power is ON or for some time after power-OFF, do not touch this
product as it will be extremely hot. Doing so may cause burns.
CAUTION Transportation and installation To prevent injury, wear cut-resistant gloves when opening packaging with
sharp tools. Use proper lifting techniques or a trolley when carrying products. Failure
to do so may lead to injuries. Do not stand or place heavy objects on this product. Do not stack the boxes containing this product higher than the number
recommended. When carrying this product, do not hold it by the front cover. It may fall or break. During installation, caution must be taken not to drop this product as doing
so may cause injuries. This product must be installed on a surface that withstands the weight of
the product. Do not install this product on a hot surface. Ensure the mounting orientation of this product is correct. Ensure this product is mounted securely in its enclosure. Do not install or operate this product if it is damaged or has parts missing. Prevent conductive items such as screws and metal fragments, or
flammable substances such as oil from entering this product. As this product is a precision instrument, do not drop or subject it to impact.
CAUTION Transportation and installation The surrounding air temperature must be between -10 and +40C (non-
freezing) for this product. Otherwise the product may be damaged. The ambient humidity must be 95% RH or less (non-condensing) for this
product. Otherwise the product may be damaged. (Refer to page 7 for details.) The temporary storage temperature (applicable to a short limited time
such as a transportation time) must be between -20 and +65C. Otherwise this product may be damaged.
This product must be used indoors (without corrosive gas, flammable gas, oil mist, dust and dirt). Otherwise the product may be damaged.
Do not use this product at an altitude above 4000 m. The maximum amplitude amount must be 0.075 mm (frequency range: 10 to 57 Hz), and the maximum acceleration speed must be 1G (frequency range: 57 to 150 Hz). Otherwise the product may be damaged. (Refer to page 7 for details.)
If halogens (including fluorine, chlorine, bromine, and iodine) contained in fumigants for wood packages enter this product, the product may be damaged. Prevent the entry of fumigant residuals or use an alternative method such as heat disinfection. Note that sterilization or disinfection of wood packages should be performed before packing the product.
Wiring Do not install a power factor correction capacitor, surge absorber, or radio noise
filter on the output side of this product. These devices may overheat or burn out. The output of this product (output terminals U, V, and W) must be correctly
connected to a motor. Otherwise the motor will rotate inversely. Even with the power OFF, high voltage is still applied to the terminals U, V
and W while the PM motor is running. Ensure the PM motor has stopped before carrying out any wiring.
Never connect a PM motor to a commercial power supply. Connecting a commercial power supply to the input terminals (U, V, W) of a PM motor will burn it out. The PM motor must be connected with the output terminals (U, V, W) of this product.
Test operation Before starting operation, confirm or adjust the parameter settings. Failure
to do so may cause some machines to make unexpected motions.
WARNING Usage Stay away from the equipment after using the retry function in this product as
the equipment will restart suddenly after the output shutoff of this product. Depending on the function settings of this product, the product does not
stop its output even when the STOP/RESET key on the operation panel is pressed. To prepare for it, provide a separate circuit and switch (to turn OFF the power of this product, or apply a mechanical brake, etc.) for an emergency stop.
Be sure to turn OFF the start (STF/STR) signal before clearing the fault as this product will restart the motor suddenly after a fault is cleared.
Do not use a PM motor for an application where the PM motor is driven by its load and runs at a speed higher than the maximum motor speed.
Use only a three-phase induction motor or PM motor as a load on this product. Connection of any other electrical equipment to the output of this product may damage the equipment.
Performing pre-excitation (LX signal and X13 signal) under torque control (Real sensorless vector control) may start the motor running at a low speed even when the start command (STF or STR) is not input. This product with the start command ON may also rotate the motor at a low speed when the speed limit value is set to zero. Confirm that the motor running will not cause any safety problems before performing pre-excitation.
Do not modify this product. Do not remove any part which is not instructed to be removed in the
Instruction Manual (Detailed). Doing so may lead to a failure or damage of this product.
CAUTION Usage The electronic thermal O/L relay function may not be enough for
protection of the motor from overheating. It is recommended to install an external thermal relay or a PTC thermistor for overheat protection.
Do not repeatedly start or stop this product with a magnetic contactor on its input side. Doing so may shorten the life of this product.
Use a noise filter or other means to minimize electromagnetic interference with other electronic equipment used nearby this product.
Appropriate precautions must be taken to suppress harmonics. Otherwise power harmonics generated from this product may heat/damage a power factor correction capacitor or a generator.
To drive a 400 V class motor with this product, use an insulation- enhanced motor, or take measures to suppress surge voltage. Otherwise surge voltage, which is attributed to the length and thickness of wire, may occur at the motor terminals, causing the motor insulation to deteriorate.
As all parameters return to their initial values after the Parameter clear or All parameter clear is performed, the parameters must be set again as required before the operation is started.
This product can be easily set for high-speed operation. Therefore, consider all things related to the operation such as the performance of a motor and equipment in a system before the setting change.
This product’s brake function cannot be used as a mechanical brake. Use a separate device instead.
CAUTION Usage Perform an inspection and test operation of this product if it has been
stored for a long period of time. To avoid damage to this product due to static electricity, static electricity in
your body must be discharged before you touch this product. Only one PM motor can be connected to a single unit of this product. A PM motor must be used under PM sensorless vector control. Do not use
a synchronous motor, induction motor, or synchronous induction motor. Do not connect a PM motor to this product with it set to the induction
motor control setting (initial setting). Do not connect an induction motor to this product with it set to the PM sensorless vector control setting. Doing so will cause failure.
As a process of starting a PM motor, turn ON the power of this product first, and then close the contactor on the output side of this product.
In order to protect this product and the system against unauthorized access from external sources through Ethernet communication, take security measures such as setting up a firewall.
Depending on the Ethernet network environment, this product may not operate as intended due to delays or disconnection in communication. Carefully consider what type of environment this product will be used in and any safety issues related to its use.
Emergency stop A safety backup such as an emergency brake must be provided for
devices or equipment in a system to prevent hazardous conditions in case of failure of this product or an external device controlling this product.
If the breaker installed on the input side of this product trips, check for wiring faults (such as short circuits) and damage to internal parts of this product, etc. Identify and remove the cause of the trip before resetting the tripped breaker and applying the power to this product again.
When any protective function is activated, take an appropriate corrective action before resetting this product to resume the operation.
Maintenance, inspection and parts replacement Do not carry out a megger (insulation resistance) test on the control circuit
of this product. Doing so will cause failure. Disposal This product must be treated as industrial waste.
General instruction For clarity, illustrations in this Instruction Manual (Detailed). may be drawn
with covers or safety guards removed. Ensure all covers and safety guards are properly installed prior to starting operation. For details on the PM motor, refer to the Instruction Manual of the PM motor.
Application of caution labels Caution labels are used to ensure safety during use of Mitsubishi Electric inverters. Apply the following labels to the inverter if the «retry function» and/or «automatic restart after instantaneous power failure» have been enabled. For the retry function
For automatic restart after instantaneous power failure
Application of motor control labels Apply the following labels to the inverter to avoid connecting motors not intended for a particular motor control setting.
CAUTION Retry Function Has Been Selected
Stay away from the motor and machine. They will start suddenly (after given time has elapsed) when alarm occurs.
CAUTION Automatic Restart after Instantaneous Power Failure Has Been Selected
Stay away from the motor and machine. They will start suddenly (after reset time has elapsed) when instantaneous power failure occurs.
Induction motor setting The inverter is set for the induction motor control. IM LED is ON during induction motor control. Do not drive a PM motor.
PM motor control setting The inverter is set for the PM motor control. PM LED is ON during PM motor control. Do not drive an induction motor.
1 INVERTER INSTALLATION AND PRECAUTIONS
1.1 Inverter model
Specification differs by the type. Major differences are shown in the table below.
Inverter equipped with a built-in Ethernet board (FR-A8ETH). ON when the inverter has a built-in Class C2 EMC filter.
NOTE In this Instruction Manual, the inverter model name consists of the applicable motor capacity and the rated current. (Example) FR-A840M-04540(200K)
Type Monitor output Initial setting
Built-in EMC filter Control logic Rated
frequency Pr.19 Base frequency voltage
FM (terminal FM equipped model)
Terminal FM: pulse train output Terminal AM: analog voltage output (0 to 10 VDC) OFF Sink logic 60 Hz 9999
(same as the power supply voltage) CA (terminal CA equipped model)
Terminal CA: analog current output (0 to 20 mADC) Terminal AM: analog voltage output (0 to 10 VDC) ON Source logic 50 Hz 8888
(95% of the power supply voltage)
Symbol
Symbol
Symbol Symbol
Symbol
Symbol Type
Circuit board coating (conforming to IEC 60721-3-3 3C2/3S2)
Plated conductor
400 V class DescriptionVoltage class
With With With With
Without
Without Without Without
None
FR- M -A 8 04 -160K
4 Structure
Slim modelM Communication type
FM RS-485
Ethernet CA FM CA
1 2
E1 E2
EMC filter
—
Built-in C3 filter C2 Built-in C2 filter60
06
06B 60B
160, 200K 03630, 04540
Inverter ND rated capacity (kW) Inverter SLD rated current (A)
With
With With With
Built-in brake transistor
Capacity plate
Inverter model
Serial number
Rating plate
Input rating Output rating
SERIAL
Inverter model FR-A840M-04540-E1-60BC2
Country of origin
FR-A840M-04540-E1-60BC2
INVERTER INSTALLATION AND PRECAUTIONS 3
Accessory Earthing (grounding) cable (1): For connection with a communication option. (Ethernet model) CD-ROM (1): Including the Instruction Manual (Detailed) and other documents.
Installing a communication option (Ethernet model) To use a communication option, the enclosed earthing (grounding) cable needs to be installed. Install the cable according
to the following procedure.
NOTE The number and shape of the spacers used differ depending on the communication option type. Refer to the Instruction
Manual of each communication option for details. The earth plate enclosed with a communication option is not used.
No. Installation procedure 1 Insert spacers into the mounting holes that will not be tightened with the option mounting screws. 2 Fit the connector of the communication option to the guide of the connector of the inverter, and insert the option as far as it goes. (Insert it to the inverter option connector 1.)
3 Remove the mounting screw (lower) of the Ethernet board earth plate. Fit the one terminal of the earthing (grounding) cable on the Ethernet board earth plate and fix it securely to the inverter with the mounting screw (tightening torque 0.33 Nm to 0.40 Nm).
4 Fix the left part of the communication option securely with the option mounting screw, and place another terminal of the earthing (grounding) cable on the right part of the option and fix the cable terminal and the option with the option mounting screw (tightening torque 0.33 Nm to 0.40 Nm). If the screw holes do not line up, the connector may not be inserted deep enough. Check the connector.
Ethernet board earth plate
Ethernet board earth plate
Spacer
Spacer
Option connector 1
Example of FR-A8NC
Spacer
Spacer
Mounting screw
Mounting screw
Mounting screw
Earth cable
Earth cable
4 INVERTER INSTALLATION AND PRECAUTIONS
1.2 Inverter component names Component names are shown below.
RS-485 model
Symbol Name Description Refer to page
(a) PU connector Connects the operation panel (FR-DU08) or the parameter unit (FR-PU07). This connector also enables the RS-485 communication. 11
(b) RS-485 terminals Enables RS-485 and MODBUS RTU communication. FR-A800 Instruction Manual (Detailed)
(c) USB A connector Connects a USB memory device. (d) USB mini B connector Connects a personal computer and enables communication with FR Configurator 2. (e) EMC filter ON/OFF connector Turns ON/OFF the EMC filter. (f) Plug-in option connector 1
Connects a plug-in option or a communication option. Instruction Manual of the option
(g) Plug-in option connector 2 (h) Plug-in option connector 3
(i) Voltage/current input switch (SW2) Selects between voltage and current for the terminal 2 and 4 inputs.
FR-A800 Instruction Manual (Detailed)
(j) Control circuit terminal block Connects cables for the control circuit. 4 (k) Main circuit terminal block Connects cables for the main circuit. 18 (l) Wiring cover Remove the protective bushes to connect cables. 19
(m) Front cover Remove this cover for the installation of the product, installation of a plug-in (communication) option, RS-485 terminal wiring, switching of the voltage/current input switch, etc. 11
(n) Power lamp Stays ON while the power is supplied to the control circuit (R1/L11, S1/L21). 18
(o) Alarm lamp Turns ON when the protective function of the inverter is activated.
FR-A800 Instruction Manual (Detailed)
(p) Operation panel (FR-DU08) Operates and monitors the inverter. 25 (q) Charge lamp Stays ON while the power is supplied to the main circuit. 18 (r) Upper main circuit terminal block cover
Connects cables for the main circuit. 11
(s) Lower main circuit terminal block cover 11 (t) Cooling fan Cools the inverter. 33
(q)
(s)
(p)
(a) (b)
(c)
(e)
(l)
(k)
(j)
(g)
(f)
(d)
(h)
(i)
(t)
(m)
(n)
(k)
(l)
(o)
(r)
INVERTER INSTALLATION AND PRECAUTIONS 5
Ethernet model
Symbol Name Description Refer to page
(a) PU connector Connects the operation panel (FR-DU08) or the parameter unit (FR-PU07). This connector also enables the RS-485 communication. 11
(b) Ethernet communication connector Connect the Ethernet dedicated cable for connection to the network. FR-A800 Instruction Manual (Detailed)
(c) USB A connector Connects a USB memory device. (d) USB mini B connector Connects a personal computer and enables communication with FR Configurator 2. (e) EMC filter ON/OFF connector Turns ON/OFF the EMC filter. (f) Plug-in option connector 1
Connects a plug-in option or a communication option. Instruction Manual of the option
(g) Plug-in option connector 3
(h) Plug-in option connector 2 Connector 2 cannot be used because the Ethernet board is installed in the initial status. The Ethernet board must be removed to install a plug-in option to connector 2. (However, Ethernet communication is disabled in that case.)
(i) Voltage/current input switch (SW2) Selects between voltage and current for the terminal 2 and 4 inputs.
FR-A800 Instruction Manual (Detailed)
(j) Control circuit terminal block Connects cables for the control circuit. 4 (k) Main circuit terminal block Connects cables for the main circuit. 18 (l) Wiring cover Remove the protective bushes to connect cables. 19
(m) Front cover Remove this cover for the installation of the product, installation of a plug-in (communication) option, RS-485 terminal wiring, switching of the voltage/current input switch, etc. 11
(n) Power lamp Stays ON while the power is supplied to the control circuit (R1/L11, S1/L21). 18
(o) Alarm lamp Turns ON when the protective function of the inverter is activated.
FR-A800 Instruction Manual (Detailed)
(p) Operation panel (FR-DU08) Operates and monitors the inverter. 25 (q) Charge lamp Stays ON while the power is supplied to the main circuit. 18 (r) Upper main circuit terminal block cover
Connects cables for the main circuit. 11
(s) Lower main circuit terminal block cover 11 (t) Cooling fan Cools the inverter. 33
(q)
(s)
(p)
(a)
(b)
(c)
(e)
(l)
(k)
(j)
(h)
(f)
(d)
(g)
(i)
(m)
(n)
(k)
(l)
(o)
(r)
(t)
6 INVERTER INSTALLATION AND PRECAUTIONS
1.3 Inverter placement
Installation environment Before installation, confirm that the following environment conditions are met.
Temperature applicable for a short time, e.g. in transit. For the installation at an altitude above 1000 m up to 4000 m, consider a 3% reduction in the rated current per 500 m increase in altitude. For the amount of heat generated by the inverter, refer to page 13.
Installation on the enclosure Install the inverter on a strong surface securely with screws. Leave enough clearances and take cooling measures. Avoid places where the inverter is subjected to direct sunlight, high temperature and high humidity. Install the inverter on a nonflammable wall surface. When encasing multiple inverters, install them in parallel as a cooling measure. When designing or building an enclosure for the inverter, carefully consider influencing factors such as heat generation
of the contained devices and the operating environment.
There needs to be a space of at least 30 cm below the inverter to replace the cooling fan. Refer to page 33 for fan replacement.
Item Description Surrounding air temperature -10 to +40C (non-freezing) Enclosure
Ambient humidity With circuit board coating (conforming to IEC 60721-3-3 3C2/3S2): 95% RH or less (non- condensing),
Storage temperature -20 to +65C
Atmosphere Indoors (free from corrosive gas, flammable gas, oil mist, dust and dirt) Altitude Maximum 4000 m
Vibration The maximum amplitude amount must be 0.075 mm (frequency range: 10 to 57 Hz), and the maximum acceleration speed must be 1G (frequency range: 57 to 150 Hz).
Vertical
Clearances (front) Clearances (side)
Inverter
5 cm or more
20 cm or more
20 cm or more
5 cm or more
5 cm or more
Allow clearance.
Measurement position
Measurement position
Inverter 5 cm 5 cm
5 cm
INVERTER INSTALLATION AND PRECAUTIONS 7
1.4 Peripheral devices
1.4.1 Inverter and peripheral devices
NOTE To prevent an electric shock, always earth (ground) the motor and inverter. Do not install a power factor correction capacitor, surge suppressor, or capacitor type filter on the inverter’s output side. Doing so will cause the inverter shut off or
damage the capacitor or surge suppressor. If any of the above devices is connected, immediately remove it. When installing a molded case circuit breaker on the output side of the inverter, contact the manufacturer of the molded case circuit breaker.
Electromagnetic wave interference: The input/output (main circuit) of the inverter includes high frequency components, which may interfere with the communication devices (such as AM radios) used near the inverter. To minimize interference, enabling the built-in EMC filter or installing an external EMC filters is effective. (Refer to the Instruction Manual (Detailed).)
For details of options and peripheral devices, refer to the respective Instruction Manual. A PM motor cannot be driven by the commercial power supply. A PM motor is a motor with permanent magnets embedded inside. High voltage is generated at the motor terminals while the motor is running. Before closing the
contactor at the output side, make sure that the inverter power is ON and the motor is stopped. When external harmonic surges affect the power supply, appropriate precautions must be taken at the source. Installing an AC reactor on the input side may reduce a
surge current flowing into the inverter.
R/L1 S/L2 T/L3 N/-P/+
P/+ PR
P/+ P/+ PR
PR
U V W U V W
IM connection PM connection
USB device (Mini B connector)
Earth (Ground)
Earth (Ground)
(c) Molded case circuit breaker (MCCB) or earth leakage current breaker (ELB), fuse
(e) AC reactor (FR-HAL)
(d) Magnetic contactor (MC)
(a) Inverter(b) Three-phase AC power supply
(k) brake resistor (Built-in brake transistor model only)
(j) USB connector
Personal computer (FR Configurator 2)
USB
USB host (A connector) Communication status indicator (LED)(USB host)
Earth (Ground)
(i) EMC filter (ferrite core)(FR-BLF)
(m) Induction motor
(n) Contactor Example) No-fuse switch (DSN type)
(o) IPM motor
: Install these options as required.
(f) High power factor converter (FR-HC2)
(g) Power regeneration converter (MT-RC)
(i) Resistor unit (MT-BR5)
(h) Brake unit (MT-BU, FR-BU2)
8 INVERTER INSTALLATION AND PRECAUTIONS
1.4.2 Peripheral devices Check the model of the inverter you purchased. Appropriate peripheral devices must be selected according to the capacity. Refer to the following table for right selection.
Molded case circuit breaker / Earth leakage circuit breaker This is a matrix showing the rated current of the molded case circuit breaker (MCCB) or earth leakage circuit breaker (ELB) (NF or NV type) according to the
selected inverter and rating.
NOTE Select an MCCB according to the power supply capacity. Install one MCCB per inverter. For the use in the United States or Canada, refer to page 39, and select an appropriate fuse or molded case circuit breaker (MCCB).
When the inverter capacity is larger than the motor capacity, select an MCCB and a magnetic contactor according to the inverter model, and select cables according to the motor output.
When the breaker installed on the inverter input side is shut off, check for wiring faults (short circuits), damage to internal parts of the inverter. The cause of the output shutoff must be identified and removed before turning ON the power of the breaker.
Symbol Name Overview Refer to page
(a) Inverter (FR-A840M)
The life of the inverter is influenced by the surrounding air temperature. The surrounding air temperature should be as low as possible within the permissible range. This must be noted especially when the inverter is installed in an enclosure. Incorrect wiring may lead to damage of the inverter. The control signal lines must be kept fully away from the main circuit lines to protect them from noise. The built-in EMC filter can reduce the noise.
7 14
(b) Three-phase AC power supply Must be within the permissible power supply specifications of the inverter. 35
(c) Molded case circuit breaker (MCCB), earth leakage circuit breaker (ELB), or fuse Must be selected carefully since an inrush current flows in the inverter at power ON. 9
(d) Magnetic contactor (MC) Install this to ensure safety. Do not use this to start and stop the inverter. Doing so will shorten the life of the inverter. 10
(e) AC reactor (FR-HAL)
Install this to suppress harmonics and to improve the power factor. An AC reactor (FR-HAL) (option) is required when installing the inverter near a large power supply system (1000 kVA or more). Under such condition, the inverter may be damaged if you do not use a reactor. Select a reactor according to the applied motor capacity. Installing an AC reactor may reduce a surge current flowing into the inverter.
32
(f) High power factor converter (FR-HC2) Suppresses the power supply harmonics significantly. Install this as required. 23 (g) Power regeneration converter (MT-RC) Provides a large braking capability. Install this as required. 24 (h) Brake unit (MT-BU, FR-BU2)
Allows the inverter to provide the optimal regenerative braking capability. Install this as required. 22 (i) Resistor unit (MT-BR5)
(j) USB connection Connect between the inverter and a personal computer with a USB (ver. 1.1) cable. Use a USB memory device to copy parameter settings or use the trace function.
FR-A800 Instruction Manual (Detailed)
(k) Brake resistor Improves the braking capability of the inverter built-in brake. 22
(l) Noise filter (ferrite core) (FR-BLF) Install this to reduce the electromagnetic noise generated from the inverter. The noise filter is effective in the range from about 0.5 to 5 MHz. A wire should be wound four turns at maximum.
FR-A800 Instruction Manual (Detailed)
(m) Induction motor Connect a squirrel-cage induction motor.
(n) Example) No-fuse switch (DSN type)
Connect this for an application where a PM motor is driven by the load even while the inverter power is OFF. Do not open or close the contactor while the inverter is running (outputting).
(o) IPM motor Use the specified motor. An IPM motor cannot be driven by the commercial power supply.
Inverter model FR-A840M-[]
Rating SLD ND
03630(160K) 400 A 350 A 04540(200K) 500 A 400 A
MCCB INV
MCCB INV
M
M
INVERTER INSTALLATION AND PRECAUTIONS 9
Magnetic contactor at the inverter’s input side This is a matrix showing the model name of the Mitsubishi magnetic contactor to be installed at the inverter’s input side according to the selected inverter and
rating.
NOTE The matrix shows the magnetic contactor selected according to the standards of Japan Electrical Manufacturers’ Association (JEM standards) for AC-1 class. The
electrical durability of magnetic contactor is 500,000 times. When the MC is used for emergency stops during motor driving, the electrical durability is 25 times. If using the MC for emergency stop during motor driving, select the MC for the inverter input current according to the rated current against JEM 1038 standards for AC-3 class. When installing an MC on the inverter output side to switch to the commercial-power supply operation while running a general-purpose motor, select the MC for the rated motor current according to the rated current against JEM 1038 standards for AC-3 class.
When the inverter capacity is larger than the motor capacity, select an MCCB and a magnetic contactor according to the inverter model, and select cables and reactors according to the motor output.
When the breaker installed on the inverter input side is shut off, check for wiring faults (short circuits), damage to internal parts of the inverter. The cause of the output shutoff must be identified and removed before turning ON the power of the breaker.
Inverter model FR-A840M-[]
Rating SLD ND
03630(160K) S-N400 S-N300 04540(200K) S-N600 S-N400
10 INVERTER INSTALLATION AND PRECAUTIONS
1.4.3 Removal and reinstallation of the operation panel or the front covers Removal and reinstallation of the operation panel
To reinstall the operation panel, align its connector on the back with the PU connector of the inverter, and insert the operation panel. After confirming that the operation panel is fit securely, tighten the screws. (Tightening torque: 0.40 to 0.45 Nm)
Removal of the upper main circuit terminal cover
(a) Remove the mounting screws to remove the upper main circuit terminal cover. (b) With the cover removed, main circuit terminal (R/L1, S/L2, T/L3, P/+, N/-, PR) can be wired.
Removal of the lower main circuit terminal cover
(a) Remove the mounting screws to remove the lower main circuit terminal cover. (b) With the cover removed, main circuit terminal (U, V, W) can be wired.
Loosen the two screws on the operation panel. (These screws cannot be removed.)
Press the upper edge of the operation panel while pulling out the operation panel.
(a) (b)
(a) (b)
INVERTER INSTALLATION AND PRECAUTIONS 11
Removal of the front cover
(a) With the lower main circuit terminal cover removed, loosen the mounting screws on the front cover. (These screws cannot be removed.)
(b) While holding the areas around the installation hooks on the sides of the front cover, pull out the cover using its upper side as a support.
(c) With the front cover removed, the control circuit can be wired and the plug-in option can be installed.
Reinstallation of the front cover
(a) Insert the upper hooks of the front cover into the sockets of the inverter. Securely install the front cover to the inverter by fixing the hooks on the sides of the cover into place.
(b) Tighten the mounting screw(s) at the lower part of the front cover. (c) Fasten the lower main circuit terminal cover with the mounting screws.
NOTE Fully make sure that the front cover has been reinstalled securely. Always tighten the installation screws of the front cover.
Loosen
(a) (b) (c)
(a)
Tighten
(b)
Tighten
(c)
12 INVERTER INSTALLATION AND PRECAUTIONS
1.4.4 Amount of heat generated by the inverter Installing the heat sink inside the enclosure When the heat sink is installed inside the enclosure, the amount of heat generated by the inverter unit is shown in the following tables.
NOTE The amount of heat generated shown assumes that the output current is the inverter rated current, and the carrier frequency is 2 kHz.
Inverter model FR-A840M-[]
Amount of heat generated (W) SLD ND
03630(160K) 4175 3300 04540(200K) 5300 4175
INVERTER INSTALLATION AND PRECAUTIONS 13
Terminal connection diagrams
2 WIRING 2.1 Terminal connection diagrams FM type (RS-485 model)
The function of these terminals can be changed with the input terminal assignment (Pr.178 to Pr.189). (Refer to the Instruction Manual (Detailed).) Terminal JOG is also used as the pulse train input terminal. Use Pr.291 to choose JOG or pulse. Terminal input specifications can be changed by analog input specification switchover (Pr.73, Pr.267). To input a voltage, set the voltage/current input switch OFF. To
input a current, set the voltage/current input switch ON. Terminals 10 and 2 are also used as a PTC input terminal. (Pr.561) (Refer to the Instruction Manual (Detailed).) It is recommended to use 2 W 1 k when the frequency setting signal is changed frequently. Connect a brake resistor to terminals P/+ and PR (built-in brake transistor model only). Install a thermal relay to prevent overheating and damage of the brake resistor
(refer to page 22). The function of these terminals can be changed with the output terminal assignment (Pr.195, Pr.196). (Refer to the Instruction Manual (Detailed).) The function of these terminals can be changed with the output terminal assignment (Pr.190 to Pr.194). (Refer to the Instruction Manual (Detailed).) Terminal F/C (FM) can be used to output pulse trains as open collector output by setting Pr.291. Not required when calibrating the scale with the operation panel. Do not change the initially set ON (enabled) position of the EMC filter ON/OFF connector in the case of the inverter with a built-in C2 filter. The Class C2 compatibility
condition is not satisfied with the EMC filter OFF. When using separate power supply for the control circuit, remove the jumper between R1/L11 and S1/L21. Terminal PR is provided for the built-in brake transistor model only.
NOTE To prevent a malfunction due to noise, keep the signal cables 10 cm or more away from the power cables. Also, separate the main circuit cables at the input side from
the main circuit cables at the output side. After wiring, wire offcuts must not be left in the inverter. Wire offcuts can cause an alarm, failure or malfunction. Always keep the inverter clean. When drilling mounting
holes in an enclosure etc., take caution not to allow chips and other foreign matter to enter the inverter. Set the voltage/current input switch correctly. Incorrect setting may cause a fault, failure or malfunction.
Three-phase AC power supply
MCCB R/L1 S/L2 T/L3
R1/L11 S1/L21
PC24VDC power supply (Common for external power supply transistor)
Forward rotation start
Reverse rotation start
Start self-holding selection
Middle speed
High speed
Low speed
Jog operation
Second function selection
Output stop
Reset Terminal 4 input selection
(Current input selection) Selection of automatic restart
after instantaneous power failure
Frequency setting signals (Analog) 10E(+10V) 10(+5V)
2
(Analog common)
2 3
1
Auxiliary input
Terminal 4 input (Current input)
1
4
Frequency setting potentiometer 1/2W1k
Running
Up to frequency
Instantaneous power failure Overload
Frequency detection
Open collector output common Sink/source common
F/C (FM)
SD
Control input signals (No voltage input allowed)
Motor
Relay output 1 (Fault output)
C1
B1
A1
U V W
Indicator (Frequency meter, etc.)
+ —
(-)
(+) Analog signal output (0 to 10VDC)
Earth (Ground)
AM
5
DC0 to 5V selectable DC0 to 10V
Multi-speed selection
Open collector output
Moving-coil type 1mA full-scale
Contact input common
Calibration resistor
Main circuit terminal Control circuit terminal
DC0 to 5V DC0 to 10V selectable
MC
Main circuit
C2
B2
A2 Relay output 2
Relay output
M
DC0 to 20mA
DC0 to 5V DC0 to 10V
selectable DC4 to 20mA TXD+
Terminating resistor
TXD-
RXD+ RXD-
GND (SG)
Data transmission
GND
RS-485 terminals
PU connector
USB A connector
USB mini B connector
SI N
K
SO U
R C
E
Connector for plug-in option connection
STF
STR
STP(STOP)
RH
RM
RL
JOG
RT
MRS
RES
AU
CS
SD
RUN
SU
IPF
OL
FU
SE
Data reception
(+) (-)
5
EMC filter ON/OFF connecter
ON
OFF
+2424V external power supply input SD
Common terminal
VCC
(+) (-)
5V (Permissible load current 100mA)
Sink logic
Earth (Ground)
Connector 1 Connector 2
Connector 3
Jumper
N/-P/+
Control circuit
Initial value
Initial value
Initial value
ON
42 OFF
Voltage/current input switch
Brake unit (Option)
Safety monitor output
Safety monitor output common
So (SO)
SOC
S1
S2
PC
SD SIC
Safety stop signal
Safety stop input (Channel 1)
Shorting wire
Safety stop input common
Safety stop input (Channel 2)
24V
Inrush current limit circuit
24V
Output shutoff circuit
Built-in brake transistor model
R/L1 S/L2 T/L3
U V W
N/-P/+
Reactor
Reactor
PR
Brake resistor
Inrush current limit circuit
Reactor
Reactor
R
Terminal connection diagrams
CA type (RS-485 model)
The function of these terminals can be changed with the input terminal assignment (Pr.178 to Pr.189). (Refer to the Instruction Manual (Detailed).) Terminal JOG is also used as the pulse train input terminal. Use Pr.291 to choose JOG or pulse. Terminal input specifications can be changed by analog input specification switchover (Pr.73, Pr.267). To input a voltage, set the voltage/current input switch OFF. To
input a current, set the voltage/current input switch ON. Terminals 10 and 2 are also used as a PTC input terminal. (Pr.561) (Refer to the Instruction Manual (Detailed).) It is recommended to use 2 W 1 k when the frequency setting signal is changed frequently. Connect a brake resistor to terminals P/+ and PR (built-in brake transistor model only). Install a thermal relay to prevent overheating and damage of the brake resistor
(refer to page 22). The function of these terminals can be changed with the output terminal assignment (Pr.195, Pr.196). (Refer to the Instruction Manual (Detailed).) The function of these terminals can be changed with the output terminal assignment (Pr.190 to Pr.194). (Refer to the Instruction Manual (Detailed).) Do not change the initially set ON (enabled) position of the EMC filter ON/OFF connector in the case of the inverter with a built-in C2 filter. The Class C2 compatibility
condition is not satisfied with the EMC filter OFF. When using separate power supply for the control circuit, remove the jumper between R1/L11 and S1/L21. Terminal PR is provided for the built-in brake transistor model only.
NOTE To prevent a malfunction due to noise, keep the signal cables 10 cm or more away from the power cables. Also, separate the main circuit cables at the input side from
the main circuit cables at the output side. After wiring, wire offcuts must not be left in the inverter. Wire offcuts can cause an alarm, failure or malfunction. Always keep the inverter clean. When drilling mounting
holes in an enclosure etc., take caution not to allow chips and other foreign matter to enter the inverter. Set the voltage/current input switch correctly. Incorrect setting may cause a fault, failure or malfunction.
Three-phase AC power supply
MCCB R/L1 S/L2 T/L3
R1/L11 S1/L21
PC24VDC power supply (Common for external power supply transistor)
Forward rotation start
Reverse rotation start
Start self-holding selection
Middle speed
High speed
Low speed
Jog operation
Second function selection
Output stop
Reset Terminal 4 input selection
(Current input selection) Selection of automatic restart
after instantaneous power failure
Frequency setting signals (Analog) 10E(+10V) 10(+5V)
2
(Analog common)
2 3
1
Auxiliary input
Terminal 4 input (Current input)
1
4
Frequency setting potentiometer 1/2W1k
Running
Up to frequency
Instantaneous power failure Overload
Frequency detection
Open collector output common Sink/source common
Control input signals (No voltage input allowed)
Motor
Relay output 1 (Fault output)
C1
B1
A1
U V W
Earth (Ground)
DC0 to 5V selectable DC0 to 10V
Multi-speed selection
Open collector output
Contact input common
Main circuit terminal Control circuit terminal
DC0 to 5V DC0 to 10V selectable
MC
Main circuit
C2
B2
A2 Relay output 2
Relay output
M
DC0 to 20mA
DC0 to 5V DC0 to 10V
selectable DC4 to 20mA TXD+
Terminating resistor
TXD-
RXD+ RXD-
GND (SG)
Data transmission
GND
RS-485 terminals
PU connector
USB A connector
USB mini B connector
SI N
K
SO U
R C
E
Connector for plug-in option connection
STF
STR
STP(STOP)
RH
RM
RL
JOG
RT
MRS
RES
AU
CS
SD
RUN
SU
IPF
OL
FU
SE
Data reception
(+) (-)
5
EMC filter ON/OFF connecter
ON
OFF
+2424V external power supply input SD
Common terminal
VCC
(+) (-)
5V (Permissible load current 100mA)
Sink logic
Earth (Ground)
Connector 1 Connector 2
Connector 3
Jumper
N/-P/+
Control circuit
Initial value
Initial value
Initial value
ON
42 OFF
Voltage/current input switch
Brake unit (Option)
Safety monitor output
Safety monitor output common
So (SO)
SOC
S1
S2
PC
SD SIC
Safety stop signal
Safety stop input (Channel 1)
Shorting wire
Safety stop input common
Safety stop input (Channel 2)
24V
Inrush current limit circuit
24V
Output shutoff circuit
Built-in brake transistor model
R/L1 S/L2 T/L3
U V W
N/-P/+
Reactor
Reactor
PR
Brake resistor
Inrush current limit circuit
Reactor
Reactor
R
()
() Analog signal output (DC010V)
()
() Analog current output (DC020mA)
AM
5
F/C (CA)
Terminal connection diagrams
FM type (Ethernet model)
The function of these terminals can be changed with the input terminal assignment (Pr.178 to Pr.189). (Refer to the Instruction Manual (Detailed).) Terminal JOG is also used as the pulse train input terminal. Use Pr.291 to choose JOG or pulse. Terminal input specifications can be changed by analog input specification switchover (Pr.73, Pr.267). To input a voltage, set the voltage/current input switch OFF. To
input a current, set the voltage/current input switch ON. Terminals 10 and 2 are also used as a PTC input terminal. (Pr.561) (Refer to the Instruction Manual (Detailed).) It is recommended to use 2 W 1 k when the frequency setting signal is changed frequently. Connect a brake resistor to terminals P/+ and PR (built-in brake transistor model only). Install a thermal relay to prevent overheating and damage of the brake resistor
(refer to page 22). The function of these terminals can be changed with the output terminal assignment (Pr.195, Pr.196). (Refer to the Instruction Manual (Detailed).) The function of these terminals can be changed with the output terminal assignment (Pr.190 to Pr.194). (Refer to the Instruction Manual (Detailed).) Terminal F/C (FM) can be used to output pulse trains as open collector output by setting Pr.291. Not required when calibrating the scale with the operation panel. Do not change the initially set ON (enabled) position of the EMC filter ON/OFF connector in the case of the inverter with a built-in C2 filter. The Class C2 compatibility
condition is not satisfied with the EMC filter OFF. The option connector 2 cannot be used because the Ethernet board is installed in the initial status. The Ethernet board must be removed to install a plug-in option to the
option connector 2. (However, Ethernet communication is disabled in that case.) When using separate power supply for the control circuit, remove the jumper between R1/L11 and S1/L21. Terminal PR is provided for the built-in brake transistor model only.
NOTE To prevent a malfunction due to noise, keep the signal cables 10 cm or more away from the power cables. Also, separate the main circuit cables at the input side from
the main circuit cables at the output side. After wiring, wire offcuts must not be left in the inverter. Wire offcuts can cause an alarm, failure or malfunction. Always keep the inverter clean. When drilling mounting
holes in an enclosure etc., take caution not to allow chips and other foreign matter to enter the inverter. Set the voltage/current input switch correctly. Incorrect setting may cause a fault, failure or malfunction.
Three-phase AC power supply
MCCB R/L1 S/L2 T/L3
R1/L11 S1/L21
PC24VDC power supply (Common for external power supply transistor)
Forward rotation start
Reverse rotation start
Start self-holding selection
Middle speed
High speed
Low speed
Jog operation
Second function selection
Output stop
Reset Terminal 4 input selection
(Current input selection) Selection of automatic restart
after instantaneous power failure
Frequency setting signals (Analog) 10E(+10V) 10(+5V)
2
(Analog common)
2 3
1
Auxiliary input
Terminal 4 input (Current input)
1
4
Frequency setting potentiometer 1/2W1k
Running
Up to frequency
Instantaneous power failure Overload
Frequency detection
Open collector output common Sink/source common
F/C (FM)
SD
Control input signals (No voltage input allowed)
Motor
Relay output 1 (Fault output)
C1
B1
A1
U V W
Indicator (Frequency meter, etc.)
+ —
(-)
(+) Analog signal output (0 to 10VDC)
Earth (Ground)
AM
5
DC0 to 5V selectable DC0 to 10V
Multi-speed selection
Open collector output
Moving-coil type 1mA full-scale
Contact input common
Calibration resistor
Main circuit terminal Control circuit terminal
DC0 to 5V DC0 to 10V selectable
MC
Main circuit
C2
B2
A2 Relay output 2
Relay output
M
DC0 to 20mA
DC0 to 5V DC0 to 10V
selectable DC4 to 20mA
PU connector
USB A connector
USB mini B connector
SI N
K
SO U
R C
E
Connector for plug-in option connection
STF
STR
STP(STOP)
RH
RM
RL
JOG
RT
MRS
RES
AU
CS
SD
RUN
SU
IPF
OL
FU
SE
(+) (-)
5
EMC filter ON/OFF connecter
ON
OFF
+2424V external power supply input SD
Common terminal
(+) (-)
Sink logic
Earth (Ground)
Connector 1 Connector 2
Connector 3
Jumper
N/-P/+
Control circuit
Initial value
Initial value
Initial value
ON
42 OFF
Voltage/current input switch
Brake unit (Option)
Safety monitor output
Safety monitor output common
So (SO)
SOC
S1
S2
PC
SD SIC
Safety stop signal
Safety stop input (Channel 1)
Shorting wire
Safety stop input common
Safety stop input (Channel 2)
24V
Inrush current limit circuit
24V
Output shutoff circuit
Built-in brake transistor model
R/L1 S/L2 T/L3
U V W
N/-P/+
Reactor
Reactor
PR
Brake resistor
Inrush current limit circuit
Reactor
Reactor
R
Ethernet connector
Terminal connection diagrams
CA type (Ethernet model)
The function of these terminals can be changed with the input terminal assignment (Pr.178 to Pr.189). (Refer to the Instruction Manual (Detailed).) Terminal JOG is also used as the pulse train input terminal. Use Pr.291 to choose JOG or pulse. Terminal input specifications can be changed by analog input specification switchover (Pr.73, Pr.267). To input a voltage, set the voltage/current input switch OFF. To
input a current, set the voltage/current input switch ON. Terminals 10 and 2 are also used as a PTC input terminal. (Pr.561) (Refer to the Instruction Manual (Detailed).) It is recommended to use 2 W 1 k when the frequency setting signal is changed frequently. Connect a brake resistor to terminals P/+ and PR (built-in brake transistor model only). Install a thermal relay to prevent overheating and damage of the brake resistor
(refer to page 22). The function of these terminals can be changed with the output terminal assignment (Pr.195, Pr.196). (Refer to the Instruction Manual (Detailed).) The function of these terminals can be changed with the output terminal assignment (Pr.190 to Pr.194). (Refer to the Instruction Manual (Detailed).) Do not change the initially set ON (enabled) position of the EMC filter ON/OFF connector in the case of the inverter with a built-in C2 filter. The Class C2 compatibility
condition is not satisfied with the EMC filter OFF. The option connector 2 cannot be used because the Ethernet board is installed in the initial status. The Ethernet board must be removed to install a plug-in option to the
option connector 2. (However, Ethernet communication is disabled in that case.) When using separate power supply for the control circuit, remove the jumper between R1/L11 and S1/L21. Terminal PR is provided for the built-in brake transistor model only.
NOTE To prevent a malfunction due to noise, keep the signal cables 10 cm or more away from the power cables. Also, separate the main circuit cables at the input side from
the main circuit cables at the output side. After wiring, wire offcuts must not be left in the inverter. Wire offcuts can cause an alarm, failure or malfunction. Always keep the inverter clean. When drilling mounting
holes in an enclosure etc., take caution not to allow chips and other foreign matter to enter the inverter. Set the voltage/current input switch correctly. Incorrect setting may cause a fault, failure or malfunction.
Three-phase AC power supply
MCCB R/L1 S/L2 T/L3
R1/L11 S1/L21
PC24VDC power supply (Common for external power supply transistor)
Forward rotation start
Reverse rotation start
Start self-holding selection
Middle speed
High speed
Low speed
Jog operation
Second function selection
Output stop
Reset Terminal 4 input selection
(Current input selection) Selection of automatic restart
after instantaneous power failure
Frequency setting signals (Analog) 10E(+10V) 10(+5V)
2
(Analog common)
2 3
1
Auxiliary input
Terminal 4 input (Current input)
1
4
Frequency setting potentiometer 1/2W1k
Running
Up to frequency
Instantaneous power failure Overload
Frequency detection
Open collector output common Sink/source common
Control input signals (No voltage input allowed)
Motor
Relay output 1 (Fault output)
C1
B1
A1
U V W
Earth (Ground)
DC0 to 5V selectable DC0 to 10V
Multi-speed selection
Open collector output
Contact input common
Main circuit terminal Control circuit terminal
DC0 to 5V DC0 to 10V selectable
MC
Main circuit
C2
B2
A2 Relay output 2
Relay output
M
DC0 to 20mA
DC0 to 5V DC0 to 10V
selectable DC4 to 20mA
PU connector
USB A connector
USB mini B connector
SI N
K
SO U
R C
E
Connector for plug-in option connection
STF
STR
STP(STOP)
RH
RM
RL
JOG
RT
MRS
RES
AU
CS
SD
RUN
SU
IPF
OL
FU
SE
(+) (-)
5
EMC filter ON/OFF connecter
ON
OFF
+2424V external power supply input SD
Common terminal
(+) (-)
Sink logic
Earth (Ground)
Connector 1 Connector 2
Connector 3
Jumper
N/-P/+
Control circuit
Initial value
Initial value
Initial value
ON
42 OFF
Voltage/current input switch
Brake unit (Option)
Safety monitor output
Safety monitor output common
So (SO)
SOC
S1
S2
PC
SD SIC
Safety stop signal
Safety stop input (Channel 1)
Shorting wire
Safety stop input common
Safety stop input (Channel 2)
24V
Inrush current limit circuit
24V
Output shutoff circuit
Built-in brake transistor model
R/L1 S/L2 T/L3
U V W
N/-P/+
Reactor
Reactor
PR
Brake resistor
Inrush current limit circuit
Reactor
Reactor
Ethernet connector
R
()
() Analog signal output (DC010V)
()
() Analog current output (DC020mA)
AM
5
F/C (CA)
2.2 Main circuit terminals
2.2.1 Terminal layout of the main circuit terminals
Terminal PR is provided for the built-in brake transistor model only.
Without Class C2 EMC filter With Class C2 EMC filter
R/L1 S/L2 T/L3 N/- P/+ PR
U V W
M Motor
Power supply
Charge lamp
Jumper
U V W
R/L1 S/L2 T/L3
N/- P/+ PR R/L1 S/L2 T/L3
N/- P/+ PR
M Motor
Power supply
Charge lamp
Jumper
2.2.2 Wiring method (1) Remove the upper and lower main circuit terminal covers of the inverter. (Refer to page 11). (2) Remove the front side of the wiring cover and the protective bushes.
(Do not remove the protective bushes that are not used for wiring of cables.)
(3) Make holes in the protective bushes, then pass the cables through the bushes.
(4) Connect the cables to the main circuit terminals, then reinstall the bushes to the rear parts of wiring covers.
(5) Reinstall the wiring cover.
(6) Reinstall the upper and lower main circuit terminal covers of the inverter. (Refer to page 11).
CAUTION Make holes in the protective bushes according to the cable diameter.
Wiring cover
Protective bushes
2.2.3 Recommended cables and wiring length Select a recommended size cable to ensure that the voltage drop ratio is within 2%. If the wiring distance is long between the inverter and motor, the voltage drop in the main circuit will cause the motor torque to decrease especially at a low speed. The following tables show the recommended cable size for cables that are 20 m in length.
For the ND rating
For the SLD rating
This cable gauge is with the continuous maximum permissible temperature of 90C or higher (LMFC (heat resistant flexible cross-linked polyethylene insulated cable), etc.). Assumes that the surrounding air temperature is 50C or less and the wiring is in-enclosure.
This cable gauge is with continuous maximum permissible temperature of 90C (THHN cable). This assumes a surrounding air temperature of 40C or lower and in- enclosure wiring. (For the use in the United States or Canada, refer to page 39.)
This cable gauge is with continuous maximum permissible temperature of 90C (XLPE cable). This assumes a surrounding air temperature of 40C and in-enclosure wiring. (Selection example mainly for use in Europe.)
The terminal screw size indicates the size of the terminal screw for R/L1, S/L2, T/L3, U, V, W, PR, P/+, N/- and the screw for earthing (grounding). The screw size for earthing (grounding) is indicated in parenthesis.
Terminal PR is only equipped with a product with a built-in brake transistor.
The line voltage drop can be calculated by the following formula:
Line voltage drop [V] = wire resistance [m/m] wiring distance [m] current [A] / 1000 Use a larger diameter cable when the wiring distance is long or when it is desired to decrease the voltage drop (torque reduction) in the low speed range.
NOTE Tighten the terminal screw to the specified torque.
A screw that has been tightened too loosely can cause a short circuit or malfunction. A screw that has been tightened too tightly can cause a short circuit or malfunction due to the unit breakage.
Use crimp terminals with insulation sleeves to wire the power supply and motor.
Total wiring length With induction motor
Connect one or more general-purpose motors within the total wiring length shown in the following table. (The wiring length should be 100 m or shorter under
Vector control.)
When driving a 400 V class motor by the inverter, surge voltages attributable to the wiring constants may occur at the motor terminals, deteriorating the insulation of the motor. In this case, take one of the following measure. Use a «400 V class inverter-driven insulation-enhanced motor» and set Pr.72 PWM frequency selection according to the wiring length.
Connect a sine wave filter (MT-BSL/BSC) at the output side of the inverter.
With PM motor Use the wiring length of 100 m or shorter when connecting a PM motor. Use one PM motor for one inverter. Multiple PM motors cannot be connected to an inverter.
NOTE Especially for long-distance wiring, the inverter may be affected by a charging current caused by stray capacitances of the wiring, leading to an activation of the
overcurrent protection, malfunction of the fast-response current limit operation, or even to an inverter failure. It may also cause a malfunction or fault of the equipment connected ON the inverter output side. If the fast-response current limit function malfunctions, disable the function. (For the details of Pr.156 Stall prevention operation selection, Refer to the FR-A800 Instruction Manual (Detailed)).
A sine wave filter (MT-BSL/BSC) can be used under V/F control. Do not use the filters under different control methods. For the details of Pr.72 PWM frequency selection, refer to the FR-A800 Instruction Manual (Detailed). Refer to Refer to the FR-A800 Instruction Manual (Detailed) to drive a 400 V class motor by an inverter.
Applicable inverter model
FR-A840M-[]
Terminal screw
size
Tightening torque (Nm)
Crimp terminal Cable gauge
HIV cables, etc. (mm2) AWG/MCM PVC cables, etc. (mm2) R/L1, S/L2, T/L3
U, V, W R/L1, S/L2, T/L3
U, V, W P/+, P1
Earthing (grounding)
cable
R/L1, S/L2, T/L3
U, V, W R/L1, S/L2, T/L3
U, V, W Earthing
(grounding) cable
03630(160K) M12 (M10) 14.7 100-12 100-12 100 100 150 38 4/0 4/0 95 95 50
04540(200K) M12 (M10) 14.7 100-12 100-12 100 100 150 38 4/0 4/0 95 95 70
Applicable inverter model
FR-A840M-[]
Terminal screw
size
Tightening torque (Nm)
Crimp terminal Cable gauge
HIV cables, etc. (mm2) AWG/MCM PVC cables, etc. (mm2) R/L1, S/L2, T/L3
U, V, W R/L1, S/L2, T/L3
U, V, W P/+, P1
Earthing (grounding)
cable
R/L1, S/L2, T/L3
U, V, W R/L1, S/L2, T/L3
U, V, W Earthing
(grounding) cable
03630(160K) M12 (M10) 14.7 100-12 100-12 100 100 150 38 4/0 4/0 95 95 50
04540(200K) M12 (M10) 14.7 150-12 100-12 150 150 200 38 300 300 150 150 95
Pr.72 setting (carrier frequency) FR-A840M-03630(160K) FR-A840M-0450(200K)
2 (2 kHz) or lower 500 m 500 m 3 (3 kHz) or higher 500 m 500 m
Wiring length longer than 100 m 4 (4 kHz) or lower
2.3 Control circuit terminal
Wiring precautions It is recommended to use a cable of 0.3 to 0.75 mm2 for connection to the control circuit terminals. The wiring length should be 30 m (200 m for terminal FM) at the maximum. Use two or more parallel micro-signal contacts or twin contacts to prevent contact faults when using contact inputs since
the control circuit input signals are micro-currents. To suppress EMI, use shielded or twisted cables for the control circuit terminals and run them away from the main and
power circuits (including the 200 V relay sequence circuit). For the cables connected to the control circuit terminals, connect their shields to the common terminal of the connected control circuit terminal. When connecting an external power supply to terminal PC, however, connect the shield of the power supply cable to the negative side of the external power supply. Do not directly earth (ground) the shield to the enclosure, etc.
Always apply a voltage to the fault output terminals (A1, B1, C1, A2, B2, C2) via a relay coil, lamp, etc. Do not connect any terminal SD on the inverter and the 0 V terminal of the external power supply (when the sink logic is selected). Separate the wiring of the control circuit away from the wiring of the main circuit.
Make cuts in rubber bush of the inverter side and lead the wires through.
Wiring method Blade terminals commercially available (as of April 2019)
A ferrule terminal with an insulation sleeve compatible with the MTW wire which has a thick wire insulation. Applicable for the terminal A1, B1, C1, A2, B2 and C2 only.
Cable gauge (mm2) Ferrule terminal model
Manufacturer Crimping tool nameWith insulation
sleeve Without insulation
sleeve For UL wire
0.3 AI 0,34-10TQ
Phoenix Contact Co., Ltd. CRIMPFOX 6
0.5 AI 0,5-10WH AI 0,5-10WH-GB
0.75 AI 0,75-10GY A 0,75-10 AI 0,75-10GY-GB
1 AI 1-10RD A 1-10 AI 1-10RD/1000GB
1.25, 1.5 AI 1,5-10BK A 1,5-10 AI 1,5-10BK/1000GB
0.75 (two-wire product) AI-TWIN 20,75-10GY
Cable gauge (mm2) Blade terminal product number
Insulation cap product number Manufacturer Crimping tool
product number 0.3 to 0.75 BT 0.75-11 VC 0.75 NICHIFU Co., Ltd. NH 69
Micro signal contacts Twin contacts
Rubber bush viewed from inside
Make cuts along the lines on the inside with a cutter knife
Wiring example
Connection of stand-alone option units
2.4 Connection of stand-alone option units The inverter accepts a variety of stand-alone option units as required. Incorrect connection will cause inverter damage or accident. Connect and operate the option unit carefully in accordance with the Instruction Manual of the corresponding option unit.
2.4.1 Connection of the brake resistor (built-in brake transistor model) When an inverter-driven motor is driven by a load or requires rapid acceleration, install an external brake resistor. Connect the brake resistor to terminals P/+ and PR. (For the locations of terminal P/+ and PR, refer to the terminal block layout (refer to page 18).)
Do not use the brake resistor with a resistance smaller than the minimum resistance shown below. Also, the brake resistor must have a sufficient capacity to consume the regenerative power.
Set parameters as follows: Pr.30 Regenerative function selection = «1, 11, 21, 101, 111, or 121» (Refer to page 27) Set Pr.70 Special regenerative brake duty according to the amount and frequency of the regenerative driving, and make sure that the resistor can consume
the regenerative power properly. When the regenerative brake transistor is damaged, install a thermal relay as shown in the following sequence to prevent overheat and burnout of the brake
resistor. Properly select a thermal relay according to the regenerative driving frequency or the rated power or resistance of the brake resistor.
2.4.2 Connection of the brake unit (FR-BU2) Connect the brake unit (FR-BU2(-H)) as follows to improve the braking capability during deceleration. After making sure that the wiring is correct and secure, set Pr.30 Regenerative function selection = «1» and Pr.70 Special regenerative brake duty = «0 (initial value)». Set Pr.0 Brake mode selection = «2» in the brake unit FR-BU2.
When wiring, make sure to match the terminal symbols (P/+, N/-) on the inverter and on the brake unit (FR-BU2). (Incorrect connection will damage the inverter and brake unit.)
Install a stepdown transformer. The wiring distance between the inverter, brake unit (FR-BU2) and resistor unit (FR-BR) must be within 5 m. When using twisted pair cable, use the cable within 10 m. The contact between TH1 and TH2 is open in the normal status and is closed at a fault. The CN8 connector used with the MT-BU5 type brake unit is not used.
NOTE The warning «oL» of the stall prevention (overvoltage) does not occur while Pr.30 Regenerative function selection = «1» and Pr.70 Special regenerative brake duty
= 0% (initial value). (Refer to the FR-A800 Instruction Manual (Detailed).)
Inverter Minimum resistance () Power consumption of resistor (kW) FR-A840M-03630(160K) 3.85 160 FR-A840M-04540(200K) 3 200
CAUTION If the resistor selection or the setting of Pr.30 or Pr.70 is incorrect, overcurrent may damage the inverter built-in brake transistor. If the selection of the thermal relay is incorrect, the resistor may be burned due to overheat.
R Brake resistor
Thermal relay (OCR)Inverter
PR
P/+ S/L2 T/L3
R/L1 MC
Power Supply
T F
ONOFF MC
MC OCR
Contact
Inverter
MC
T
R
PR
P/+ Brake resistor
Thermal relay (OCR)
S/L2 T/L3
R/L1
ON OFF B
C
F
MC
MC
Power Supply
OCR Contact
MC R/L1 Motor
M
Inverter
S/L2 T/L3
U V
P/+ N/- P
PR
10 m or less
W
Three phase AC power supply
MCCB
TH1
TH2
MC
CR1
OFFON
MC
CR1
T
P N BUE SD
P PR
Brake unit FR-BU2
Resistor unit MT-BR5
A B C
Connection of stand-alone option units
2.4.3 Connection of the high power factor converter (FR-HC2) When connecting the high power factor converter (FR-HC2) to suppress power harmonics, perform wiring securely as follows. Incorrect connection will damage the high power factor converter and the inverter. After making sure that the wiring is correct and secure, set the rated motor voltage in Pr.19 Base frequency voltage (under V/F control) or Pr.83 Rated motor voltage (under other than V/F control) and «2 or 102» in Pr.30 Regenerative function selection. (Refer to the FR-A800 Instruction Manual (Detailed).)
Remove jumpers across terminals R/L1 and R1/L11 as well as across terminals S/L2 and S1/L21, and connect the power supply for the control circuit to terminals R1/ L11 and S1/L21. Do not connect anything to power input terminals (R/L1, S/L2, and T/L3). Incorrect connection will damage the inverter. (The E.OPT fault (Option fault) occurs. (Refer to the FR-A800 Instruction Manual (Detailed).)
Do not install an MCCB across terminals P/+ and N/- (between terminals P and P/+ or between terminals N and N/-). Connecting the opposite polarity of terminals N/- and P/+ will damage the inverter.
Use Pr.178 to Pr.189 (Input terminal function selection) to assign the terminals used for the X10 (X11) signal. (Refer to the FR-A800 Instruction Manual (Detailed).) For RS-485 or any other communication where the start command is only transmitted once, use the X11 signal to save the operation mode at the time of an instantaneous power failure.
Assign the IPF signal to a terminal on the FR-HC2. (Refer to the Instruction Manual of the FR-HC2.) Always connect terminal RDY on the FR-HC2 to a terminal where the X10 signal or MRS signal is assigned on the inverter. Always connect terminal SE on the FR-HC2
to terminal SD on the inverter. Not connecting these terminals may damage the FR-HC2. Always connect terminals R/L1, S/L2, and T/L3 on the FR-HC2 to the power supply. Operating the inverter without connecting them will damage the FR-HC2. Do not install an MCCB or MC across terminals (R/L1, S/L2, T/L3) on the reactor 1 and terminals (R4/L14, S4/L24, T4/L34) on the FR-HC2. Doing so disrupts proper
operation. Securely perform grounding (earthing) by using the grounding (earthing) terminal. Installation of a fuse is recommended. (Refer to the Instruction Manual of the FR-HC2.) Outside box is not available for the FR-HC2-H280K or higher. Connect filter capacitors, inrush current limit resistors, and magnetic contactors. (Refer to the Instruction
Manual of the FR-HC2.)
NOTE The voltage phases of terminals R/L1, S/L2, and T/L3 and the voltage phases of terminals R4/L14, S4/L24, and T4/L34 must be matched. The control logic (sink logic/source logic) of the high power factor converter and the inverter must be matched. (Refer to the FR-A800 Instruction Manual (Detailed).)
ROH2 ROH1
Outside box (FR-HCB2) Inverter
High power factor converter
(FR-HC2)Reactor2 (FR-HCL22)
Motor
M
Reactor1 (FR-HCL21)
P/+ P/+ N/-N/-
R1/L11 S1/L21
X10 X11
SD
RDY
RSO SE
R/L1
Earth (ground)
S/L2 T/L3
Three-phase AC power supply
U V W
R1/L11 S1/L21
88R88R 88S88S
ROH SD
MCCB MC R4/ L14 R4/L14 S4/ L24 S4/L24 T4/ L34 T4/L34
R3/ L13 R3/
L13 S3/ L23
S3/ L23
T3/ L33
T3/ L33
R2/ L12
R2/ L12
S2/ L22
S2/ L22
T2/ L32
T2/ L32
R/ L1 S/ L2 T/ L3
R/L1 S/L2 T/L3
RES IPF
Fuse
Connection of stand-alone option units
2.4.4 Connection of the power regeneration converter (MT-RC) When connecting the power regeneration converter (MT-RC), perform wiring securely as follows. Incorrect connection will damage the power regeneration converter and the inverter. After making sure that the wiring is correct and secure, set «1» in Pr.30 Regenerative function selection and «0» in Pr.70 Special regenerative brake duty.
NOTE When using the inverter with the MT-RC, install a magnetic contactor (MC) at the input side of the inverter so that power is supplied to the inverter after one second or
more has elapsed after powering ON the MT-RC. When power is supplied to the inverter prior to the MT-RC, the inverter and the MT-RC may be damaged or the MCCB may be shut off or damaged.
When connecting the power coordination reactor and others, refer to Instruction Manual of the MT-RC for precautions.
R/L1 S/L2 T/L3 R1/L11 S1/L21
R R2 RES
U V W
Inverter
MT-RCL
N/-
P N
RDY
SE
MT-RC
Reset signal
Ready signal
Three-phase AC power supply
MCCB MC2MC1
M
STF SD
S
T
S2
T2
R2
S2
T2
R
S
T
R1
S1
C
Alarm signalB A
P/+
MT-RC power supply (MC1)
Inverter input power supply (MC2)
1s or more
ON
ON
Operation panel (FR-DU08)
3 BASIC OPERATION
3.1 Operation panel (FR-DU08)
No. Name Description
(a) Setting dial
The setting dial of the Mitsubishi Electric inverters. Turn the setting dial to change the setting of frequency or parameter, etc. Press the setting dial to perform the following operations: To display a set frequency in the monitoring mode (The monitor item shown on the display can be changed by using Pr.992.) To display the present setting during calibration To display a fault history number in the fault history mode
(b) MODE key
Switches the operation panel to a different mode. The easy setting of the inverter operation mode is enabled by pressing this key simultaneously with [PU/EXT] key. Every key on the operation panel becomes inoperable by holding this key for 2 seconds. The key inoperable function is invalid when Pr.161=»0 (initial setting)». (Refer to the FR-A800 Instruction Manual (Detailed).)
(c) SET key Confirms each selection. When this key is pressed during inverter operation, the monitor item changes. (The monitor item can be changed according to the settings of Pr.52, Pr.774 to Pr.776.)
(d) ESC key Goes back to the previous display. Holding this key for a longer time changes the display back to the monitor mode.
(e) PU/EXT key
Switches between the PU operation mode, the PUJOG operation mode, and the External operation mode. The easy setting of the inverter operation mode is enabled by pressing this key simultaneously with [MODE] key. Also cancels the PU stop warning.
(a)
(b) (c) (d)
(e)
Operation panel (FR-DU08)
3.1.1 Basic operation (factory setting)
For the details of operation modes, refer to the Instruction Manual (Detailed). The monitor items can be changed. (Refer to the Instruction Manual (Detailed).) For the details of the trace function, refer to the Instruction Manual (Detailed). For the details of fault history, refer to the Instruction Manual (Detailed). The USB memory mode indication appears while a USB memory device is connected. Refer to the Instruction Manual (Detailed) for the details of the USB memory
mode.
Operation mode switchover/Frequency setting
Fu nc
tio n
M on
ito r
Pa ra
m et
er s
et tin
g Fa
ul t h
is to
ry Blinking Blinking Blinking
External operation mode(At power-ON)
First screen (Output frequency*2 monitoring)
PU operation mode PU Jog operation mode
Second screen (Output current*2 monitoring)
Third screen (Output voltage monitoring)
Value change
(Example)
Frequency setting written and complete.
Alternating
The last eight fault records can be displayed. (On the display of the last fault record (fault record 1), a decimal point LED is ON.)
The present setting displayed.
Value change Parameter write complete
Alternating (Example)
(Example) (Example) (Example)
Parameter copy
Initial value change listIPM parameter initialization
Parameter clear All parameter clear Fault history clear
Automatic parameter setting
Trace function
Fault record 1 Fault record 2 Fault record 8
When the fault history is empty, is displayed.
Group parameter setting
Hold down
Parameter settings and protective functions
3.2 Parameter settings and protective functions The setting ranges and specifications of the following parameters and protective functions differ from those of the FR-A800 standard model.
Parameters Pr.30 Regenerative function selection
Available for the built-in brake transistor model only. For details, refer to the FR-A800 Instruction Manual (Detailed).
Pr.570 Multiple rating setting
Pr.260 PWM frequency automatic switchover When the carrier frequency automatic reduction function is used, operation with the carrier frequency set to 3 kHz or higher (Pr.72 3) automatically reduces the carrier frequency for heavy-load operation as shown below.
For details, refer to the FR-A800 Instruction Manual (Detailed).
Protective function
15 ms for the FR-A800 standard model.
NOTE Parameters and protective functions not mentioned above are the same as those of the FR-A800 standard model. For parameters and protective functions not found in
this Instruction Manual, refer to the FR-A800 Instruction Manual (Detailed).
Regeneration unit Power supply terminals of inverter Pr.30 Setting Pr.70 Setting
Without regenerative function R, S, T 0 (initial value), 100
P, N 10, 110 R, S, T/P, N 20, 120
Brake unit (FR-BU2 (MT-BR5)) R, S, T 1, 101
0% (initial value)P, N 11, 111 R, S, T/P, N 21, 121
Brake resistor R, S, T 1, 101
0% (initial value)P, N 11, 111 R, S, T/P, N 21, 121
Power regeneration converter (MT-RC) R, S, T 1, 101 0% (initial value) High power factor converter (FR-HC2) P, N 2, 102
Pr. Name Initial value Setting range
Description (overload current rating, surrounding air temperature)
570 Multiple rating setting 2 0 SLD rating.
110% for 60 seconds, 120% for 3 seconds (inverse-time characteristics) at surrounding air temperature of 40C.
2 ND rating. 150% for 60 seconds, 200% for 3 seconds (inverse-time characteristics) at surrounding air temperature of 40C.
Pr.260 Setting Pr.570 Setting
1 0 (SLD) The carrier frequency will reduce automatically with continuous operation of 50% of the inverter rated current or higher. 2 (ND) The carrier frequency will reduce automatically with continuous operation of 50% of the inverter rated current or higher.
0 0 (SLD) The carrier frequency will reduce automatically with continuous operation of 50% of the inverter rated current or higher.
2 (ND) Without carrier frequency automatic reduction (Perform continuous operation with the carrier frequency set to 2 kHz or lower or with less than 50% of the inverter rated current.)
Operation panel indication E.IPF FR-LU08 indication Instantaneous power
failure
Name Instantaneous power failure
Description
If a power failure occurs (or when power input to the inverter is shut off) for longer than 10 ms, the instantaneous power failure protective function is activated to shut off the inverter output in order to prevent the control circuit from malfunctioning. If a power failure persists for 100 ms or longer, the fault warning output is not provided, and the inverter restarts if the start signal is ON upon power restoration. (The inverter continues operating if an instantaneous power failure is within 10 ms.) In some operating status (load magnitude, acceleration/deceleration time setting, etc.), overcurrent or other protection may be activated upon power restoration. When instantaneous power failure protection is activated, the IPF signal is output.
Check point Find the cause of instantaneous power failure occurrence.
Corrective action Remedy the instantaneous power failure. Prepare a backup power supply for instantaneous power failure. Set the function of automatic restart after instantaneous power failure (Pr.57). (Refer to the FR-A800 Instruction Manual (Detailed).)
4 FAILSAFE SYSTEM WHICH USES THE INVERTER When a fault is detected by the protective function, the protective function activates and output a Fault (ALM) signal. However, a fault signal may not be output at an inverter’s fault occurrence when the detection circuit or output circuit fails, etc. Although Mitsubishi Electric assures the best quality products, provide an interlock which uses inverter status output signals to prevent accidents such as damage to the machine when the inverter fails for some reason. Also, at the same time consider the system configuration where a failsafe from outside the inverter, without using the inverter, is enabled even if the inverter fails.
Interlock method which uses the inverter status output signals By combining the inverter output signals to provide an interlock as shown below, an inverter failure can be detected.
Backup method outside the inverter Even if the interlock is provided by the inverter status signal, enough failsafe is not ensured depending on the failure status of the inverter itself. For example, if an inverter CPU fails in a system interlocked with the inverter’s fault, start, and RUN signals, no fault signal will be output and the RUN signal will be kept ON because the inverter CPU is down. Provide a speed detector to detect the motor speed and current detector to detect the motor current and consider the backup system such as performing a check as below according to the level of importance of the system.
Start signal and actual operation check Check the motor running and motor current while the start signal is input to the inverter by comparing the start signal to the inverter and detected speed of the speed detector or detected current of the current detector. Note that the current is flowing through the motor while the motor coasts to stop, even after the inverter’s start signal is turned OFF. For the logic check, configure a sequence considering the inverter’s deceleration time. In addition, it is recommended to check the three-phase current when using the current detector.
Command speed and actual operation check Check for a gap between the actual speed and commanded speed by comparing the inverter’s speed command and the speed detected by the speed detector.
5 PRECAUTIONS FOR USE OF THE INVERTER The FR-A800 series inverter is a highly reliable product, but incorrect peripheral circuit making or operation/handling method may shorten the product life or damage the product. Before starting operation, always recheck the following points.
Use crimp terminals with insulation sleeves to wire the power supply and the motor. Application of power to the output terminals (U, V, W) of the inverter will damage the inverter. Never perform such wiring. After wiring, wire offcuts must not be left in the inverter.
Wire offcuts can cause an alarm, failure or malfunction. Always keep the inverter clean. When drilling mounting holes in an enclosure etc., take caution not to allow chips and other foreign matter to enter the inverter.
Select a recommended size cable to ensure that the voltage drop ratio is within 2%. If the wiring distance is long between the inverter and motor, a voltage drop in the main circuit will cause the motor torque to decrease especially during the output of a low frequency. Refer to page 20 for the recommended cable gauge.
Keep the total wiring length within the specified length. In long distance wiring, charging currents due to stray capacitance in the wiring may degrade the fast-response current limit operation or cause the equipment on the inverter’s output side to malfunction. Pay attention to the total wiring length. (Refer to Chapter 2 of the Instruction Manual (Detailed).)
Electromagnetic wave interference The input/output (main circuit) of the inverter includes high frequency components, which may interfere with the communication devices (such as AM radios) used near the inverter. In this case, activate the EMC filter (turn ON the EMC filter ON/OFF connector) to minimize interference. (Refer to Chapter 3 of the Instruction Manual (Detailed).)
Interlock method Check method Used signals Refer to
Inverter protective function operation
Operation check of an alarm contact. Circuit error detection by negative logic. Fault output (ALM) signal
Chapter 5 of the Instruction Manual (Detailed)
Inverter operating status Operation ready signal check. Inverter operation ready (RY) signal Chapter 5 of the Instruction Manual (Detailed)
Inverter running status Logic check of the start signal and running signal.
Start signal (STF signal, STR signal) Inverter running (RUN) signal
Chapter 5 of the Instruction Manual (Detailed)
Inverter running status Logic check of the start signal and output current.
Start signal (STF signal, STR signal) Output current detection signal (Y12 signal)
Chapter 5 of the Instruction Manual (Detailed)
Inverter Controller
System failure
To the alarm detection sensor
Sensor (speed, temperature,
air volume, etc.)
28 FAILSAFE SYSTEM WHICH USES THE INVERTER
Electrical corrosion of the bearing When a motor is driven by the inverter, axial voltage is generated on the motor bearing, which may cause electrical corrosion of the bearing in rare cases depending on: condition of the grease used for the bearing, wiring, load, operating conditions of the motor, or specific inverter settings (high carrier frequency, EMC filter ON). Contact your sales representative to take appropriate countermeasures for the motor. The following shows examples of countermeasures for the inverter. Decrease the carrier frequency. Turn OFF the EMC filter. Provide a common mode choke on the output side of the inverter. (This is effective regardless of the EMC filter ON/OFF connector setting.)
Recommended common mode choke: FT-3KM F series FINEMET common mode choke cores manufactured by Hitachi Metals, Ltd. FINEMET is a registered trademark of Hitachi Metals, Ltd.
Do not install a power factor correction capacitor, surge suppressor or capacitor type filter on the inverter’s output side. Doing so will cause the inverter to trip or the capacitor and surge suppressor to be damaged. If any of the above devices is connected, immediately remove it.
For some short time after the power-OFF, a high voltage remains in the smoothing capacitor, and it is dangerous. A smoothing capacitor holds high voltage some time after power-OFF. When accessing the inverter for inspection, wait for at least 10 minutes after the power supply has been switched OFF, and then make sure that the voltage across the main circuit terminals P/+ and N/- of the inverter is low enough using a tester, etc.
If «EV» is displayed on the operation panel, turn OFF the 24 V external power supply before performing wiring. A short circuit or earth (ground) fault on the inverter’s output side may damage the inverter module.
Fully check the insulation resistance of the circuit prior to inverter operation since repeated short circuits caused by peripheral circuit inadequacy or an earth (ground) fault caused by wiring inadequacy or reduced motor insulation resistance may damage the inverter module.
Fully check the to-earth (ground) insulation and phase-to-phase insulation of the inverter’s output side before power-ON. Especially for an old motor or use in hostile atmosphere, securely check the motor insulation resistance, etc.
Do not use the magnetic contactor (MC) on the inverter’s input side to start/stop the inverter. Since repeated inrush currents at power ON will shorten the life of the converter circuit (1,000,000 times for others), frequent starts and stops of the input side MC must be avoided. Turn ON/OFF the inverter’s start signals (STF, STR) to run/stop the inverter. (Refer to page 14.)
Across terminals P/+ and PR, connect only an external brake resistor. Do not connect a mechanical brake.
Do not apply a voltage higher than the permissible voltage to the inverter I/O signal circuits. Application of a voltage higher than the permissible voltage to the inverter I/O signal circuits or opposite polarity may damage the I/O devices. Especially check the wiring to prevent the speed setting potentiometer from being connected incorrectly to short circuit terminals 10E and 5.
If the machine must not be restarted when power is restored after a power failure, provide an MC in the inverter’s input side and also make up a sequence which will not switch ON the start signal.
If the start signal (start switch) remains ON after a power failure, the inverter will automatically restart as soon as the power is restored. Vector control is available with an encoder-equipped motor. And such an encoder must be directly connected to a motor shaft without any
backlash. (Real sensorless vector control does not require an encoder.) MC on the inverter’s input side
On the inverter’s input side, connect an MC for the following purposes. (For the selection, refer to Chapter 2 of the Instruction Manual (Detailed).) To disconnect the inverter from the power supply at activation of a protective function or at malfunctioning of the driving system (emergency stop, etc.). To prevent any accident due to an automatic restart at power restoration after an inverter stop made by a power failure. To separate the inverter from the power supply to ensure safe maintenance and inspection work. If using an MC for emergency stop during operation, select an MC regarding the inverter input side current as JEM 1038-AC-3 class rated current.
Handling of the magnetic contactor on the inverter’s output side Switch the magnetic contactor between the inverter and motor only when both the inverter and motor are at a stop. When the magnetic contactor is turned ON while the inverter is operating, overcurrent protection of the inverter and such will activate. When providing MCs to use the commercial power supply during general-purpose motor operation, switch the MCs after both the inverter and motor stop. A PM motor is a synchronous motor with high-performance magnets embedded inside. High-voltage is generated at the motor terminals while the motor is running even after the inverter power is turned OFF. Before wiring or inspection, confirm that the motor is stopped. In an application, such as fan and blower, where the motor is driven by the load, a low-voltage manual contactor must be connected at the inverter’s output side, and wiring and inspection must be performed while the contactor is open. Otherwise you may get an electric shock.
Countermeasures against inverter-generated EMI If electromagnetic noise generated from the inverter causes the frequency setting signal to fluctuate and the motor rotation speed to be unstable when changing the motor speed with analog signals, the following countermeasures are effective. Do not run the signal cables and power cables (inverter I/O cables) in parallel with each other and do not bundle them. Run signal cables as far away as possible from power cables (inverter I/O cables). Use shielded cables. Install a ferrite core on the signal cable (Example: ZCAT3035-1330 TDK).
Instructions for overload operation When performing frequent starts/stops by the inverter, rise/fall in the temperature of the transistor element of the inverter will repeat due to a repeated flow of large current, shortening the life from thermal fatigue. Since thermal fatigue is related to the amount of current, the life can be increased by reducing current at locked condition, starting current, etc. Reducing current may extend the service life but may also cause torque shortage, which leads to a start failure. Adding a margin to the current can eliminate such a condition. For a general-purpose motor, use an inverter of a higher capacity (up to 2 ranks). For an IPM motor, use an inverter and IPM motor of higher capacities.
Make sure that the specifications and rating match the system requirements.
To use the commercial power supply during general-purpose motor operation, be sure to provide electrical and mechanical interlocks between the electronic bypass contactors MC1 and MC2.
When using a switching circuit as shown right, chattering due to mis-configured sequence or arc generated at switching may allow undesirable current to flow in and damage the inverter. Mis-wiring may also damage the inverter. (The commercial power supply operation is not available with vector control dedicated motors (SF-V5RU, SF- THY) nor with PM motors.)
Power supply
Inverter Undesirable current
MC2
MC1 Interlock
U V W
R/L1 S/L2 T/L3
IM
PRECAUTIONS FOR USE OF THE INVERTER 29
5.1 Power supply harmonics
5.1.1 Power supply harmonics The inverter may generate power supply harmonics from its converter circuit to affect the power generator, power factor correction capacitor, etc. Power supply harmonics are different from noise and leakage currents in source, frequency band and transmission path. Take the following countermeasure suppression techniques.
The differences between harmonics and noises
Countermeasures The harmonic current generated from the inverter to the input side differs according to various conditions such as the wiring impedance, whether a reactor is used or not, and output frequency and output current on the load side. (The FR-A840M inverter has a built-in DC reactor on its DC side.) For the output frequency and output current, we understand that this should be calculated in the conditions under the rated load at the maximum operating frequency.
NOTE The power factor improving capacitor and surge suppressor on the inverter output side may be overheated or damaged by the harmonic components of the inverter
output. Also, since an excessive current flows in the inverter to activate overcurrent protection, do not provide a capacitor and surge suppressor on the inverter output side when the motor is driven by the inverter. For power factor improvement, install a reactor on the inverter input side of the inverter or in the DC circuit.
Item Harmonics Noise Frequency Normally 40th to 50th degrees or less (3 kHz or less). High frequency (several 10 kHz to 1 GHz order). Location To-electric channel, power impedance. To-space, distance, wiring path
Quantitative understanding Theoretical calculation possible. Random occurrence, quantitative grasping difficult.
Generated amount Nearly proportional to the load capacity. Changes with the current variation ratio. (Gets larger as switching speed increases.)
Affected equipment immunity Specified by standards per equipment. Different depending on maker’s equipment specifications. Countermeasure Provide an AC reactor. Increase distance.
AC reactor (FR-HAL) Do not insert power
factor improving capacitor.
MCCB MC
Inverter
Po w
er s
up pl
y
R
S
T Z
Y
X U
V
W
R/L1
S/L2
T/L3
M
30 PRECAUTIONS FOR USE OF THE INVERTER
5.1.2 Harmonic suppression guidelines in Japan Inverters have a converter section (rectifier circuit) and generate a harmonic current. Harmonic currents flow from the inverter to a power receiving point via a power transformer. The Harmonic Suppression Guidelines was established to protect other consumers from these outgoing harmonic currents. The three-phase 200 V input specifications 3.7 kW or lower were previously covered by «the Harmonic Suppression Guidelines for Household Appliances and General-purpose Products» and other models were covered by «the Harmonic Suppression Guidelines for Consumers Who Receive High Voltage or Special High Voltage». However, the transistorized inverter has been excluded from the target products covered by «the Harmonic Suppression Guidelines for Household Appliances and General-purpose Products» in January 2004 and «the Harmonic Suppression Guideline for Household Appliances and General-purpose Products» was repealed on September 6, 2004. All capacity and all models of general-purpose inverter used by specific consumers are now covered by «the Harmonic Suppression Guidelines for Consumers Who Receive High Voltage or Special High Voltage» (hereinafter referred to as «the Specific Consumer Guidelines»). «Specific Consumer Guidelines»
This guideline sets forth the maximum harmonic currents outgoing from a high-voltage or especially high-voltage receiving consumer who will install, add or renew harmonic generating equipment. If any of the maximum values is exceeded, this guideline requires that consumer to take certain suppression measures.
Maximum Values of Outgoing Harmonic Currents per 1 kW Contract Power
Application of the specific consumer guidelines
Conversion factors
Equivalent Capacity Limits
Received power voltage 5th 7th 11th 13th 17th 19th 23rd Over 23rd 6.6 kV 3.5 2.5 1.6 1.3 1.0 0.9 0.76 0.70 22 kV 1.8 1.3 0.82 0.69 0.53 0.47 0.39 0.36 33 kV 1.2 0.86 0.55 0.46 0.35 0.32 0.26 0.24
Classification Circuit type Conversion coefficient Ki
3 Three-phase bridge (Capacitor smoothing)
With reactor (DC side) K33 = 1.8 With reactors (AC, DC sides) K34 = 1.4
5 Self-excitation three-phase bridge When a high power factor converter is used K5 = 0
Received power voltage Reference capacity 6.6 kV 50 kVA 22/33 kV 300 kVA 66 kV or more 2000 kVA
Install, add or renew equipment
Calculation of equivalent capacity total
Equivalent capacity total
Calculation of outgoing harmonic current
Not more than harmonic current upper
limit?
Harmonic suppression measures unnecessary
Harmonic suppression measures necessaryEqual to or less
than upper limit
More than upper limit
Above reference capacity
Equal to or less than reference capacity
PRECAUTIONS FOR USE OF THE INVERTER 31
Harmonic content (Values of the fundamental current is 100%)
Calculation of equivalent capacity P0 of harmonic generating equipment «Equivalent capacity» is the capacity of a 6-pulse converter converted from the capacity of consumer’s harmonic generating equipment and is calculated by the following equation: If the sum of equivalent capacities is higher than the limit (Refer to page 31), harmonics must be calculated with the following procedure:
Calculation of outgoing harmonic current Outgoing harmonic current = fundamental wave current (value converted from received power voltage) operation ratio harmonic content
Operation ratio: Operation ratio = actual load factor operation time ratio during 30 minutes Harmonic content: Refer to page 32.
Rated capacities and outgoing harmonic currents of inverter-driven motors
Determining if a countermeasure is required A countermeasure for harmonics is required if the following condition is satisfied: outgoing harmonic current > maximum value per 1 kW contract power contract power
Harmonic suppression techniques
Reactor 5th 7th 11th 13th 17th 19th 23rd 25th Used (DC side) 30 13 8.4 5.0 4.7 3.2 3.0 2.2 Used (AC, DC sides) 28 9.1 7.2 4.1 3.2 2.4 1.6 1.4
P0 = (Ki Pi) [kVA] Rated capacity: Determined by the capacity of the applied motor and found in the following table. The rated capacity used here is used to calculate the generated harmonic amount and is different from the power supply capacity required for actual inverter drive.
Ki: Conversion coefficient (Refer to page 31) Pi: Rated capacity of harmonic generating equipment [kVA] i: Number indicating the conversion circuit type
Applicable motor (kW)
Fundamental wave current (A)
Fundamental wave current
converted from 6.6 kV (mA)
Rated capacity
(kVA)
Outgoing harmonic current converted from 6.6 kV (mA) (With a DC reactor, 100% operation ratio)
400 V 5th 7th 11th 13th 17th 19th 23rd 25th
75 123 7455 87.2 2237 969.2 626.2 372.8 350.4 238.6 223.7 164 90 147 8909 104 2673 1158 748.4 445.5 418.7 285.1 267.3 196 110 179 10848 127 3254 1410 911.2 542.5 509.9 347.1 325.4 238.7 132 216 13091 153 3927 1702 1100 654.6 615.3 418.9 392.7 288 160 258 15636 183 4691 2033 1313 781.8 734.9 500.4 469.1 344 220 355 21515 252 6455 2797 1807 1076 1011 688.5 645.5 473.3 250 403 24424 286 7327 3175 2052 1221 1148 781.6 732.7 537.3 280 450 27273 319 8182 3545 2291 1364 1282 872.7 818.2 600 315 506 30667 359 9200 3987 2576 1533 1441 981.3 920 674.7 355 571 34606 405 10382 4499 2907 1730 1627 1107 1038 761.3 400 643 38970 456 11691 5066 3273 1949 1832 1247 1169 857.3 450 723 43818 512 13145 5696 3681 2191 2059 1402 1315 964 500 804 48727 570 14618 6335 4093 2436 2290 1559 1462 1072 560 900 54545 638 16363 7091 4582 2727 2564 1745 1636 1200 630 1013 61394 718 18418 7981 5157 3070 2886 1965 1842 1351
No. Item Description
1 Reactor installation (FR-HAL)
Because a DC reactor is built in on the DC side of this product, outgoing harmonic current can be suppressed. By installing an AC reactor (FR-HAL) on the AC side of the inverter, the outgoing harmonic current suppression performance can be improved.
2 High power factor converter (FR-HC2).
This converter trims the current waveform to be a sine waveform by switching the rectifier circuit (converter module) with transistors. Doing so suppresses the generated harmonic amount significantly. Connect it to the DC area of an inverter. Use the high power factor converter (FR-HC2) with the accessories that come as standard.
3 Installation of power factor improving capacitor
When used with a reactor connected in series, the power factor improving correction capacitor can absorb harmonic currents.
4 Transformer multi-phase operation
Use two transformers with a phase angle difference of 30 as in — and — combinations to provide an effect corresponding to 12 pulses, reducing low-degree harmonic currents.
5 Passive filter (AC filter)
A capacitor and a reactor are used together to reduce impedances at specific frequencies. Harmonic currents are expected to be absorbed greatly by using this technique.
6 Active filter This filter detects the current in a circuit generating a harmonic current and generates a harmonic current equivalent to a difference between that current and a fundamental wave current to suppress the harmonic current at the detection point. Harmonic currents are expected to be absorbed greatly by using this technique.
32 PRECAUTIONS FOR USE OF THE INVERTER
Replacement procedure of the cooling fan
6 REPLACEMENT OF PARTS
6.1 Replacement procedure of the cooling fan The replacement interval of the cooling fan used for cooling the parts generating heat such as the main circuit semiconductor is greatly affected by the surrounding air temperature. When unusual noise and/or vibration are noticed during inspection, the cooling fan must be replaced immediately.
NOTE Switch the power OFF before replacing fans. Even after the power supply is shut off, the inverter is charged and can cause an electric shock. Before replacing the fan,
make sure to check that the voltage across inverter main circuit terminals P/+ and N/- has been dropped enough using a tester after 10 minutes or more after the power supply shutoff.
To replace the fan with the cables connected, use a crosshead screwdriver whose length is 25 cm or longer.
6.1.1 Removal (1) Remove the lower main circuit terminal cover. (Refer to page 11) (2) Remove the fan fixing screws.
(3) Slide the fan in the direction shown by the arrow in the following figure. The hooks come off the inverter and the fan can be removed.
Disconnect the fan connector, and remove the fan itself.
Removed
Hook
Hook Fan connector
Replacement procedure of the cooling fan
(4) Remove the screws fixing the fan to the fan cover (tightening torque: 0.73 0.1 Nm), and remove the fan.
6.1.2 Installation (1) After confirming the orientation of the fan, install the fan so that the «AIR FLOW» arrow faces up.
(2) Reverse the removal procedure to reinstall the fan.
NOTE Installing the fan in the opposite direction of air flow may shorten the inverter life. Ensure that the cables are not caught when the fan is installed. Switch OFF the power before starting the fan replacement work. To prevent an electric shock accident, keep the inverter with its covers on during fans replacement
since the inverter circuits are charged with voltage even after power OFF.
AIR FLOW
7 SPECIFICATIONS
7.1 Inverter rating
The applicable motor capacity indicated is the maximum capacity applicable for use of the Mitsubishi Electric 4-pole standard motor. The rated output capacity is the value with respect to 440 V output voltage. The percentage of the overload current rating is the ratio of the overload current to the inverter’s rated output current. For repeated duty, allow time for the inverter and
motor to return to or below the temperatures under 100% load. The maximum output voltage does not exceed the power supply voltage. The maximum output voltage can be changed within the setting range. However, the maximum
point of the voltage waveform at the inverter output side is the power supply voltage multiplied by about . The value when a commercially-available brake resistor is used. (Set the value of %ED in Pr.70 Special regenerative brake duty. For details, refer to page 22.) Value for the ND rating The rated input current is the value at a rated output voltage. The input power impedances (including those of the input reactor and cables) affect the value. The power supply capacity is the value at the rated output current. The input power impedances (including those of the input reactor and cables) affect the value. FR-DU08: IP40 (except for the PU connector) For the power voltage exceeding 480 V, set Pr.977 Input voltage mode selection. (For details, refer to the FR-A800 Instruction Manual (Detailed).) Values measured 1 m in front of the inverter and 1.6 m from the floor.
Model FR-A840M-[] 03630 04540 160K 200K
Applicable motor capacity (kW)
SLD 200 250 ND (initial setting) 160 200
O ut
pu t
Rated capacity (kVA)
SLD 200 250 ND (initial setting) 160 200
Rated current (A) SLD 363 454 ND (initial setting) 293 363
Overload current rating
SLD 110% 60 s, 120% 3 s (inverse-time characteristics) at surrounding air temperature of 40C
ND (initial setting) 150% 60 s, 200% 3 s (inverse-time characteristics) at surrounding air temperature of 40C
Rated voltage Three-phase 380 to 500 V Regenerative braking
Brake transistor Built-in (Built-in brake transistor model only.) Maximum brake torque 100% torque
Po w
er s
up pl
y
Rated input AC voltage/frequency Three-phase 380 to 500 V, 50/60 Hz Permissible AC voltage fluctuation 323 to 550 V, 50/60 Hz Permissible frequency fluctuation 5%
Rated input current (A) SLD 363 454 ND (initial setting) 293 363
Power supply capacity (kVA) SLD 277 346 ND (initial setting) 223 277
Protection rating of structure (IEC 60529) IP20 (IP55 between internal and external air regions) Cooling system Forced air Noise level (dB) 73.4 73.4 Approx. mass (kg) 148 148
2
Outline dimension drawings
7.2 Outline dimension drawings FR-A840M-03630(160K), FR-A840M-04540(200K)
4-12M10 4-24 hole
408
25 6
45 (45) (1 5)
12 20
12 50
(1 5)
450
(1
12 14
18
3.2 22
5-42
36 0
85
Unit mm
48
5-42
300 390
APPENDIX Appendix 1 Differences with the FR-A840
For the installation at an altitude above 1000 m up to 4000 m, consider a 3% reduction in the rated current per 500 m increase in altitude.
Item FR-A840M FR-A840
Surrounding air temperature -10C to +40C (non-freezing) -10C to +50C (non-freezing) for LD, ND (initial setting), or HD rating -10C to +40C (non-freezing) for SLD rating
Altitude 4000 m 2500 m
Vibration Frequency range 10 to 57 Hz: maximum amplitude 0.075 mm. Frequency range 57 to 150 Hz: maximum acceleration speed 1G.
2.9 m/s2 or less at 10 to 55 Hz (in X, Y, and Z directions) for the FR-A840-04320(160K) or higher
Protective structure IP20 (IP55 between internal and external air regions) for all capacities Open type (IP00) for FR-A840-00770(30K) or higher
Brake transistor (brake resistor usable) Built-in brake transistor model is available. Built-in for the FR-A840-00023(0.4K) to 03160(55K)
EMC filter Class C3 filter is built in. (The inverter with a built-in Class C2 filter is also available.) Class C3 filter is built in.
DC reactor Built-in Optional
Noise level (dB) 73.4 61.2 for the FR-A840-04810(185K)
PWM carrier frequency automatic reduction function
(Pr.260 PWM frequency automatic
switchover)
Current value to enable the function for each rating: 50% of the rated current or higher
Current value to enable the function for each rating: 85% of the rated current or higher
Multiple ratings (Pr.570 Multiple rating setting)
SLD and ND (initial setting) ratings (Setting range: «0 or 2»)
SLD, LD, ND (initial setting) and HD ratings (Setting range: «0 to 3»)
Protective function (E.IPF (Instantaneous power
failure)) Activated when a power failure occurs for longer than 10 ms. Activated when a power failure occurs for longer than 15 ms.
Appendix 2 Instructions for compliance with the EU Directives
The EU Directives are issued to standardize different national regulations of the EU Member States and to facilitate free movement of the equipment, whose safety is ensured, in the EU territory. Since 1996, compliance with the EMC Directive that is one of the EU Directives has been legally required. Since 1997, compliance with the Low Voltage Directive, another EU Directive, has been also legally required. When a manufacturer confirms its equipment to be compliant with the EMC Directive and the Low Voltage Directive, the manufacturer must declare the conformity and affix the CE marking. The authorized representative in the EU
The authorized representative in the EU is shown below. Name: Mitsubishi Electric Europe B.V. Address: Mitsubishi-Electric-Platz 1, 40882 Ratingen, Germany
Note We declare that this inverter and the converter unit conform with the EMC Directive in industrial environments and affix the CE marking on the inverter and the
converter unit. When using the inverter in a residential area, take appropriate measures and ensure the conformity of the inverter used in the residential area.
EMC Directive We declare that this inverter conforms with the EMC Directive and affix the CE marking on the inverter. EMC Directive: 2014/30/EU Standard(s): EN 61800-3:2004+A1:2012 (First environment / PDS Category «C2», Second environment / PDS Category «C3») This inverter is not intended to be used on a low-voltage public network which supplies domestic premises. Ensure the converter is suitable for the
environment in which it is to be used when using it in residential areas. Radio frequency interference is expected if used on such a network. The installer shall provide a guide for installation and use, including recommended mitigation devices.
Note: First environment Environment including buildings/facilities which are directly connected to a low voltage main supply which also supplies residential buildings. Directly connected means that there is no intermediate transformer between these buildings. Second environment Environment including all buildings/facilities which are not directly connected to a low voltage main supply which also supplies residential buildings.
Instructions Ensure the EMC filter is enabled, install the product as stated below, and, then carry out any wiring. The inverter has a built-in EMC filter (Class C3). Enable the EMC filter. (Refer to the Instruction Manual (Detailed).) Connect the inverter to an earthed (grounded) power supply. Install the motor and controller cable found in the EMC Installation Manual (BCN-A21041-204) according to the instructions. To make full use of the built-in EMC filter, motor cable lengths should not exceed 20 m. Ensure that the finalized system which includes an inverter complies with the EMC Directive. If the equipment with a built-in Class C2 EMC filter has an input current of 16 A or less, limits for harmonic current emissions of EN/IEC 61000-3-2 shall
apply. However, for professional equipment with a total rated power of 1 kW or higher, the limits for harmonic current emissions of EN/IEC 61000-3-2 shall not apply. If the equipment input current is more than 16 A and does not exceed 75 A, the equipment complies with EN/IEC 61000-3-12 provided that the short-circuit power Ssc is greater than or equal to the value provided in the table below at the interface point between the user’s supply and the public system. It is the responsibility of the installer or user of the equipment to ensure, by consultation with the distribution network operator if necessary, that the equipment is connected only to a supply with a short-circuit power Ssc greater than or equal to the value mentioned in the table below. If the equipment input current is more than 75 A and the power supply capacity is 100 kVA or more, limits for the harmonic current emissions of IEC 61000-3-4 shall apply. However, the equipment complies with IEC 61000-3-4 provided that the short-circuit ratio Rsce is greater than or equal to the value provided
in the table below. Inverter model Standard Ssc Rsce
FR-A840M-03630(160K) IEC 61000-3-4 350
FR-A840M-04540(200K)
Low Voltage Directive We have self-confirmed our inverters as products compliant to the Low Voltage Directive (Conforming standard EN 61800-5-1) and affix the CE marking on the inverters.
Outline of instructions Do not use an earth leakage circuit breaker as an electric shock protector without connecting the equipment to the earth. Connect the equipment to the
earth (ground) securely. Wire the earth terminal independently. (Do not connect two or more cables to one terminal.) Use the cable sizes on page 20 under the following conditions.
Surrounding air temperature: 40C maximum If conditions are different from above, select appropriate wire according to EN 60204. Use a tinned (plating should not include zinc) crimping terminal to connect the earth (ground) cable. When tightening the screw, be careful not to damage
the threads. For use as a product compliant with the Low Voltage Directive, use PVC cable whose size is indicated on page 20.
Use the molded case circuit breaker and magnetic contactor which conform to the EN or IEC Standard. DC current may flow from the inverter to a protective earth (ground) conductor. When using a residual current device (RCD) or residual current monitor
(RCM), connect a type B RCD or RCM to the power supply side. Use the inverter under the conditions of overvoltage category II (usable regardless of the earth (ground) condition of the power supply), overvoltage
category III (usable with the earthed-neutral system power supply, 400 V class only) and pollution degree 2 or lower specified in IEC 60664. — To use the inverter under the conditions of pollution degree 2, install it in the enclosure of IP2X or higher. — To use the inverter under the conditions of pollution degree 3, install it in the enclosure of IP54 or higher.
On the input and output of the inverter, use cables of the type and size set forth in EN 60204. The operating capacity of the relay outputs (terminal symbols A1, B1, C1, A2, B2, and C2) should be 30 VDC, 0.3 A. (Relay output has basic isolation from
the inverter internal circuit.) Control circuit terminals on page 14 are safely isolated from the main circuit.
Environment (For the detail, refer to page 7.)
For installation at an altitude above 1000 m, consider a 3% reduction in the rated current per 500 m increase in altitude.
Wiring protection Provide the appropriate fuse in accordance with the table below.
Short circuit ratings 400 V class Suitable for use in a circuit capable of delivering not more than 100 kA rms symmetrical amperes, 500 V maximum.
Motor overload protection When using the electronic thermal relay function as motor overload protection, set the rated motor current in Pr.9 Electronic thermal O/L relay.
NOTE The internal accumulated heat value of the electronic thermal relay function is reset by inverter power reset and reset signal input. Avoid unnecessary reset and power-
OFF. When multiple motors are driven with a single inverter or when a multi-pole motor or a special motor is driven, install an external thermal relay (OCR) between the
inverter and motors. When configuring an external thermal relay, note that the current indicated on the motor rating plate is affected by the line-to-line leakage current. (Refer to the Instruction Manual (Detailed).)
The cooling effect of the motor drops during low-speed operation. Use a thermal protector or a motor with built-in thermistor. When the difference between the inverter and motor capacities is large and the setting is small, the protective characteristics of the electronic thermal relay function will
be deteriorated. In this case, use an external thermal relay. A special motor cannot be protected by the electronic thermal relay function. Use an external thermal relay. Motor over temperature sensing is not provided by the drive. The electronic thermal memory retention function is not provided by the drive.
During operation Ssc Rsce Surrounding air temperature -10 to +40C -20 to +65C -20 to +65C Humidity 95% RH or less 95% RH or less 95% RH or less Altitude 4000 m 4000 m 10000 m
Fuse type Model Manufacturer Rating FR-A840M-03630(160K) UL recognized semi-conductor fuse 170M6112 Bussmann 700V, 800A FR-A840M-04540(200K) UL recognized semi-conductor fuse 170M6114 Bussmann 700V, 1000A
Operation characteristics of electronic thermal relay function This function detects the overload of the motor, stops the operation of the inverter’s output transistor, and stops the output. (The operation characteristic is shown on the left.) When using the Mitsubishi Electric constant-torque motor
When a value 50% of the inverter rated output current (current value) is set in Pr.9 The % value denotes the percentage to the inverter rated current. It is not the
percentage to the rated motor current. Transistor protection is activated depending on the temperature of the heat sink. The
protection may be activated even with less than 150% depending on the operating conditions.
Range for transistor protection*3
230
52.5% 105%
50 100 150
60
120
180
240
50
60
70
6Hz
20Hz 10Hz
6Hz 0.5Hz
30Hz or more
20Hz 10Hz
0.5Hz
Pr. 9 = 50% setting of inverter rating*1.2
Pr. 9 = 100% setting of inverter rating*1.2
Se co
nd d
is pl
ay in
th is
ra ng
e M
in ut
e di
sp la
y in
th
is ra
ng e
O pe
ra tio
n tim
e (m
in )
O pe
ra tio
n tim
e (s
)
Characteristic when electronic thermal relay function for motor protection is turned off (When Pr. 9 setting is 0(A))
30Hz or more*3
Inverter output current (%) (% to the rated output current)
Operation range Range on the right of characteristic curve Non-operation range Range on the left of characteristic curve
40 Appendix
Appendix 3 Instructions for UL and cUL (Standard to comply with: UL61800-5-1, CSA C22.2No274-13)
General precaution CAUTION — Risk of Electric Shock — The bus capacitor discharge time is 10 minutes. Before starting wiring or inspection, switch power off, wait for more than 10 minutes, and check for residual voltage between terminal P/+ and N/- with a meter etc., to avoid a hazard of electrical shock. ATTENTION — Risque de choc lectrique — La dure de dcharge du condensateur de bus est de 10 minutes. Avant de commencer le cblage ou linspection, mettez lappareil hors tension et attendez plus de 10 minutes.
Installation The below types of inverter have been approved as products for use in enclosure and approval tests were conducted under the following conditions. Design the enclosure so that the surrounding air temperature, humidity and ambience of the inverter will satisfy the specifications. (Refer to page 7.)
Wiring protection Provide the appropriate fuse in accordance with the table below.
Important note The operating capacity of the relay outputs (terminal symbols A1, B1, C1, A2, B2 and C2) should be 30 VDC, 0.3 A. (Relay output has basic isolation from the inverter internal circuit.)
Wiring to the power supply and the motor Refer to the National Electrical Code (Article 310) regarding the allowable current of the cable. Select the cable size for 125% of the rated current according to the National Electrical Code (Article 430). To wire the input (R/L1, S/L2, T/L3) and output (U, V, W) terminals of the inverter, use UL approved copper wires (rated at 75C).
Short circuit ratings Suitable For Use in A Circuit Capable of Delivering Not More Than 100 kA rms Symmetrical Amperes, 500 V Maximum.
Motor overload protection When using the electronic thermal relay function as motor overload protection, set the rated motor current in Pr.9 Electronic thermal O/L relay.
NOTE The internal accumulated heat value of the electronic thermal relay function is reset by inverter power reset and reset signal input. Avoid unnecessary reset and power-
OFF. When multiple motors are driven with a single inverter or when a multi-pole motor or a special motor is driven, install an external thermal relay (OCR) between the
inverter and motors. Note that the current indicated on the motor rating plate is affected by the line-to-line leakage current (details in the Instruction Manual (Detailed)) when selecting the setting for an external thermal relay.
The cooling effect of the motor drops during low-speed operation. Use a thermal protector or a motor with built-in thermistor. When the difference between the inverter and motor capacities is large and the setting is small, the protective characteristics of the electronic thermal relay function will
be deteriorated. In this case, use an external thermal relay. A special motor cannot be protected by the electronic thermal relay function. Use an external thermal relay. Set Pr.9 = «0» for vector-control-dedicated motors (SF-V5RU) because they are equipped with thermal protectors. Motor over temperature sensing is not provided by the drive.
Inverter model Fuse type Model Manufacturer Rating FR-A840M-03630(160K) UL recognized semi-conductor fuse 170M6112 Bussmann 700V, 800A FR-A840M-04540(200K) UL recognized semi-conductor fuse 170M6114 Bussmann 700V, 1000A
Operation characteristics of electronic thermal relay function This function detects the overload (overheat) of the motor, stops the operation of the inverter’s output transistor, and stops the output. (The operation characteristic is shown on the left.) When using the Mitsubishi Electric constant-torque motor (1) Set one of «1, 13 to 16, 50, 53, 54» in Pr.71. (This provides a 100% continuous torque
characteristic in the low-speed range.) (2) Set the rated current of the motor in Pr.9.
When a value 50% of the inverter rated output current (current value) is set in Pr.9 The % value denotes the percentage to the inverter rated current. It is not the
percentage to the rated motor current. When you set the electronic thermal relay function dedicated to the Mitsubishi Electric
constant-torque motor, this characteristic curve applies to operation at 6 Hz or higher. Transistor protection is activated depending on the temperature of the heat sink. The
protection may be activated even with less than 150% depending on the operating conditions.
Range for transistor protection*3
230
52.5% 105%
50 100 150
60
120
180
240
50
60
70
6Hz
20Hz 10Hz
6Hz 0.5Hz
30Hz or more
20Hz 10Hz
0.5Hz
Pr. 9 = 50% setting of inverter rating*1.2
Pr. 9 = 100% setting of inverter rating*1.2
Se co
nd d
is pl
ay in
th is
ra ng
e M
in ut
e di
sp la
y in
th
is ra
ng e
O pe
ra tio
n tim
e (m
in )
O pe
ra tio
n tim
e (s
)
Characteristic when electronic thermal relay function for motor protection is turned off (When Pr. 9 setting is 0(A))
30Hz or more*3
Inverter output current (%) (% to the rated output current)
Operation range Range on the right of characteristic curve Non-operation range Range on the left of characteristic curve
Appendix 41
Appendix 4 Instructions for EAC
The product certified in compliance with the Eurasian Conformity has the EAC marking.
Note: EAC marking In 2010, three countries (Russia, Belarus, and Kazakhstan) established a Customs Union for the purposes of revitalizing the economy by forming a large economic bloc by abolishing or reducing tariffs and unifying regulatory procedures for the handling of articles. Products to be distributed over these three countries of the Customs Union must comply with the Customs Union Technical Regulations (CU-TR), and the EAC marking must be affixed to the products.
For information on the country of origin, manufacture year and month, and authorized sales representative (importer) in the CU area of this product, refer to the following:
Country of origin indication Check the rating plate of the product. (Refer to page 3.) Example: MADE IN JAPAN
Manufactured year and month Check the SERIAL number indicated on the rating plate of the product. (Refer to page 3.)
Authorized sales representative (importer) in the CU area The authorized sales representative (importer) in the CU area is shown below. Name: Mitsubishi Electric (Russia) LLC Address: 52, bld 1 Kosmodamianskaya Nab 115054, Moscow, Russia Phone: +7 (495) 721-2070 Fax: +7 (495) 721-2071
Rating plate example
Symbol Year Month Control number SERIAL
The SERIAL consists of one symbol, two characters indicating the production year and month, and six characters indicating the control number. The last digit of the production year is indicated as the Year, and the Month is indicated by 1 to 9, X (October), Y (November), or Z (December).
42 Appendix
Appendix 5 Restricted Use of Hazardous Substances in Electronic and Electrical Products
The mark of restricted use of hazardous substances in electronic and electrical products is applied to the product as follows based on the Management Methods for the Restriction of the Use of Hazardous Substances in Electrical and Electronic Products of the People’s Republic of China.
SJ/T11364 GB/T26572 GB/T26572
Appendix 6 Referenced Standard (Requirement of Chinese standardized law)
This Product is designed and manufactured accordance with following Chinese standards.
Machinery safety : GB/T 16855.1 GB/T 12668.502 GB 28526 GB/T 12668.3
Electrical safety : GB/T 12668.501 EMC : GB/T 12668.3
(Pb)
(Hg)
(Cd)
(Cr(VI))
(PBB)
(PBDE)
43
WARRANTY
When using this product, make sure to understand the warranty described below.
1. Warranty period and coverage We will repair any failure or defect (hereinafter referred to as «failure») in our FA equipment (hereinafter referred to as the «Product») arisen during warranty period at no charge due to causes for which we are responsible through the distributor from which you purchased the Product or our service provider. However, we will charge the actual cost of dispatching our engineer for an on-site repair work on request by customer in Japan or overseas countries. We are not responsible for any on-site readjustment and/or trial run that may be required after a defective unit are repaired or replaced.
[Term] The term of warranty for Product is twelve months after your purchase or delivery of the Product to a place designated by you or eighteen months from the date of manufacture whichever comes first («Warranty Period»). Warranty period for repaired Product cannot exceed beyond the original warranty period before any repair work.
[Limitations] (1) You are requested to conduct an initial failure diagnosis by yourself, as a general rule. It can also be carried out by us or our service company upon your
request and the actual cost will be charged. However, it will not be charged if we are responsible for the cause of the failure.
(2) This limited warranty applies only when the condition, method, environment, etc. of use are in compliance with the terms and conditions and instructions that are set forth in the instruction manual and user manual for the Product and the caution label affixed to the Product.
(3) Even during the term of warranty, the repair cost will be charged on you in the following cases; a failure caused by your improper storing or handling, carelessness or negligence, etc., and a failure caused by your hardware or software problem a failure caused by any alteration, etc. to the Product made on your side without our approval a failure which may be regarded as avoidable, if your equipment in which the Product is incorporated is equipped with a safety device required by
applicable laws and has any function or structure considered to be indispensable according to a common sense in the industry a failure which may be regarded as avoidable if consumable parts designated in the instruction manual, etc. are duly maintained and replaced any replacement of consumable parts (condenser, cooling fan, etc.) a failure caused by external factors such as inevitable accidents, including without limitation fire and abnormal fluctuation of voltage, and acts of
God, including without limitation earthquake, lightning and natural disasters a failure generated by an unforeseeable cause with a scientific technology that was not available at the time of the shipment of the Product from our
company any other failures which we are not responsible for or which you acknowledge we are not responsible for
2. Term of warranty after the stop of production (1) We may accept the repair at charge for another seven (7) years after the production of the product is discontinued. The announcement of the stop of
production for each model can be seen in our Sales and Service, etc. (2) Please note that the Product (including its spare parts) cannot be ordered after its stop of production.
3. Service in overseas Our regional FA Center in overseas countries will accept the repair work of the Product; however, the terms and conditions of the repair work may differ depending on each FA Center. Please ask your local FA center for details.
4. Exclusion of loss in opportunity and secondary loss from warranty liability Regardless of the gratis warranty term, Mitsubishi Electric shall not be liable for compensation to: (1) Damages caused by any cause found not to be the responsibility of Mitsubishi Electric. (2) Loss in opportunity, lost profits incurred to the user by Failures of Mitsubishi Electric products. (3) Special damages and secondary damages whether foreseeable or not, compensation for accidents, and compensation for damages to products other
than Mitsubishi Electric products. (4) Replacement by the user, maintenance of on-site equipment, start-up test run and other tasks.
5. Change of Product specifications Specifications listed in our catalogs, manuals or technical documents may be changed without notice.
6. Application and use of the Product (1) For the use of our product, its applications should be those that may not result in a serious damage even if any failure or malfunction occurs in product,
and a backup or fail-safe function should operate on an external system to product when any failure or malfunction occurs. (2) Our product is designed and manufactured as a general purpose product for use at general industries.
Therefore, applications substantially influential on the public interest for such as atomic power plants and other power plants of electric power companies, and also which require a special quality assurance system, including applications for railway companies and government or public offices are not recommended, and we assume no responsibility for any failure caused by these applications when used. In addition, applications which may be substantially influential to human lives or properties for such as airlines, medical treatments, railway service, incineration and fuel systems, man-operated material handling equipment, entertainment machines, safety machines, etc. are not recommended, and we assume no responsibility for any failure caused by these applications when used. We will review the acceptability of the abovementioned applications, if you agree not to require a specific quality for a specific application. Please contact us for consultation.
44
About the enclosed CD-ROM The enclosed CD-ROM contains PDF copies of the manuals related to this product.
Before using the enclosed CD-ROM The copyright and other rights of the enclosed CD-ROM all belong to Mitsubishi Electric Corporation. No part of the enclosed CD-ROM may be copied or reproduced without the permission of Mitsubishi Electric Corporation. Specifications of the enclosed CD-ROM are subject to change for modification without notice. We are not responsible for any damages and lost earnings, etc. from use of the enclosed CD-ROM. Trademarks
Microsoft, Windows, Windows Vista, and Internet Explorer are either registered trademarks or trademarks of Microsoft Corporation in the United States and/or other countries. Adobe and Adobe Reader are either registered trademarks or trademarks of Adobe Systems Incorporated in the United States and/or other countries. Intel and Pentium are trademarks of Intel Corporation in the United States and/or other countries. Other company and product names of companies herein are all trademarks or registered trademarks of those respective companies.
Warranty We do not provide a warranty against defects in the enclosed CD-ROM and related documents.
NOTE This is a personal computer dedicated CD-ROM. Do not attempt to play it on ordinary audio devices. The loud volume may damage hearing and speakers.
System requirements for the enclosed CD-ROM The following system is required to read instruction manuals contained in the enclosed CD-ROM.
Operating method of the enclosed CD-ROM How to read instruction manuals
Step 1. Start the personal computer and place the enclosed CD-ROM in the CD-ROM drive. Step 2. The main window will automatically open in the web browser. Step 3. Choose your language from a language menu. Step 4. Click the manual you want to read in the «INSTRUCTION MANUAL» list. Step 5. The PDF manual will open.
Manual opening of the enclosed CD-ROM Step 1. Start the personal computer and place the enclosed CD-ROM in the CD-ROM drive. Step 2. Open the «index.html» file. Step 3. The main window will open in the web browser. Follow the previous steps from Step 3 to Step 5.
PDF data of the instruction manual are stored in «MANUAL» folder on the enclosed CD-ROM.
Item Specifications
OS Microsoft Windows 10, Windows 8.1, Windows 8, Windows 7, Windows Vista
CPU Intel Pentium or better processor
Memory 128 MB of RAM
Hard disk 90 MB of available hard-disk space
CD-ROM drive Double speed or more (more than quadruple speed is recommended)
Monitor 800600 dots or more
Application Adobe Reader 7.0 or more Internet Explorer 6.0 or more
45
REVISIONS *The manual number is given on the bottom left of the back cover.
Revision date *Manual number Revision
Aug. 2020 IB-0600932-A First edition
1 BCN-C22005-957
FR-A800/A800 Plus Series Instruction Manual Supplement
1 Emergency drive
This function is used in case of emergency such as a fire to forcibly continue inverter operation to drive a motor without activating protective functions even if the inverter detects a fault. Using this function may cause damage of the motor or the inverter because driving the motor is given the highest priority. Use this function for emergency operation only. When the inverter is damaged by a fault, the motor operation can be continued by switching to the commercial power supply operation. The emergency drive function is available only for standard structure models and IP55 compatible models.
*1 The setting is available for the standard structure model and the IP55 compatible model. *2 Set Pr.524 after setting Pr.523. *3 When Pr.523 = «100, 200, 300, or 400», the emergency drive is activated regardless of the Pr.524 setting.
Pr. Name Initial value
Setting range Description FM CA
523 H320*1
Emergency drive mode selection 9999
100, 111, 112, 121, 122, 123, 124, 200, 211, 212, 221, 222, 223, 224, 300, 311, 312, 321, 322, 323, 324, 400, 411, 412, 421, 422, 423, 424
Select the operation mode of the emergency drive.
9999 Emergency drive disabled.
524 H321*1*2
Emergency drive running speed 9999
0 to 590 Hz*3 Set the running frequency in the fixed frequency mode of the emergency drive (when the fixed frequency mode is selected in Pr.523)
0% to 100%*3 Set the PID set point in the PID control mode of the emergency drive (when the PID control mode is selected in Pr.523)
9999*3 Emergency drive disabled.
515 H322*1
Emergency drive dedicated retry count
1 1 to 200 Set the retry count during emergency drive operation.
9999*3 Without retry count excess (no restriction on the number of retries).
1013 H323*1
Emergency drive running speed after retry reset
60 Hz 50 Hz 0 to 590 Hz Set the frequency for operation after a retry when any of E.CPU, E.1 to E.3, and E.5 to E.7 occurs during emergency drive operation.
514 H324*1
Emergency drive dedicated waiting time
9999 0.1 to 600 s Set the retry waiting time during emergency drive
operation. 9999 The Pr.68 setting is applied to the operation.
136 A001
MC switchover interlock time 1 s 0 to 100 s Set the operation interlock time for MC2 and MC3.
139 A004
Automatic switchover frequency from inverter to bypass operation
9999 0 to 60 Hz
Set the frequency at which the inverter-driven operation is switched over to the commercial power supply operation when the condition for the electronic bypass is established during emergency drive operation.
8888, 9999 Electronic bypass during emergency drive is disabled.
57 A702
Restart coasting time 9999
0
Coasting time differs according to the inverter capacity. (Refer to the description of the automatic restart after instantaneous power failure function in the Instruction Manual (Detailed) or the Instruction Manual (Function).)
0.1 to 30 s Set the waiting time for the inverter to perform a restart after restoring power due to an instantaneous power failure.
9999 No restart
V/F Magnetic flux Sensorless PM
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Connection diagram A connection diagram of the emergency drive (commercial mode) is as follows.
*1 Be careful of the capacity of the sequence output terminals. The applied terminals differ by the settings of Pr.190 to Pr.196 (Output terminal function selection).
*2 When connecting a DC power supply, insert a protective diode. When connecting an AC power supply, use relay output terminals of the inverter or contact output terminals of the relay output option (FR-A8AR).
*3 The applied terminals differ by the settings of Pr.180 to Pr.189 (Input terminal function selection) *4 The applied terminals differ by the settings of Pr.190 to Pr.196 (Output terminal function selection).
NOTE Be sure to provide a mechanical interlock for MC2 and MC3.
Output terminal capacity Output terminal permissible load Open collector output of inverter (RUN, SU, IPF, OL, FU) 24 VDC 0.1 A
Inverter relay output (A1-C1, B1-C1, A2-B2, B2-C2) Relay output option (FR-A8AR)
230 VAC 0.3 A 30 VDC 0.3 A
Emergency drive execution
IM R/L1 S/L2 T/L3
X84
Emergency drive in operation
Fault output during emergency drive
CS
RES
SD
U V W
Y65
MC2
SE
MC3
MC2 24VDC
Reset
MC3
Inverter/bypass
MCCB
MC2
MC3
MC2
MC3
ALM3
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Emergency drive execution sequence
When the X84 signal is ON for 3 seconds, the emergency drive is activated. The Y65 signal turns ON during emergency drive operation. «ED» appears on the operation panel during emergency drive operation. The ALM3 signal turns ON when a fault occurs during emergency drive operation.
To activate the emergency drive, the X84 signal needs to be ON for three seconds while all the following conditions are satisfied.
When the «retry» (Pr.523 = «2[][], 3[][]») is selected, it is recommended to use the automatic restart after instantaneous power failure function at the same time.
Parameter setting is not available during emergency drive operation. To return to the normal operation during emergency drive operation, do the following. (The operation will not be
returned to normal only by turning OFF the X84 signal.) Reset the inverter, or turn the power supply OFF. Clear a fault by turning ON the X51 signal while the sequence function is enabled (when the protective function is activated).
The operation is switched over to the commercial power supply operation in case of the following during emergency drive operation while the commercial mode or the retry / commercial mode is selected. 24 V external power supply operation, power failure status or operation with the power supplied through R1/S1 (except when the DC feeding mode 1 or 2 is selected), undervoltage
To input the X84 signal, set «84» in any of Pr.178 to Pr.189 (Input terminal function selection) to assign the function.
For the terminal used for the Y65 signal output, assign the function by setting «65 (positive logic)» or «165 (negative logic)» in any of Pr.190 to Pr.196 (Output terminal function selection). For the terminal used for the ALM3 signal output, assign the function by setting «66 (positive logic)» or «166 (negative logic)» in any of Pr.190 to Pr.196 (Output terminal function selection).
The X84 signal input is valid either through the external terminal or via network regardless of the Pr.338 and Pr.339 settings (Selection of control source in Network operation mode).
During emergency drive operation, the operation is performed as Pr.502 Stop mode selection at communication error = «0 (initial value)» and communication errors (such as E.SER) do not occur. (A protective function is performed according to its operation during emergency drive operation.)
Item Condition Emergency drive parameter settings
Pr.523 «9999» Pr.524 «9999» (Setting is not required when Pr.523 = «100, 200, 300, or 400».)
Control method
Either of the following control methods is selected (when Pr.800 = «9, 10, 20, 109, or 110» or Pr.451 = «10, 20, 110, or 9999») V/F control Advanced magnetic flux vector control Real sensorless vector control (speed control) PM sensorless vector control (speed control) PM sensorless vector control test operation
Contradictory condition
None of the following conditions are satisfied. Enabling the electronic bypass sequence function Enabling the brake sequence function Using the FR-A8NS (option) During offline auto tuning Supplying power through terminals R1 and S1 Pr.30 = «2, 102»
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The following diagram shows the operation of the emergency drive function (in the retry / output shutoff mode or in the fixed frequency mode (Pr.523 = «211»)).
The following diagram shows the operation of switching over to the commercial power supply operation during emergency drive operation by using the CS signal (when the electronic bypass during emergency drive operation is enabled) (in the commercial mode or in the fixed frequency mode (Pr.523 = «411»)).
*1 Input the CS signal via an external terminal.
NOTE The emergency drive function is not available for the FR-A800-CRN and FR-B, B3 series inverters.
Continuous operation except in case of critical faults (such as E.PUE)
Coasting
RES
X84
STF
ALM3
Time
Motor rotations per minute
Retry waiting time Pr.514
Emergency drive in operation Y65
Retry in case of critical faults
Normal operation
Emergency drive continued
ALM
Frequency
Pr.524
3s
Emergency drive finished
ON
ON
ON
ON
ON
ON
ON
3s
Emergency drive continued
Normal operation
Coasting
Power supply
STF
X84
CS*1
MC3
MC2
MC3
MC2
Frequency
Pr.136
Time
Motor rotations per minute
Emergency drive commercial power supply operation
Emergency drive in operation Y65
MC delay
MC delay
ON
ON
ON
ON
ON
ON
ON
ON
ON
ON
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Emergency drive operation selection (Pr.523, Pr.524) Use Pr.523 Emergency drive mode selection to select the emergency drive operation. Set a value in the
hundreds place to select the operation when a valid protective function is activated (critical fault) during emergency drive. Set values in the ones and tens places to select the operation method.
*1 Under PM sensorless vector control, the operation is not switched over to the commercial power supply operation and the output is shut off.
NOTE The operation is automatically switched from the PU operation mode or External/PU combined operation mode to
the External operation mode when the emergency drive is activated in the fixed frequency mode or in the PID control mode.
Retry operation during emergency drive (Pr.515, Pr.514) Set the retry operation during emergency drive operation. Use Pr.515 Emergency drive dedicated retry count
to set the retry count, and use Pr.514 Emergency drive dedicated waiting time to set the retry waiting time. The ALM signal output conditions depend on the Pr.67 Number of retries at fault occurrence setting. (Refer to
the description of the retry function in the Instruction Manual (Detailed) or the Instruction Manual (Function).) For the protective functions (critical faults) for which a retry is performed during emergency drive operation, refer
to page 7.
NOTE During emergency drive operation, Pr.65 Retry selection is not available.
Pr.523 setting Emergency drive operation mode Description
1[][] Output shutoff mode
Selecting operation when a critical fault occurs during emergency drive operation
Output shutoff at a critical fault occurrence.
2[][] Retry / output shutoff mode
Retry operation at a critical fault occurrence. (Output shutoff at the occurrence of a fault for which retry is not permitted.) The output is shut off when a critical fault for which retry is not permitted occurs, or the retry count is exceeded.
3[][]*1 Retry / commercial mode
Retry operation at a critical fault occurrence. (Electronic bypass at the occurrence of a critical fault for which retry is not permitted.) The operation is switched over to the commercial power supply operation when a critical fault for which retry is not permitted occurs, or the retry count is exceeded. While Pr.515 = «9999», the operation is switched over to the commercial power supply operation when the retry count reaches 200.
4[][]*1 Commercial mode The operation is switched over to the commercial power supply operation when a critical fault occurs.
[]00 Normal operation
Selecting the operation method during emergency drive operation
The operation is performed with the same set frequency and by the same starting command as those in the normal operation. Use this mode to avoid output shutoff due to a fault.
[]11 Fixed frequency mode
Forward rotation The operation is forcibly performed with the frequency set in Pr.524. Even when the motor is stopped, the operation is started by the emergency drive operation.
[]12 Reverse rotation
[]21
PID control mode
Forward rotation The operation is performed under PID control using the Pr.524 setting as a set point. The measured values are input in the method set in Pr.128.[]22 Reverse rotation
[]23 Forward rotation (Second PID measured value input) The operation is performed under PID control using the
Pr.524 setting as a set point. The measured values are input in the method set in Pr.753.
[]24 Reverse rotation (Second PID measured value input)
9999 Emergency drive disabled.
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Electronic bypass during emergency drive (Pr.136, Pr.139, Pr.57) For selecting the commercial mode (Pr.523 = «3[][], 4[][]»), setting is required as follows.
Set Pr.136 MC switchover interlock time and Pr.139 Automatic switchover frequency from inverter to bypass operation and assign MC2 and MC3 signals to output terminals. When the CS signal is assigned to an input terminal, set Pr.57 Restart coasting time «9999» and input the CS signal through the terminal. (In the initial setting, the CS signal is assigned to the terminal CS.) Select V/F control, Advanced magnetic flux vector control, or Real sensorless vector control. (Under PM sensorless vector control, the operation is not switched over to the commercial power supply operation the output is shut off.)
During emergency drive operation, the operation is switched over to the commercial power supply operation when any of the following conditions is satisfied. CS signal turns OFF. A critical fault for which retry is not permitted occurs while Pr.523 = «3[][]». A critical fault occurs while Pr.523 = «4[][]».
While the motor is driven by the inverter during emergency drive operation, if a condition for electronic bypass is satisfied, the output frequency is accelerated/decelerated to the Pr.139 setting. When the frequency reaches the set frequency, the operation is switched over to the commercial power supply operation. (The operation is immediately switched over to the commercial power supply operation during output shutoff due to a critical fault occurrence.)
If the parameter for electronic bypass is not set while the commercial mode is set (Pr.523 = «3[][], 4[][]»), the operation is not switched over to the commercial power supply operation even when a condition for switchover is satisfied, and the output is shut off.
To assign the MC2 and MC3 signals to output terminals, use any two of Pr.190 to Pr.196 (Output terminal function selection) and set «18 (positive logic)» for the MC2 signal and set «19 (positive logic)» for the MC3 signal.
Operation of magnetic contactor (MC2, MC3)
The input signals are as follows.
*1 Input the CS signal via an external terminal. (Set Pr.162 = «0 to 3, 10 to 13» or Pr.338 = «1».) *2 If the signal is turned ON after switchover to the emergency drive commercial power supply operation, the operation will not be
returned to the inverter-driven operation. *3 If the signal is turned OFF during the emergency drive operation, the operation will not be returned to normal. *4 MC operation is as follows.
NOTE During electronic bypass operation while the electronic bypass sequence is enabled (Pr.135 = «1»), the emergency
drive function is not available.
Magnetic contactor Installation location
Operation During commercial power
supply operation During inverter operation
MC2 Between power supply and motor Shorted Open MC3 Between inverter output side and motor Open Shorted
Signal Function Operation MC operation*4
MC2 MC3
CS*1 Inverter/bypass ON: Inverter operation OFF: Emergency drive commercial power supply operation*2
X84 Emergency drive operation ON: Emergency drive operation
OFF: Normal operation*3
RES Operation status reset ON: Reset No change OFF: Normal operation
Notation MC operation ON OFF
During inverter operation: MC2-OFF, MC3-ON During commercial power supply operation: MC2-ON, MC3-OFF
No change The operation status before changing the signal state to ON or OFF is held.
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PID control during emergency drive operation During emergency drive operation in the PID control mode, the operation is performed under PID control using
the Pr.524 setting as a set point. Input the measured values in the method set in Pr.128 or Pr.753. When the PID control mode is selected for emergency drive, the PID action during emergency drive operation is
as follows depending on the PID control setting.
While the «retry» (Pr.523 = «22[], 32[]») is selected in the PID control mode, if a retry occurs at an occurrence of E.CPU, E.1 to E.3, or E.5 to E.7 during emergency drive operation, the operation is performed not under PID control but with the fixed frequency. Use Pr.1013 Emergency drive running speed after retry reset to set the fixed frequency.
Operation of protective functions during emergency drive Operation of protective functions during emergency drive is as follows.
*1 While the switchover to the commercial power supply operation during emergency drive operation is enabled, when the same protective function is activated twice consecutively, the retry is attempted up to twice.
*2 In normal operation (Pr.523 = «200 or 300»), the start signal is turned OFF at the same time the retry function resets the protective function. Input the start signal again to resume the operation.
Item PID control action
Set point / measured value input setting Deviation input setting Without PID control
setting Measured value input selection (Pr.128, Pr.753) Held Terminal 4 input Terminal 4 input Forward action / reverse action selection (Pr.128, Pr.753) Held Held Reverse action
Proportional band (Pr.129, Pr.756) Held Held 100% (initial value) Integral time (Pr.130, Pr.757) Held Held 1 s (initial setting) Differential time (Pr.134, Pr.758) Held Held Not used (initial setting) Applied to the frequency / calculation only (Pr.128, Pr.753) Applied to the frequency Applied to the frequency Applied to the frequency
Dancer control Invalid Invalid Invalid Other PID-related settings Held Held Held
Protective function
Operation during emergency drive
Protective function
Operation during emergency drive
Protective function
Operation during emergency drive
E.OC1 Retry E.OP3 The function is disabled. E.ECA The function is disabled. E.OC2 Retry E.16 The function is disabled. E.MB1 The function is disabled. E.OC3 Retry E.17 The function is disabled. E.MB2 The function is disabled. E.OV1 Retry E.18 The function is disabled. E.MB3 The function is disabled. E.OV2 Retry E.19 The function is disabled. E.MB4 The function is disabled. E.OV3 Retry E.20 The function is disabled. E.MB5 The function is disabled. E.THT Retry E.PE Output shutoff E.MB6 The function is disabled. E.THM Retry E.PUE The function is disabled. E.MB7 The function is disabled. E.FIN Retry E.RET Output shutoff E.EP The function is disabled. E.IPF The function is disabled. E.PE2 Output shutoff E.MP The function is disabled. E.UVT The function is disabled. E.CPU Retry E.EF The function is disabled. E.ILF The function is disabled. E.CTE The function is disabled. E.IAH The function is disabled. E.OLT Retry E.P24 The function is disabled. E.LCI The function is disabled. E.SOT Retry E.CDO Retry E.PCH The function is disabled. E.LUP The function is disabled. E.IOH Output shutoff E.PID The function is disabled. E.LDN The function is disabled. E.SER The function is disabled. E.1 Retry*2
E.BE Retry*1 E.AIE The function is disabled. E.2 Retry*2
E.GF Retry E.USB The function is disabled. E.3 Retry*2
E.LF The function is disabled. E.SAF Retry*1 E.5 Retry*2
E.OHT Retry E.PBT Retry*1 E.6 Retry*1*2
E.PTC Retry E.OS The function is disabled. E.7 Retry*1*2
E.OPT The function is disabled. E.OSD The function is disabled. E.11 The function is disabled. E.OP1 The function is disabled. E.ECT The function is disabled.
E.13 Output shutoff E.OP2 The function is disabled. E.OD The function is disabled.
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The fault output during emergency drive operation is as follows.
Input signal operation During emergency drive operation in the fixed frequency mode or in the PID control mode, input signals unrelated
to the emergency drive become invalid with some exceptions. The following table shows functions of the signals that do not become invalid during emergency drive operation
in the fixed frequency mode or in the PID control mode.
*1 The signal is available only for the FR-A800-LC.
Emergency drive status monitor Set «68» in Pr.52, Pr.774 to Pr.776, Pr.992 to monitor the status of the emergency drive on the operation panel. Description of the status monitor
*1 The first digit remains the same as the previous numerical value (fault condition). *2 «A certain alarm» means a protective function disabled during emergency drive shown in the tables on page 7.
Signal Pr.190 to Pr.196 setting
DescriptionPositive logic
Negative logic
ALM 99 199 Turns ON at the occurrence of a fault that causes the above-mentioned «retry» or «output shutoff» during emergency drive operation.
ALM3 66 166 Output when a fault occurs during emergency drive operation. During emergency drive operation, if a fault that does not activate any protective function occurs, the signal turns ON for 3 seconds and then turns OFF.
Input signal status Fixed frequency mode PID control mode
Valid OH, X31*1, X32, X41*1, TRG, TRC, X51, RES, X70, X71
OH, X31*1, X32, X41*1, TRG, TRC, X51, RES, X70, X71
Held RT, X9, X17, X18, MC, SQ, X84 RT, X9, X17, X18, MC, SQ, X64, X65, X66, X67, X79, X84
Always-ON X14, X77, X78, X80
Operation panel
indication
Description
Emergency drive setting Emergency drive operating status
0 Emergency drive function setting is not available.
1
Electronic bypass during emergency drive operation is disabled.
During normal operation 2
Emergency drive in operation
Operating properly 3 A certain alarm is occurring.*2
4 A critical fault is occurring. The operation is being continued by the retry.
5 A critical fault is occurring. The continuous operation is not allowed due to output shutoff.
11
Electronic bypass during emergency drive operation is enabled.
During normal operation 12
Emergency drive in operation
Operating properly 13 A certain alarm is occurring.*2
14 A critical fault is occurring. The operation is being continued by the retry.
15 A critical fault is occurring. The continuous operation is not allowed due to output shutoff.
2[]*1 Electronic bypass is started during emergency drive (during acceleration/ deceleration to the switchover frequency).
3[]*1 During electronic bypass during emergency drive (waiting during the interlock time).
4[]*1 During commercial power supply operation during emergency drive
CAUTION When the emergency drive operation is performed, the operation is continued or the retry is repeated even when
a fault occurs, which may damage or burn the inverter and motor. Before restarting the normal operation after using this function, make sure that the inverter and motor have no fault. Any damage of the inverter or the motor caused by using the emergency drive function is not covered by the warranty even within the guarantee period.
BCN-C22005-957_ENG.fm 8
9 BCN-C22005-957
2 Forward rotation output (Y30) signal and Reverse rotation output (Y31) signal
The Forward rotation output (Y30) signal and Reverse rotation output (Y31) signal become available under encoder feedback control.
Under Vector control or encoder feedback control, the Forward rotation output (Y30) signal or the Reverse rotation output (Y31) signal is output according to the actual rotation direction of the motor.
NOTE For the details on the Y30 and Y31 signals, refer to the Instruction Manual (Detailed) or the Instruction Manual
(Function).
BCN-C22005-957_ENG.fm 9
1 BCN-C22005-969
FR-A800/A800 Plus Series Instruction Manual Supplement
1 Internal storage device fault (E.PE6) The operation of the storage device in the inverter can be checked. If a data fault occurs in the storage device in the inverter, the protective function (E.PE6) is activated. When the read value of Pr.890 is «7» or smaller, an inverter reset after All parameter clear can return the operation to normal. (The parameters that had been changed before All parameter clear must be set again.)
*1 For example, when parameter clear, All parameter clear, Parameter copy, or offline auto tuning is performed in the inverter, or when parameter batch write is performed in FR Configurator2.
NOTE «E.PE6» does not activate the retry function. «E.PE6» outputs the Fault output 3 (Y91) signal. «E.PE6» turns OFF the Safety monitor output (SAFE) signal. «E.PE6» is not cleared by turning ON the Fault clear (X51) signal. «E.PE6» is not activated during emergency drive operation. The communication data code for «E.PE6» is 172 (HAC).
Checking faulty area in the internal storage device When E.PE6 occurs, faulty area in the internal storage device can be checked by reading Pr.890.
Use the read value of Pr.890 to check the faulty area. The following table shows faulty areas indicated by the read value of Pr.890. Some read values indicate that there are multiple
faulty areas. (For example, the read value «7» indicates that all the areas described in No. 1 to No. 3 are faulty.)
Operation panel indication E.PE6 FR-LU08
indication Fault
Name Internal storage device fault
Description This protective function is activated by an inverter reset if writing data fails due to power-OFF or a data fault occurs in the storage device during parameter operations*1.
Check point Check if the power was turned OFF during parameter operations.
Corrective action
Check the power supply or the devices on the power system to check that the devices have no fault. When E.PE6 occurs due to power-OFF during parameter operations:
Check the read value of Pr.890. When the value is «7» or smaller, perform All parameter clear and then an inverter reset. The parameters that had been changed before All parameter clear must be set again.
When E.PE6 occurs due to other reason (such as turning OFF/ON the power or an inverter reset): Contact your sales representative.
Pr. Name Initial value Setting range Description 890 H325
Internal storage device status indication 0 (0 to 9999) A faulty area detected by self-check function can be
indicated in the internal storage device.
No. Read value Description
1 1, 3, 5, 7
Storage area other than the area for parameter settings is faulty (such as area for the set frequency). (When All parameter clear is performed, the set frequency, remotely-set frequency, host name for Ethernet communication, position pulse, multi-revolution counter, and offline auto tuning data are cleared.)
2 2, 3, 6, 7 Storage area for standard parameter settings is faulty. 3 4, 5, 6, 7 Storage area for communication parameter settings is faulty. 4 8 to 9999 Area for manufacturer setting
Pr.890 read Pr.890 setting read
BCN-C22005-969_ENG.fm 1
2 BCN-C22005-969
2 Note for terminal P3 (200/400 V class only) Some descriptions about terminal P3 are incorrect in the Instruction Manual. The descriptions are corrected as follows.
Details on the main circuit terminals Use terminal P3 only when a brake resistor is connected. [Incorrect]
[Correct]
Terminal connection diagrams In the terminal connection diagrams, the wiring of the optional brake unit is corrected as follows.
Terminal symbol Terminal name Terminal function description
P3, PR Brake resistor connection for FR-A820- 00770(15K) to 01250(22K), or FR- A840-00470(18.5K) to 01800(55K)
Connect an optional brake resistor across terminals P3 and PR. Connecting a brake resistor increases the regenerative braking capability.
P/+, N/- Brake unit connection
Connect the brake unit (FR-BU2, FR-BU, BU), power regeneration common converter (FR-CV), power regeneration converter (MT-RC), high power factor converter (FR-HC2), multifunction regeneration converter (FR-XC), or DC power supply (under DC feeding mode). When connecting multiple inverters, FR-A820-00770(15K) to 01250(22K) or FR-A840-00470(18.5K) to 01800(55K), in parallel using the FR-CV, FR-HC2, or FR-XC, always use either terminal P/+ or P3 for the connection. (Do not use terminals P/+ and P3 together.) Do not connect the DC power supply between terminals P3 and N/-. Use terminals P/+ and N/- for DC feeding.
P3, N/- Brake unit connection for FR-A820- 00770(15K) to 01250(22K), or FR- A840-00470(18.5K) to 01800(55K)
Terminal symbol Terminal name Terminal function description
P3, PR Brake resistor connection for FR-A820- 00770(15K) to 01250(22K), or FR- A840-00470(18.5K) to 01800(55K)
Connect an optional brake resistor across terminals P3 and PR. Connecting a brake resistor increases the regenerative braking capability.
P/+, N/- Brake unit connection
Connect the brake unit (FR-BU2, FR-BU, BU), power regeneration common converter (FR-CV), power regeneration converter (MT-RC), high power factor converter (FR-HC2), multifunction regeneration converter (FR-XC), or DC power supply (under DC feeding mode).
[Incorrect] [Correct]
Jumper
P1
Earth (Ground)
R
P3 PR N/-P/+
Brake unit (Option)
DC reactor (FR-HEL)
Brake resistor
Inrush current limit circuit
FR-A820-00770(15K) to 01250(22K), FR-A840-00470(18.5K) to 01800(55K)
Jumper
P1
Earth (Ground)
R
P3 PR N/-P/+
Brake unit (Option)
DC reactor (FR-HEL)
Brake resistor
Inrush current limit circuit
FR-A820-00770(15K) to 01250(22K), FR-A840-00470(18.5K) to 01800(55K)
BCN-C22005-969_ENG.fm 2
3 BCN-C22005-969
Connection of stand-alone option units When the brake unit (FR-BU2, FR-BU, BU), power regeneration common converter (FR-CV), power regeneration converter (MT-RC), high power factor converter (FR-HC2), multifunction regeneration converter (FR-XC), or DC power supply (under DC feeding mode) is connected, use terminal P/+ of the inverter. (Do not use terminal P3.) The following diagram shows the connection example with the FR-BU2 (GRZG type discharging resistor).
U V W
P/+ N/-
R/L1 S/L2 T/L3
Motor M
Inverter PR
N/- BUE SD
P/+ A B C
FR-BU2
GRZG type discharging
resistor RR
Three-phase AC power supply
MCCB MC
OFFON
MC T
10 m or less
OCR contact
MC
External thermal relay
OCR
PR PX
Connection example with the FR-BU2 (GRZG type discharging resistor)
BCN-C22005-969_ENG.fm 3
46 IB-0600932-A
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HEADQUARTERS EUROPEAN REPRESENTATIVES EUROPEAN REPRESENTATIVES EURASIAN REPRESENTATIVES
MIDDLE EAST REPRESENTATIVE
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1
1 …………………………………… 3
2 ………………………………………………….. 13
3 ………………………………………………. 24
4 …………………………. 27
5 ………………………………….. 27
6 ………………………………………………. 32
7 ………………………………………………….. 34
,
( : ,
,
,
,
, , 10 , 250 IEC61140 1 EN M , ,,, OFF1 OFF PM
, , P/+N/-
( )
, , , , 10 40 95RH() ( 3 ) ()2065 ( ) 4000m 0.075mm 10 57Hz 1G 57 150Hz 3 , )
2
( UVW) PMPMUVW PM PM PM (UVW) PM PM (U,V,W)
, , STOP/RESET PM PM LX X13 STF STR =0
PTC / 400V , , , , 1 PM PM PM ()PMPM PM, ON Ethernet Ethernet
, ()
PM PM
()
()
,IM PM
PM PM PM,PM
3
1
1.1
*1
*2 Ethernet FR-A8ETH
*3 C2 EMC ON
NOTE (FR-A840M-04540(200K)
1Ethernet
CD-ROM 1
EMC Pr.19
FM( FM ) FM: AM: (DC0 10V)
OFF*3 60Hz 9999( )
CA( CA ) CA: (DC0 20mA) AM: (DC0 10V)
ON 50Hz 8888( 95%)
4
Ethernet
NOTE
No.
1
2 1
3 Ethernet Ethernet 0.33Nm 0.40Nm
4 1 1 0.33Nm 0.40Nm
5
1.2
RS-485
(a) PU FR-DU08FR-PU07 RS-485 10
(b) RS-485 RS-485 MODBUS RTU
(c) USB A USB
(d) USB B FR Configrator2
(e) EMC EMC ON/OFF
(f) 1
(g) 2
(h) 3
(i) / 2 4
(j) 4
(k) 17
(l) 18
(m) RS-485 /
11
(n) R1/L11S1/L21 17
(o)
(p) FR-DU08 10
(q) 17
(r)
10
(s) 11
(t) 32
(q)
(s)
(p)
(a) (b)
(c)
(e)
(l)
(k)
(j)
(g)
(f)
(d)
(h)
(i)
(t)
(m)
(n)
(k)
(l)
(o)
(r)
6
Ethernet
(a) PU FR-DU08FR-PU07 RS-485 10
(b) Ethernet Ethernet
(c) USB A USB
(d) USB B FR Configurator2
(e) EMC EMC ON/OFF
(f) 1
(g) 3
(h) 2 Ethernet 2 2 Ethernet Ethernet
(i) / SW2 2 4
(j) 4
(k) 17
(l) 18
(m) RS-485 /
11
(n) R1/L11S1/L21 17
(o)
(p) FR-DU08 10
(q) 17
(r)
10
(s) 11
(t) 32
(q)
(s)
(p)
(a)
(b)
(c)
(e)
(l)
(k)
(j)
(h)
(f)
(d)
(g)
(i)
(m)
(n)
(k)
(l)
(o)
(r)
(t)
7
1.3
*1
*2 1000m , 500m 3%
*3 12
*1 30cm 32
*3 -10 40
IEC60721-3-3 3C2/3S2:95%RH
-20 +65 *1
( )
4000m *2
10 57Hz 0.075mm 57 150Hz 1G
8
1.4
1.4.1
NOTE
/ AM EMC
PM
PM
ON
(m)USB
(FR Configurator 2)
USB
USB A
LED USB
USB B
R/L1 S/L2 T/L3 N/-P/+
P/+ PR
P/+
P/+
PR
PR
U V W
U
V W
IM PM
(c)(MCCB) (ELB)
(e) (FR-HAL) (n) ()
(o)
(FR-BLF)
(p)
(q)
DSN
(r)IPM
(h) FR-HC2
(j) (MT-RC
(l) (MT-BR5
(k) (MT-BUFR-BU2
(d)MC
(a) (b)
9
1.4.2
/
MCCB ELBNFNV
NOTE MCCB
1 1 MCCB 38 MCCB
MCCB
1
NOTE AC-1 50 25
JEM1038-AC-3 JEM1038-
AC-3
MCCB
1
(a) FR-A840M
EMC
7 13
(b) 34
(c) MCCBELB 9
(d) MC)
9
(e) FR-HAL)
1000kVA FRHAL
31
(f) FR-HC2) 22
(g) MT-RC) 23
(h) MT-BUFR-BU2) 21
(i) MT-BR5
(j) USB USB Ver1.1 USB
(k) 21
(l) FR-BLF 0.5MHz 5MHz 4T
(m)
(n) DSN
PM
(o) IPM
FR-A840M-[]
SLD ND
03630(160K) 400A 350A
04540(200K) 500A 400A
FR-A840M-[]
SLD ND
03630(160K) S-N400 S-N300
04540(200K) S-N600 S-N400
10
1.4.3
(a)
(b) (R/L1, S/L2, T/L3, P/+, N/-, PR)
PU 0.40 0.45Nm
11
(a)
(b) (U, V, W)
(a)
(b)
(c)
(a)
(b)
(c)
NOTE
12
1.4.4
NOTE 2kHz
FR-A840M-[]
W
SLD ND
03630(160K) 4175 3300
04540(200K) 5300 4175
13
2
2.1
FM (RS-485 )
*1 (Pr.178 Pr.189) *2 JOG JOG/ Pr.291 *3 (Pr.73Pr.267) / OFF ON 102 PTC
Pr.561 *4 2W1k *5 P/+ PR 21 *6 (Pr.195Pr.196) *7 (Pr.190 Pr.194) *8 F/C(FM) Pr.291 *9 *10 C2 EMC ON OFF C2 *11 , R1/L11S1/L21 *12 PR
NOTE 10cm
/
14
CA (RS-485 )
*1 (Pr.178 Pr.189) *2 JOG JOG/ Pr.291 *3 (Pr.73Pr.267) / OFF ON 102 PTC
Pr.561 *4 2W1k *5 P/+ PR 21 *6 (Pr.195Pr.196) *7 (Pr.190 Pr.194) *8 C2 EMC ON OFF C2 *9 , R1/L11S1/L21 *10 PR
NOTE 10cm
/
15
FM (Ethernet )
*1 (Pr.178 Pr.189) *2 JOG JOG/ Pr.291 *3 (Pr.73Pr.267) / OFF ON 102 PTC
Pr.561 *4 2W1k *5 P/+ PR 21 *6 (Pr.195Pr.196) *7 (Pr.190 Pr.194) *8 F/C(FM) Pr.291 *9 *10 C2 EMC ON OFF C2 *11 Ethernet 2 2 Ethernet Ethernet *12 , R1/L11S1/L21 *13 PR
NOTE 10cm
/
16
CA (Ethernet )
*1 (Pr.178 Pr.189) *2 JOG JOG/ Pr.291 *3 (Pr.73Pr.267) / OFF ON 102 PTC
Pr.561 *4 2W1k *5 P/+ PR 21 *6 (Pr.195Pr.196) *7 (Pr.190 Pr.194) *8 C2 EMC ON OFF C2 *9 Ethernet 2 2 Ethernet Ethernet *10 , R1/L11S1/L21 *11 PR
NOTE 10cm
/
17
2.2
2.2.1
*1 PR
C2 C2
U V W
R/L1 S/L2 T/L3
N/- P/+ PR
18
2.2.2 (1) 1011
(2)
(3)
(4)
(5) 2
(6) 1011
19
2.2.3 2% 20m
ND
SLD
*1 ( ) (LMFC( ) ) 90 50
*2 ( ) (THHN ) 90 40 38
*3 (XLPE ) , 90 40
*4 R/L1S/L2T/L3UVWPRP/+N/-
P/+
*5 PR
[V] [m/m] [m] [A] 1000
NOTE
1 100m
400V 400V Pr.72PWM
MT-BSL/BSC
PM PM 100m PM 1 1 PM
NOTE
Pr.156
MT-BSL/BSC V/F
Pr.72PWM
400V
FR-A840M-[]
*4*5
Nm
HIV mm2 *1 AWG/MCM *2 PVC mm2 *3
R/L1 S/L2 T/L3
UVW R/L1 S/L2 T/L3
UVW P/+ P1
R/L1 S/L2 T/L3
UVW R/L1 S/L2 T/L3
UVW
03630(160K) M12(M10) 14.7 100-12 100-12 100 100 150 38 4/0 4/0 95 95 50
04540(200K) M12(M10) 14.7 100-12 100-12 100 100 150 38 4/0 4/0 95 95 70
FR-A840M-[]
*4*5
Nm
HIV mm2 *1 AWG/MCM *2 PVC mm2 *3
R/L1 S/L2 T/L3
UVW R/L1 S/L2 T/L3
UVW P/+ P1
R/L1 S/L2 T/L3
UVW R/L1 S/L2 T/L3
UVW
03630(160K) M12(M10) 14.7 100-12 100-12 100 100 150 38 4/0 4/0 95 95 50
04540(200K) M12(M10) 14.7 150-12 100-12 150 150 200 38 300 300 150 150 70
Pr.72
FR-A840M-03630(160K) FR-A840M-04540(200K)
2 2kHz 500m 500m
3 3kHz 500m 500m
100m
4 4kHz
20
2.3
0.3 0.75mm2
30m( FM 200m)
200V
PC
,
(A1,B1,C1,A2,B2,C2)
SD 0V
(2019 4
*1 MTW
*2 A1B1C1A2B2C2
mm2
UL *1
0.3 AI 0,34-10TQ
CRIMPFOX 6
0.5 AI 0,5-10WH AI 0,5-10WH-GB
0.75 AI 0,75-10GY A 0,75-10 AI 0,75-10GY-GB
1 AI 1-10RD A 1-10 AI 1-10RD/1000GB
1.251.5 AI 1,5-10BK A 1,5-10 AI 1,5-10BK/1000GB*2
0.75 2 AI-TWIN 20,75-10GY
mm2
0.3 0.75 BT 0.75-11 VC 0.75 NICHIFU NH 69
21
2.4
2.4.1 P/+PR P/+PR
17
Pr.30 =11121101111121 26
Pr.70
2.4.2 FR-BU2 FR-BU2(H)
Pr.30 1Pr.70 0 FR-BU2 Pr.0
2
*1 (P/+N/-) (FR-BU2)
*2
*3 (FR-BU2) (MT-BR5) 5m 10m
*4 TH1-TH2 TH1-TH2
*5 MT-BU5 CN8
NOTE Pr.30 1Pr.70 0% oL
kW
FR-A840M-03630 160K 3.85 160
FR-A840M-04540 200K 3 200
Pr.30Pr.70
22
2.4.3 FR-HC2 FR-HC2
Pr.19 V/F Pr.83 V/F Pr.30 2 102
*1 R/L1-R1/L11S/L2-S1/L21 R1/L11S1/L21 R/L1S/L2T/L3
E.OPT
*2 P/+ N/- P P/+ N N/- MCCB N/-P/+
*3 X10(X11) Pr.178 Pr.189
RS-485X11
*4 FR-HC2 IPF FR-HC2
*5 FR-HC2 RDY X10 MRS FR-HC2 SE SD
FR-HC2
*6 FR-HC2 R/L1S/L2T/L3 FR-HC2
*7 1 R/L1S/L2T/L3 FR-HC2 R4/L14S4/L24T4/L34 MCCBMC
*8
*9 FR-HC2
*10 FR-HC2-H280K FR-HC2
NOTE R/L1S/L2T/L3 R4/L14S4/L24T4/L34
/
ROH2
ROH1
FR-HCB2
(FR-HC2)2
(FR-HCL22)
M
1 (FR-HCL21)
P/+ *2P/+ N/-N/-
R1/L11 S1/L21
X10
X11
SD
RDY
RSO
SE
R/L1
S/L2 T/L3
U V W
R1/L11 S1/L21
88R88R 88S88S
ROH
SD
MCCB MC R4/ L14
R4/L14
S4/ L24 S4/L24
T4/ L34 T4/L34
R3/ L13
R3/ L13
S3/ L23
S3/ L23
T3/ L33
T3/ L33
R2/ L12
R2/ L12
S2/ L22
S2/ L22
T2/ L32
T2/ L32
R/ L1
S/ L2
T/ L3
R/L1 S/L2 T/L3
RES
IPF
*3
*5 *3
*2
*4
*8
*8
*7*7
*6
*8 *8
*7
*10
*7
*9
*1
*8
23
2.4.4 MT-RC MT-RC Pr.30 1
Pr.70 0
NOTE MT-RC MC MT-RC 1
MT-RC MT-RC MCCB
MT-RC
R/L1
S/L2
T/L3
R1/L11
S1/L21
R R2 RES
U
V
W
MT-RCL
N/-
P N
RDY
SE
MT-RC
MCCB MC2MC1
M
STF
SD S
T
S2
T2
R2
S2
T2
R
S
T
R1
S1
C
B
A
P/+
24
(FR-DU08)
3
3.1 (FR-DU08)
No.
(a) M
Pr.992
(b) MODE
[PU/EXT] (2 ) Pr.1610
(c) SET Pr.52Pr.774 Pr.776
(d) ESC
(e) PU/EXT PU PUJOG [MODE] PU
(FR-DU08)
25
3.1.1 ( )
*1
*2
*3
*4
*5 USB , USB USB , ( )
26
3.2
FR-A800
Pr.30
*1
*2 , ( )
Pr.570
Pr.260 PWM
PWM 3kHz Pr.72 3
*1 , ( )
*1 FR-A800 15ms
NOTE FR-A800 FR-A800
Pr.30 *2 Pr.70 *2
RST 0 100
PN 10110
RST/PN 20120
FR-BU2 MT-BR5
RST 1101
0 PN 11111
RST/PN 21121
*1
RST 1101
0 PN 11111
RST/PN 21121
MT-RC
RST 1101 0
FR-HC2
PN 2102
Pr.
570 2
0 SLD 110% 60s120% 3s 40
2 ND 150% 60s200% 3s 40
Pr.260 *1 Pr.570 *1
1 0(SLD) 50%
2(ND) 50%
0
0(SLD) 50%
2(ND) 2kHz 50%
E.IPF FR-LU08
10ms*1 100ms ON 10ms*1 IPF
Pr.57 ( )
27
4
(ALM)
RUN
CPU RUN
5
FR-A800
(UVW)
2%
19
2
/ AM EMC EMC
ON, 3
EMC ON
EMC OFF
*1 EMC ON/OFF
*1 FINEMET FT-3KM F
FINEMET
10 P/+ N/-
EV 24V OFF
(ALM ) 5
(RY ) (RY ) 5
(STF STR ) (RUN )
5
(STF STR ) (Y12)
5
28
100 )
STFSTR ONOFF 13
P/+PR
10E 5
ON
ON
PLG PLG PLG)
MC
, MC( 2 )
, ,
JEM1038-AC-3
OFF ON ,
MC MC
PM
( )
: ZCAT3035-1330 TDK
2 PM , PM
, MC1 MC2
,
( SF-V5RU,SF-THYPM
29
5.1
5.1.1
FR-
A840M
NOTE
40 50 3kHz kHz 1GHz
30
5.1.2
200V 3.7kW
2004 1 2004 9 6
1kW
100%
P0
6 30
30
30
5 7 11 13 17 19 23 23
6.6kV 3.5 2.5 1.6 1.3 1.0 0.9 0.76 0.70
22kV 1.8 1.3 0.82 0.69 0.53 0.47 0.39 0.36
33kV 1.2 0.86 0.55 0.46 0.35 0.32 0.26 0.24
Ki
3 K33 1.8
K34 1.4
5 K5 0
6.6kV 50kVA
22/33kV 300kVA
66kV 2000kVA
5 7 11 13 17 19 23 25
30 13 8.4 5.0 4.7 3.2 3.0 2.2
28 9.1 7.2 4.1 3.2 2.4 1.6 1.4
P0 (KiPi)[kVA] *1
Ki 30
Pi*1[kVA]
i
31
1kW
kW
A
6.6kV
mA
kVA
6.6kV (mA) 100%
200V 400V 5 7 11 13 17 19 23 25
75 245 123 7455 87.2 2237 969 626 373 350 239 224 164
90 293 147 8909 104 2673 1158 748 445 419 285 267 196
110 357 179 10848 127 3254 1410 911 542 510 347 325 239
132 216 13091 153 3927 1702 1100 655 615 419 393 288
160 258 15636 183 4691 2033 1313 782 735 500 469 344
220 355 21515 252 6455 2797 1807 1076 1011 688 645 473
250 403 24424 286 7327 3175 2052 1221 1148 782 733 537
280 450 27273 319 8182 3545 2291 1364 1282 873 818 600
315 506 30667 359 9200 3987 2576 1533 1441 981 920 675
355 571 34606 405 10382 4499 2907 1730 1627 1107 1038 761
400 643 38970 456 11691 5066 3274 1949 1832 1247 1169 857
450 723 43818 512 13146 5696 3681 2191 2060 1402 1315 964
500 804 48727 570 14618 6335 4093 2436 2290 1559 1462 1072
560 900 54545 638 16364 7091 4582 2727 2564 1746 1636 1200
630 1013 61394 718 18418 7981 5157 3070 2886 1965 1842 1351
No.
1 FR-HAL FR-HAL
2 FR-HC2 FR-HC2
3
4 30 — — 12
5 AC
6
32
6
6.1
NOTE 10 P/+ N/-
25cm
6.1.1 1) 11
2)
3)
33
4) 0.730.1Nm
6.1.2 1) AIR FLOW
2)
NOTE
AIR FLOW
34
7
7.1
*1 4
*2 400V 440V
*3 % , 100%
*4
*5 ED Pr.70 21
*6 ND
*7 ( )
*8 ( )
*9 FR-DU08:IP40 PU
*10 480V Pr.977 FR-A800
*11 1m 1.6m
FR-A840M-[] 160K 200K
03630 04540
(kW) *1 SLD 200 250
ND 160 200
(kVA) *2 SLD 200 250
ND 160 200
(A) SLD 363 454
ND 293 363
*3 SLD 110% 60s120% 3s ( ) 40
ND 150% 60s200% 3s ( ) 40
*4 380 500V
*6 100% *5
380 500V 50Hz/60Hz *10
323 550V 50Hz/60Hz
5%
(A) *7 SLD 363 454
ND 293 363
(kVA) *5 SLD 277 346
ND 223 277
(IEC 60529) *9 IP20 IP55
(dB)*11 73.4 73.4
(kg) 148 148
35
7.2 FR-A840M-03630160KFR-A840M-04540200K
36
1 FR-A840
*1 1000m 500m 3%
FR-A840M FR-A840
-10 +40 -10 +50 LDND HD -10 +40 SLD
*1 4000m 2500m
10 57Hz 0.075mm 57 150Hz 1G
2.9m/s2 10 55Hz XYZ FR-A840-04320(160K)
IP20 IP55 IP00FR-A840-00770(30K)
FR-A840-00023(0.4K) 03160(55K)
EMC C3 C2 C3
DC
dB 73.4 61.2FR-A840-04810(185K)
PWM Pr.260
PWM
50%
85%
Pr.570
SLDND 02
SLDLDND HD 0 3
E.IPF
10ms
15ms
37
2
1996 EMC 1997 EMC
CE
Mitsubishi Electric Europe B.V.
Mitsubishi-Electric-Platz 1, 40882 Ratingen, Germany
EMC CE
EMC EMC CE
EMC 2014/30/EU
EN61800-3:2004+A1:2012 (First environment / PDS Category «C2», Second environment / PDS Category «C3»)
First environment
Second environment
EMC
C3 EMC EMC
EMC Installation Manual BCN-A21041-204
EMC 20m
EMC
C2 EMC 16A EN/IEC61000-3-2 EN/IEC61000-3-2
1kW 16A 75A Ssc
EN/IEC61000-3-12
Ssc 75A 100kVA IEC61000-3-4 Rsce
IEC61000-3-4
Ssc Rsce
FR-A840M-03630(160K) IEC61000-3-4 — 350
FR-A840M-04540(200K)
38
EN 61800-5-1 CE
19
40
EN60204
19 PVC
EN IEC
RCD RCM B RCD RCM
IEC60664 2
2 IP2X
3 IP54
EN60204
A1B1C1A2B2C2 DC30V0.3A
13
7
*1 1000m 500m 3%
400V
100kA rms 500V
Pr.9
NOTE
1 OCR
-10 +40 -20 +65 -20 +65
95%RH 95%RH 95%RH
4000m*1 4000m 10000m
FR-A840M-03630(160K) UL recognized semi-conductor fuse 170M6112 Bussmann 700V800A
FR-A840M-04540(200K) UL recognized semi-conductor fuse 170M6114 Bussmann 700V1000A
*1 Pr.9 50%
*2 % %%
*3 150%
39
3 ULcUL
UL 61800-5-1, CSA C22.2 No.274-13
— —
10 10 P/+ N/-
7
A1B1C1A2B2C2 DC30V0.3A
National Electrical Code(Article 310) National Electrical Code(Article 430) 125%
R/L1S/L2T/L3 UVW UL 75
100kA rms 500V
Pr.9
NOTE
1 OCR
SF-V5RU Pr.90
FR-A840M-03630 160K UL recognized semi-conductor fuse 170M6112 Bussmann 700V800A
FR-A840M-04540 200K UL recognized semi-conductor fuse 170M6114 Bussmann 700V1000A
*1 Pr.9 50%
*2 % %%
*3 6Hz
*4 150%
40
4 EAC
EAC EAC
EAC
2010
CU-TR Custom-Union Technical Regulation EAC
CU
3
MADE IN JAPAN
3 SERIAL
CU
CU
Mitsubishi Electric (Russia) LLC
52, bld 1 Kosmodamianskaya Nab 115054, Moscow, Russia
+7 (495) 721-2070
FAX +7 (495) 721-2071
SERIAL
SERIAL 1 2 6
1 1 9 1 9 X 10 Y 11 Z 12
41
5
SJ/T11364 GB/T26572 GB/T26572
*1
*2
6
GB/T 16855.1
GB/T 12668.502
GB 28526
GB/T 12668.3
GB/T 12668.501
EMC GB/T 12668.3
*2
*1
(Pb)
(Hg)
(Cd)
(Cr(VI))
(PBB)
(PBDE)
42
1
[]
618
[]
(1)
(2)
(3)
2
(1) 7
(2)
3
FAFA
4
(1)
(2)
(3)
(4)
5
6
(1) :
(2)
43
CD-ROM CD-ROM PDF
CD-ROM CD-ROM ,
, CD-ROM
CD-ROM ,
CD-ROM ,
MicrosoftWindowsWindows VistaInternet Explorer Microsoft Corporation
Adobe Adobe Reader Adobe Systems Incorporated
Intel Pentium Intel Corporation
CD-ROM ,
NOTE CD-ROM
CD-ROM CD-ROM ,
CD-ROM
1. , CD-ROM CD-ROM
2.
3.
4.
5. PDF
CD-ROM
1. , CD-ROM CD-ROM
2. CD-ROM index.html
3. 3
PDF CD-ROM MANUAL
OS Microsoft Windows 10Windows 8.1Windows 8Windows 7 Windows Vista
CPU Intel Pentium
128MB RAM
90MB
CD-ROM 2 4
800×600
Adobe Reader 7.0
Internet Explorer 6.0
45
*
*
2020 8 IB(NA)-0600932-A
1 BCN-C22005-957
FR-A800/A800 Plus
1
IP55
*1 IP55
*2 Pr.523 Pr.524
*3 Pr.523 100200300400 Pr.524
Pr.
FM CA
523
H320*1 9999
100111112121 122123124
200211212221
222223224 300311312321
322323324 400411412421
422423424
9999
524
H321*1*2 9999
0 590Hz*3 Pr.523
0 100%*3 PID PID
Pr.523 PID
9999*3
515
H322*1 1
1 200
9999*3
1013
H323*1
60Hz 50Hz 0 590Hz E.CPUE.1 E.3 E.5 E.7
514
H324*1 9999
0.1 600s
9999 Pr.68
136
A001 MC 1s 0 100s MC2 MC3
139 A004
—
9999 0 60Hz
88889999
57 A702
9999
0
0.1 30s
9999
V/F PM
BCN-C22005-957_CHN.fm 1
2 BCN-C22005-957
*1
Pr.190 Pr.196 ( )
*2 DC
AC FR-A8AR
*3 Pr.180 Pr.189 ( )
*4 Pr.190 Pr.196
NOTE MC2MC3
(RUNSUIPFOLFU) DC24V 0.1A
(A1-C1B1-C1A2-B2B2-C2)
(FR-A8AR)
AC230V 0.3A DC30V 0.3A
IM R/L1 S/L2 T/L3
X84
CS
RES
SD
U V W
Y65
MC2
SE
MC3
MC2 DC24V
MC3
/
MCCB
MC2
MC3
MC2
MC3
ALM3
BCN-C22005-957_CHN.fm 2
3 BCN-C22005-957
X84 3s ON
Y65 ON
ED
ALM3 ON
X84 ON 3s
Pr.523 2[][]3[][]
X84 OFF
OFF
X51 ON
24V R1S1 12
X84 Pr.178 Pr.18984
Y65 Pr.190 Pr.196 65 165
ALM3 Pr.190 Pr.196
66 166
Pr.338Pr.339 X84
Pr.502 0 E.SER
Pr.523 9999 Pr.524 9999 Pr.523 100200300400
Pr.800 91020109110Pr.451 1020110
9999
V/F
PM
PM
FR-A8NS
R1S1
Pr.30=2102
BCN-C22005-957_CHN.fm 3
4 BCN-C22005-957
Pr.523 211
CS
Pr.523 411
*1 CS
NOTE FR-A800-CRNBB3
E.PUE
RES
X84
STF
ALM3
Pr.514
Y65
ALM
Pr.524
3s
ON
ON
ON
ON
ON
ON
3s
STF
X84
CS*1
MC3
MC2
MC3
MC2
Pr.136
Y65
MC
MC
ON
ON
ON
ON
ON
ON
ON
ON
ON
ON
BCN-C22005-957_CHN.fm 4
5 BCN-C22005-957
Pr.523Pr.524 Pr.523
*1 PM
NOTE PID PU /PU
Pr.515Pr.514 Pr.515 Pr514
ALM Pr.67
7
NOTE Pr.65
Pr.523
1[][]
2[][]
3[][]*1
Pr.515 9999 200
4[][]*1
[]00
[]11
Pr.524 []12
[]21
PID
Pr.524 PID Pr.128 []22
[]23 2PID
Pr.524 PID Pr.753
[]24
2PID
9999
BCN-C22005-957_CHN.fm 5
6 BCN-C22005-957
Pr.136Pr.139Pr.57 Pr.523 3[][]4[][]
Pr.136 MC Pr.139 — MC2MC3
CS Pr.57 9999 CS
ON CS CS
V/F PM
CS OFF
Pr.523=3[][]
Pr.523=4[][]
Pr.139
Pr.523 3[][]4[][]
Pr.190 Pr.19618 19
MC2MC3
MC2MC3
*1 CS Pr.162=0 310 13 Pr.338 1
*2 ON
*3 OFF
*4 MC
NOTE Pr.135=1
MC2
MC3
MC *4
MC2 MC3
CS*1 ON
OFF *2
X84 ON
OFF *3
RES ON
OFF
MC
ON
OFF
MC2-OFFMC3-ON
MC2-ONMC3-OFF
ONOFF
BCN-C22005-957_CHN.fm 6
7 BCN-C22005-957
PID PID Pr.524 PID Pr.128 Pr.753
PID PID PID
PID Pr.523 22[]32[] E.CPUE.1 E.3
E.5 E.7 PID
Pr.1013
*1 2
*2 Pr.523 200300 OFF
PID
/ PID
Pr.128Pr.753 4 4
/ Pr.128Pr.753
Pr.129Pr.756 100%
Pr.130Pr.757 1s
Pr.134Pr.758
/ Pr.128Pr.753
PID
E.OC1 E.OP3 E.ECA
E.OC2 E.16 E.MB1
E.OC3 E.17 E.MB2
E.OV1 E.18 E.MB3
E.OV2 E.19 E.MB4
E.OV3 E.20 E.MB5
E.THT E.PE E.MB6
E.THM E.PUE E.MB7
E.FIN E.RET E.EP
E.IPF E.PE2 E.MP
E.UVT E.CPU E.EF
E.ILF E.CTE E.IAH
E.OLT E.P24 E.LCI
E.SOT E.CDO E.PCH
E.LUP E.IOH E.PID
E.LDN E.SER E.1 *2
E.BE *1 E.AIE E.2 *2
E.GF E.USB E.3 *2
E.LF E.SAF *1 E.5 *2
E.OHT E.PBT *1 E.6 *1*2
E.PTC E.OS E.7 *1*2
E.OPT E.OSD E.11
E.OP1 E.ECT E.13
E.OP2 E.OD
BCN-C22005-957_CHN.fm 7
8 BCN-C22005-957
PID
PID
*1 FR-A800-LC
Pr.52Pr.774 Pr.776Pr.992 68
*1 1
*2 7
Pr.190 Pr.196
ALM 99 199 ON
ALM3 66 166
ON 3s
OFF
PID
OHX31*1X32X41*1TRGTRC X51RESX70X71
OHX31*1X32X41*1TRGTRC X51RESX70X71
RTX9X17X18MCSQX84 RTX9X17X18MCSQX64
X65X66X67X79X84
ON X14X77X78X80
0
1
2
3 *2
4
5
11
12
13 *2
14
15
2[]*1
3[]*1
4[]*1
BCN-C22005-957_CHN.fm 8
9 BCN-C22005-957
2 Y30Y31
Y30 Y31 PLG
PLG Y30Y31
NOTE Y30 Y31
BCN-C22005-957_CHN.fm 9
1 BCN-C22005-969
FR-A800/A800Plus
1 (E.PE6)
E.PE6
Pr.890 7
*1 FR Configurator2
NOTE E.PE6
E.PE6 3 Y91
E.PE6 SAFE OFF
E.PE6 X51
E.PE6
E.PE6 172 HAC
E.PE6 Pr.890
Pr.890
Pr.890 No. No.
7 No.1 3
E.PE6 FR-LU08
*1
E.PE6
Pr.890 7
E.PE6 OFF/ON
Pr.
890 H325
0 (0 9999)
No.
1 1357
Ethernet
2 2367
3 4567
4 8 9999
Pr.890 Pr.890
BCN-C22005-969_CHN.fm 1
2 BCN-C22005-969
2 P3 200V/400V
P3
P3
P3PR
FR-A820-00770(15K) 01250(22K) FR-A840-00470(18.5K) 01800(55K)
P3 PR
P/+N/-
FR-BU2FR-BUBU
FR-CV MT-RC FR-HC2 FR-XC
FR-A820-00770(15K) 01250(22K)FR-A840-00470(18.5K)
01800(55K) FR-CVFR-HC2FR-XC P/+ P3 P/+ P3
P3N/- P/+N/-
P3N/-
FR-A820-00770(15K) 01250(22K) FR-A840-00470(18.5K) 01800(55K)
P3PR FR-A820-00770(15K) 01250(22K)
FR-A840-00470(18.5K) 01800(55K)
P3 PR
P/+N/- FR-BU2FR-BUBU FR-CVMT-RCFR-HC2
FR-XC
P1
R
P3 PR N/-P/+
FR-HEL
FR-A820-00770(15K)01250(22K) FR-A840-00470(18.5K)01800(55K)
P1
R
P3 PR N/-P/+
FR-HEL
FR-A820-00770(15K)01250(22K) FR-A840-00470(18.5K)01800(55K)
BCN-C22005-969_CHN.fm 2
3 BCN-C22005-969
FR-BU2FR-BUBUFR-CVMT-RC
FR-HC2FR-XC P/+
P3
FR-BU2 GRZG
FR-BU2GRZG
U
V W
P/+
N/-
R/L1
S/L2
T/L3
M
PR
N/- BUE SD
P/+
A
B
C
FR-BU2
GRZG
RR
MCCB MC
OFFON
MC T
10m
OCR
MC
OCR
PR
PX
BCN-C22005-969_CHN.fm 3
46
http://cn.MitsubishiElectric.com/fa/zh/
IB(NA)-0600932-A
800 INSTRUCTION MANUAL (STARTUP) (ENGLISH)
( )( )
HEAD OFFICE: TOKYO BUILDING 2-7-3, MARUNOUCHI, CHIYODA-KU, TOKYO 100-8310, JAPAN
IN VER
TER A
800 FR
-A 840M
IN STR
U C
TIO N
M A
N U
A L (STA
R TU
P)
A
A800 FR-A840M-03630(160K)04540(200K)
CD-ROM CD-ROM
Thank you for choosing this Mitsubishi Electric Inverter. This Instruction Manual (Startup) and the enclosed CD-ROM give handling information and precautions for use of this product. Do not use this product until you have a full knowledge of the equipment, safety information and instructions. Please forward this Instruction Manual (Startup) and the enclosed CD-ROM to the end user.
()CD-ROM
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Инверторы серии FR-F800
Руководство пользователя
Инвертор серии FR-F800
Карманный справочник
Схема кроссовера 208-230 В (Предполагается рейтинг SLD)
HP | FR-F720 | FR-F820 |
1 | FR-F720-00046-NA | FR-F820-00046-E3N6 |
2 | FR-F720-00077-NA | FR-F820-00077-E3N6 |
3 | FR-F720-00105-NA | FR-F820-00105-E3N6 |
5 | FR-F720-00167-NA | FR-F820-00167-E3N6 |
7.5 | FR-F720-00250-NA | FR-F820-00250-E3N6 |
10 | FR-F720-00340-NA | FR-F820-00340-E3N6 |
15 | FR-F720-00490-NA | FR-F820-00490-E3N6 |
20 | FR-F720-00630-NA | FR-F820-00630-E3N6 |
25 | FR-F720-00770-NA | FR-F820-00770-E3N6 |
30 | FR-F720-00930-NA | FR-F820-00930-E3N6 |
40 | FR-F720-01250-NA | FR-F820-01250-E3N6 |
50 | FR-F720-01540-NA | FR-F820-01540-E3N6 |
60 | FR-F720-01870-NA | FR-F820-01870-E3N6 |
75 | FR-F720-02330-NA | FR-F820-02330-E3N6 |
100 | FR-F720-03160-NA | FR-F820-03160-E360 +FR-HEL-90K |
125 | FR-F720-03800-NA | FR-F820-03800-E3U6 +FR-HEL-110K |
150 | FR-F720-04750-NA | FR-F820-04750-E3U6 +FR-HEL-110K |
На этой диаграмме показан ближайший эквивалент по производительности между дисками FR-F700 и FR-F800.
Таблица выбора FR-F820
Номер модели | AMPS Для Долг | Лошадиная сила для работы (NEC) | Размер рамки | Вес (кг) | ||
SLD | LD | SLD | LD | |||
ФР-Ф820-00046–E3N6 | 4.6 | 4.2 | 1 | 1 | A | 6 |
FR-F820-00077-E3N6 | 7.7 | 7 | 2 | 2 | B | 6 |
FR-F820-00105-E3N6 | 10.5 | 9.6 | 3 | 3 |
C |
9 |
FR-F820-00167-E3N6 | 16.7 | 15.2 | 5 | 5 | 9 | |
FR-F820-00250-E3N6 | 25 | 23 | 7.5 | 7.5 | 9 | |
FR-F820-00340-E3N6 | 34 | 31 | 10 | 10 | D | 17 |
FR-F820-00490-E3N6 | 49 | 45 | 20 | 15 | 17 | |
FR-F820-00630-E3N6 | 63 | 58 | 20 | 20 | E | 20 |
FR-F820-00770-E3N6 | 77 | 70.5 | 25 | 25 |
F |
37 |
FR-F820-00930-E3N6 | 93 | 85 | 30 | 30 | 37 | |
FR-F820-01250-E3N6 | 125 | 114 | 40 | 40 | 37 | |
ФР-Ф820-01540-Э360 | 154 | 140 | 60 | 50 | G | 48 |
ФР-Ф820-01870-Э360 | 187 | 170 | 60 | 60 | H | 92 |
ФР-Ф820-02330-Э360 | 233 | 212 | 75 | 75 | 92 | |
ФР-Ф820-03160-Э360 | 316 | 288 | 125 | 100 | K | 119 |
FR-F820-03800-E3U6 | 380 | 346 | 150 | 125 | L | 163 |
FR-F820-04750-E3U6 | 475 | 432 | 150 | 150 | 163 |
Важная заметка: Приводы в затененной зоне ДОЛЖНЫ использоваться вместе с дросселем звена постоянного тока FR-HEL (продается отдельно). Масса не включает отдельные дроссели звена постоянного тока.
Дроссели звена постоянного тока FR-HEL (продано отдельно)
Приводы в заштрихованной области ДОЛЖНЫ использоваться вместе с дросселем звена постоянного тока.
Номер модели | LD |
SLD |
ФР-Ф820-03160-Э360 | ФР-ХЕЛ-75К | ФР-ХЕЛ-90К |
FR-F820-03800-E3U6 | ФР-ХЕЛ-90К | ФР-ХЕЛ-110К |
FR-F820-04750-E3U6 | ФР-ХЕЛ-110К | ФР-ХЕЛ-110К |
Ключ к кодам обязанностей
Рейтинг перегрузки | |||
60s | 3s | Окружающая температура. | |
SLD | 110% | 120% | 40 ° C |
LD | 120% | 150% | 50 ° C |
Схема кроссовера 460-480 В (Предполагается рейтинг SLD)
HP | FR-F740 |
FR-F840 |
1 | FR-F740-00023-NA | FR-F840-00023-E3N6 |
2 | FR-F740-00038-NA | FR-F840-00038-E3N6 |
3 | FR-F740-00052-NA | FR-F840-00052-E3N6 |
5 | FR-F740-00083-NA | FR-F840-00083-E3N6 |
7.5 | FR-F740-00126-NA | FR-F840-00126-E3N6 |
10 | FR-F740-00170-NA | FR-F840-00170-E3N6 |
15 | FR-F740-00250-NA | FR-F840-00250-E3N6 |
20 | FR-F740-00310-NA | FR-F840-00310-E3N6 |
25 | FR-F740-00380-NA | FR-F840-00380-E3N6 |
30 | FR-F740-00470-NA | FR-F840-00470-E3N6 |
40 | FR-F740-00620-NA | FR-F840-00620-E3N6 |
50 | FR-F740-00770-NA | FR-F840-00770-E3N6 |
60 | FR-F740-00830-NA | ФР-Ф840-00930-Э360 |
75 | FR-F740-01160-NA | ФР-Ф840-01160-Э360 |
100 | FR-F740-01800-NA | FR-F840-01800-E360 +FR-HEL-H90K |
150 | FR-F740-02160-NA | FR-F840-02160-E3U6 +FR-HEL-H110K |
200 | FR-F740-02600-NA | FR-F840-02600-E3U6 +FR-HEL-H132K |
250 | FR-F740-03250-NA | FR-F840-03250-E3U6 +FR-HEL-H160K |
300 | FR-F740-03610-NA | FR-F840-03610-E3U6 +FR-HEL-H185K |
350 | FR-F740-04320-NA | FR-F840-04320-E3U6 +FR-HEL-H220K |
400 | FR-F740-04810-NA | FR-F840-04810-E3U6 +FR-HEL-H250K |
450 | FR-F740-05470-NA | FR-F840-05470-E3U6 +FR-HEL-H280K |
500 | FR-F740-06100-NA | FR-F840-06100-E3U6 +FR-HEL-H315K |
550 | FR-F740-06830-NA | FR-F840-06830-E3U6 +FR-HEL-H355K |
650 | FR-F740-07700-NA | FR-F842-07700-E3U6 +FR-CC2-H400K-60 |
700 | FR-F740-08660-NA | FR-F842-08660-E3U6 + FR-CC2-H450K-60 |
800 | FR-F740-09620-NA | FR-F842-09620-E3U6 +FR-CC2-H500K-60 |
900 | FR-F740-10940-NA | FR-F842-10940-E3U6 +FR-CC2-H560K-60 |
1000 | FR-F740-12120-NA | FR-F842-12120-E3U6 +FR-CC2-H630K-60 |
На этой диаграмме показан ближайший эквивалент по производительности между дисками FR-F700 и FR-F800.
Таблица выбора FR-F840
Номер модели | AMPS Для Долг | Лошадиная сила для работы (NEC) | Размер рамки | Вес в фунтах)* | ||
SLD | LD | SLD | LD | |||
FR-F840-00023-E3N6 | 2.3 | 2.1 | 1 | 1 | C | 8 |
FR-F840-00038-E3N6 | 3.8 | 3 | 2 | 2 | 8 | |
FR-F840-00052-E3N6 | 5.2 | 4.8 | 3 | 3 | 8 | |
FR-F840-00083-E3N6 | 8.3 | 7.6 | 5 | 5 | 9 | |
FR-F840-00126-E3N6 | 12.6 | 11.5 | 7.5 | 7.5 | 9 | |
FR-F840-00170-E3N6 | 17 | 16 | 10 | 10 | D | 17 |
FR-F840-00250-E3N6 | 25 | 23 | 15 | 15 | 17 | |
FR-F840-00310-E3N6 | 31 | 29 | 20 | 20 | E | 20 |
FR-F840-00380-E3N6 | 38 | 35 | 25 | 25 | 20 | |
FR-F840-00470-E3N6 | 47 | 43 | 30 | 30 | F | 37 |
FR-F840-00620-E3N6 | 62 | 57 | 40 | 40 | 37 | |
ФР-Ф840-00770-Э360 | 77 | 70 | 60 | 50 | G | 51 |
ФР-Ф840-00930-Э360 | 93 | 85 | 60 | 60 | H | 90 |
ФР-Ф840-01160-Э360 | 116 | 106 | 75 | 75 | 90 | |
ФР-Ф840-01800-Э360 | 180 | 144 | 150 | 100 | 95 | |
FR-F840-02160-E3U6 | 216 | 180 | 150 | 150 | J | 114 |
FR-F840-02600-E3U6 | 260 | 216 | 200 | 150 | 121 | |
FR-F840-03250-E3U6 | 325 | 260 | 250 | 200 | L | 156 |
FR-F840-03610-E3U6 | 361 | 325 | 300 | 250 | 172 | |
FR-F840-04320-E3U6 | 432 | 361 | 350 | 300 | M | 257 |
FR-F840-04810-E3U6 | 481 | 432 | 400 | 350 | 257 | |
FR-F840-05470-E3U6 | 547 | 481 | 450 | 400 |
N |
365 |
FR-F840-06100-E3U6 | 610 | 547 | 500 | 450 | 365 | |
FR-F840-06830-E3U6 | 683 | 610 | 550 | 500 | 365 | |
FR-F842-07700-E3U6 + FR-CC2-H355K-60 | – | 683 | – | 550 | П+Р | 827 |
FR-F842-07700-E3U6 + FR-CC2-H400K-60 | 770 | – | 650 | – |
П+С |
979 |
FR-F842-08660-E3U6 + FR-CC2-H400K-60 | – | 770 | – | 650 | 979 | |
FR-F842-08660-E3U6 + FR-CC2-H450K-60 | 866 | – | 700 | – | 986 | |
FR-F842-09620-E3U6 + FR-CC2-H450K-60 | – | 866 | – | 700 | Q+S | 1162 |
FR-F842-09620-E3U6 + FR-CC2-H500K-60 | 962 | – | 800 | – | 1168 | |
FR-F842-10940-E3U6 + FR-CC2-H500K-60 | – | 962 | – | 800 | 1168 | |
FR-F842-10940-E3U6 + FR-CC2-H560K-60 | 1094 | – | 900 | – | 1168 | |
FR-F842-12120-E3U6 + FR-CC2-H560K-60 | – | 1094 | – | 900 | 1168 | |
FR-F842-12120-E3U6 + FR-CC2-H630K-60 | 1212 | – | 1000 | – | 1168 |
Вес привода и модулей CC2 ОБЪЕДИНЕН.
Важное примечание. Приводы в заштрихованной области ДОЛЖНЫ использоваться вместе с дросселем звена постоянного тока FR-HEL-H (продается отдельно). Масса не включает отдельные дроссели звена постоянного тока.
FR-HEL-H Дроссели звена постоянного тока (продано отдельно)
Приводы, показанные в заштрихованной области таблицы выбора FR-F840, ДОЛЖНЫ использоваться вместе с дросселем звена постоянного тока.
Номер модели |
LD |
SLD |
ФР-Ф840-01800-Э360 | FR-HEL-H75K | FR-HEL-H90K |
FR-F840-02160-E3U6 | FR-HEL-H90K | FR-HEL-H110K |
FR-F840-02600-E3U6 | FR-HEL-H110K | FR-HEL-H132K |
FR-F840-03250-E3U6 | FR-HEL-H132K | FR-HEL-H160K |
FR-F840-03610-E3U6 | FR-HEL-H160K | FR-HEL-H185K |
FR-F840-04320-E3U6 | FR-HEL-H185K | FR-HEL-H220K |
FR-F840-04810-E3U6 | FR-HEL-H220K | FR-HEL-H250K |
FR-F840-05470-E3U6 | FR-HEL-H250K | FR-HEL-H280K |
FR-F840-06100-E3U6 | FR-HEL-H280K | FR-HEL-H315K |
FR-F840-06830-E3U6 | FR-HEL-H315K | FR-HEL-H355K |
Рейтинги FR-F860
Номер модели (*3) | AMPS для долга | Лошадиная сила для работы (NEC) | Размер рамки | Вес (кг) | ||
SLD | LD | SLD | LD | |||
FR-F860-00027-E3N6 | 2.7 | 2.5 | 2 | 1.5 | C | 11.7 |
FR-F860-00061-E3N6 | 6.1 | 5.6 | 5 | 3 | C | 12.8 |
FR-F860-00090-E3N6 | 9 | 8.2 | 7.5 | 5 | C | 12.8 |
FR-F860-00170-E3N6 | 17 | 16 | 15 | 10 | D | 15.4 |
FR-F860-00320-E3N6 | 32 | 27 | 30 | 25 | E | 19.8 |
FR-F860-00450-E3N6 | 45 | 41 | 40 | 40 | F | 37.4 |
ФР-Ф860-00680-Э360 | 68 | 62 | 60 | 60 | H | 79.2 |
FR-F860-01080-E360 (*1) | 108 | 99 | 100 | 100 | H | 90.2 |
FR-F860-01440-E360 (*1) | 144 | 131 | 150 | 125 | J | 114 |
FR-F860-01670-E360 (*1) | 167 | 152 | 150 | 150 | J | 114 |
FR-F860-02430-E360 (*1) | 243 | 221 | 250 | 200 | J | 121 |
FR-F860-02890-E360 (*1) | 289 | 255 | 300 | 250 | M | 246 |
FR-F860-03360-E360 (*1) | 336 | 304 | 350 | 300 | M | 253 |
FR-F860-04420-E360 (*1) | 442 | 402 | 450 | 400 | N | 337 |
FR-F862-05450-E360+ FR-CC2-C355K-60 (*2) | 545 | 496 | 550 | 500 | П+Р | 810 |
FR-F862-06470-E360+ FR-CC2-C400K-60 (*2) | 647 | 589 | 650 | 600 | Q+S | 920 |
FR-F862-08500-E360+ FR-CC2-C560K-60 (*2) | 850 | 773 | 850 | 750 | Q+S | 1126 |
Ноты:
- Эти приводы НЕОБХОДИМО использовать с дросселем звена постоянного тока (продается отдельно).
- FR-F862 Приводы инверторныеtagтолько е; использовать вместе с выпрямителем FR-CC2-C. Максимальный входной и выходной ток модулей FR-CC2 соответствует показанному значению. Показан КОМБИНИРОВАННЫЙ вес.
- FR-F860 не имеет встроенного параметра. FR-DU08 или FR-LU08 продаются отдельно.
600V FR-HEL-C Дроссели промежуточного контура постоянного тока (продано отдельно)
Номер модели | SLD |
LD |
ФР-Ф860-01080-Э360 | FR-HEL-C75K | FR-HEL-C75K |
ФР-Ф860-01440-Э360 | FR-HEL-C90K | FR-HEL-C90K |
ФР-Ф860-01670-Э360 | FR-HEL-C110K | FR-HEL-C110K |
ФР-Ф860-02430-Э360 | FR-HEL-C185K | FR-HEL-C132K |
ФР-Ф860-02890-Э360 | FR-HEL-C220K | FR-HEL-C185K |
ФР-Ф860-03360-Э360 | FR-HEL-C280K | FR-HEL-C220K |
ФР-Ф860-04420-Э360 | FR-HEL-C280K | FR-HEL-C280K |
Размеры корпуса 200 В, 400 В, 600 В Приводы
FR-F800-Е Номер модели | Размер рамки | Высота | Ширина | глубина |
Размеры, дюймы (мм) | ||||
ФР-Ф820-00046 (N6) | A | 12.2 (310) 10.24 (260) без распределительной коробки |
4.33 (110) | 4.41 (112) |
ФР-Ф820-00077 (N6) | B | 12.2 (310) 10.24 (260) без распределительной коробки |
4.33 (110) | 5.00 (127) |
ФР-Ф820-00105, 00167, 00250 (Н6) ФР-Ф840-00023, 00038, 00052, 00083, 00126 (N6) ФР-Ф860-00027, 00061, 00090 (Н6) |
C | 12.52 (318) 10.24 (260) без распределительной коробки |
5.91 (150) | 5.51 (140) |
ФР-Ф820-00340, 00490 (Н6) ФР-Ф840-00170, 00250 (N6) ФР-Ф860-00170 (Н6) |
D | 12.76 (324) 10.24 (260) без распределительной коробки |
8.66 (220) |
6.69 (170) |
ФР-Ф820-00630 (N6) ФР-Ф840-00310, 00380 (N6) ФР-Ф860-00320 (Н6) |
E | «14.29 (363) 11.81 (300) без распределительной коробки |
8.66 (220) | 7.48 (190) |
ФР-Ф820-00770, 00930, 01250 (Н6) ФР-Ф840-00470, 00620 (N6) ФР-Ф860-00450 (Н6) |
F | 20.37 (517) 15.75 (400) без распределительной коробки |
9.84 (250) | 7.48 (190) |
FR-F820-01540 FR-F840-00770 | G | 21.65 (550) | 12.80 (325) | 7.68 (195) |
ФР-Ф820-01870, 02330 ФР-Ф840-00930, 01160, 01800 ФР-Ф860-00680, 01080 |
H | 21.65 (550) | 17.13 (435) | 9.84 (250) |
ФР-Ф840-02160, 02600 ФР-Ф860-01440, 01670, 02430 |
J | 24.41 (620) | 18.31 (465) | 11.81 (300) |
ФР-Ф820-03160 | K | 27.56 (700) | 18.31 (465) | 9.84 (250) |
ФР-Ф820-03800, 04750 ФР-Ф840-03250, 03610 |
L | 29.13 (740) | 18.31 (465) | 14.17 (360) |
ФР-Ф840-04320, 04810 ФР-Ф860-02890, 03360 |
M | 39.76 (1010) | 19.61 (498) | 14.96 (380) |
ФР-Ф840-05470, 06100, 06830 ФР-Ф860-04420 | N | 39.76 (1010) | 26.77 (680) | 14.96 (380) |
ФР-Ф842-07700, 08660 ФР-Ф862-05450 | P | 52.36 (1330) | 21.26 (540) | 17.32 (440) |
ФР-Ф842-09620, 10940, 12120 ФР-Ф862-06470, 08500 |
Q | 62.20 (1580) | 26.77 (680) | 17.32 (440) |
Номер модели FR-CC2 | Размер рамки | Высота | Ширина | глубина |
Размеры, дюймы (мм) | ||||
ФР-СС2-Х315К, Х355К, К355К | R | 52.36 (1330) | 23.62 (600) | 17.32 (440) |
FR-CC2-H400K, H450H, H500K H560K, H630K, C400K, C560K | S | 62.20 (1580) | 23.62 (600) | 17.32 (440) |
Примечание: Код (N6) относится к распределительной коробке UL типа 1.
Размеры НЕОБХОДИМЫХ дросселей звена постоянного тока (продано отдельно)
Номер модели | Высота | Ширина | глубина | Вес (кг) |
Размеры в дюймах (мм) | ||||
ФР-ХЕЛ-75К | 13.4 (340) | 5.9 (150) | 7.9 (200) | 37 |
ФР-ХЕЛ-90К | 13.4 (340) | 5.9 (150) | 7.9 (200) | 42 |
ФР-ХЕЛ-110К | 15.8 (400) | 6.9 (175) | 7.9 (200) | 44 |
FR-HEL-H75K | 12.6 (320) | 5.9 (140) | 7.3 (185) | 35 |
FR-HEL-H90K | 13.4 (340) | 5.9 (150) | 7.5 (190) | 44 |
FR-HEL-H110K | 13.4 (340) | 5.9 (150) | 7.7 (195) | 48 |
FR-HEL-H132K | 15.9 (405) | 6.9 (175) | 7.9 (200) | 57 |
FR-HEL-H160K | 15.9 (405) | 6.9 (175) | 8.1 (205) | 62 |
FR-HEL-H185K | 15.9 (405) | 6.9 (175) | 9.4 (240) | 64 |
FR-HEL-H220K | 15.9 (405) | 6.9 (175) | 9.4 (240) | 66 |
FR-HEL-H250K | 17.3 (440) | 7.5 (190) | 9.8 (250) | 77 |
FR-HEL-H280K | 17.3 (440) | 7.5 (190) | 10.0 (255) | 84 |
FR-HEL-H315K | 19.49 (495) | 8.27 (210) | 9.84 (250) | 92 |
FR-HEL-H355K | 19.49 (495) | 8.27 (210) | 9.84 (250) | 101 |
FR-HEL-C75K | 12.6 (320) | 5.5 (140) | 7.3 (185) | 35 |
FR-HEL-C90K | 13.3 (340) | 5.9 (150) | 9.4 (240) | 44 |
FR-HEL-C110K | 13.3 (340) | 5.9 (150) | 9.4 (240) | 51 |
FR-HEL-C132K | 15.9 (405) | 6.9 (175) | 7.7 (195) | 53 |
FR-HEL-C185K | 15.9 (405) | 6.9 (175) | 9.4 (240) | 70 |
FR-HEL-C220K | 15.9 (405) | 6.9 (175) | 9.4 (240) | 73 |
FR-HEL-C280K | 17.3 (440) | 7.5 (190) | 9.8 (250) | 88 |
Выбор периферийного оборудования (Предполагается рейтинг LD)
Номер модели | замыкатель | Автоматический выключатель | ||
Нет DCL | С ДКЛ | Нет DCL | С ДКЛ | |
200 вольт | ||||
FR-F820-00046-E3N6 | S-T10 | S-T10 | НФ50-СВФУ3П10А | НФ50-СВФУ3П10А |
FR-F820-00077-E3N6 | S-T10 | S-T10 | НФ50-СВФУ3П15А | НФ50-СВФУ3П15А |
FR-F820-00105-E3N6 | S-T10 | S-T10 | НФ50-СВФУ3П20А | НФ50-СВФУ3П15А |
FR-F820-00167-E3N6 | S-T10 | S-T10 | НФ50-СВФУ3П30А | НФ50-СВФУ3П30А |
FR-F820-00250-E3N6 | С-Т20, С-Т21 | S-T10 | НФ50-СВФУ3П50А | НФ50-СВФУ3П40А |
FR-F820-00340-E3N6 | S-T25 | С-Т20, С-Т21 | НФ125-СВУ3П60А | НФ50-СВФУ3П50А |
FR-F820-00490-E3N6 | S-T25 | S-T25 | НФ125-СВУ3П75А | НФ125-СВУ3П75А |
FR-F820-00630-E3N6 | S-N35 | S-N35 | НФ125-СВУ3П125А | НФ125-СВУ3П100А |
FR-F820-00770-E3N6 | S-N50 | S-N50 | НФ250-СВУ3П150А | НФ125-СВУ3П125А |
FR-F820-00930-E3N6 | S-N65 | S-N50 | НФ250-СВУ3П175А | НФ250-СВУ3П150А |
FR-F820-01250-E3N6 | S-N80 | S-N65 | НФ250-СВУ3П225А | НФ250-СВУ3П175А |
ФР-Ф820-01540-Э360 | S-N95 | S-N80 | НФ250-СВУ3П250А | НФ250-СВУ3П225А |
ФР-Ф820-01870-Э360 | S-N150 | S-N125 | NF4SWU3300BB | NF4SWU3300BB |
ФР-Ф820-02330-Э360 | S-N180 | S-N150 | NF4SWU3400BB | NF4SWU3350BB |
ФР-Ф820-03160-Э360 | S-N220 | S-N180 | – | NF4SWU3400BB |
FR-F820-03800-E3U6 | – | S-N300 | – | NF4SWU3400BB |
FR-F820-04750-E3U6 | – | S-N300 | – | NF6SWU3500BB |
400 вольт | ||||
FR-F840-00023-E3N6 | S-T10 | S-T10 | НФ100-ХРУ3П5А | НФ100-ХРУ3П5А |
FR-F840-00038-E3N6 | S-T10 | S-T10 | НФ100-ХРУ3П10А | НФ100-ХРУ3П10А |
FR-F840-00052-E3N6 | S-T10 | S-T10 | НФ100-ХРУ3П10А | НФ100-ХРУ3П10А |
FR-F840-00083-E3N6 | S-T10 | S-T10 | НФ125-СВУ3П20А | НФ125-СВУ3П15А |
FR-F840-00126-E3N6 | S-T10 | S-T10 | НФ125-СВУ3П30А | НФ125-СВУ3П20А |
FR-F840-00170-E3N6 | С-Т20, С-Т21 | S-T12 | НФ125-СВУ3П30А | НФ125-СВУ3П30А |
FR-F840-00250-E3N6 | С-Т20, С-Т21 | С-Т20, С-Т21 | НФ125-СВУ3П50А | НФ125-СВУ3П40А |
FR-F840-00310-E3N6 | С-Т20, С-Т21 | С-Т20, С-Т21 | НФ125-СВУ3П60А | НФ125-СВУ3П50А |
FR-F840-00380-E3N6 | S-T25 | С-Т20, С-Т21 | НФ125-СВУ3П75А | НФ125-СВУ3П60А |
FR-F840-00470-E3N6 | S-T25 | S-T25 | НФ125-СВУ3П100А | НФ125-СВУ3П75А |
FR-F840-00620-E3N6 | S-N35 | S-T25 | НФ125-СВУ3П125А | НФ125-СВУ3П100А |
ФР-Ф840-00770-Э360 | S-N50 | S-N50 | НФ250-СВУ3П150А | НФ125-СВУ3П125А |
ФР-Ф840-00930-Э360 | S-N65 | S-N65 | НФ250-СВУ3П175А | НФ250-СВУ3П150А |
ФР-Ф840-01160-Э360 | S-N80 | S-N80 | НФ250-СВУ3П200А | НФ250-СВУ3П175А |
ФР-Ф840-01800-Э360 | S-N80 | S-N95 | – | НФ250-СВУ3П225А |
Номер модели | замыкатель | Автоматический выключатель | ||
Нет DCL | С ДКЛ | Нет DCL | С ДКЛ | |
FR-F840-02160-E3U6 | – | S-N150 | – | НФ250-СВУ3П225А |
FR-F840-02600-E3U6 | – | S-N180 | – | НФ250-СВУ3П225А |
FR-F840-03250-E3U6 | – | S-N220 | – | NF4SWU3400BB |
FR-F840-03610-E3U6 | – | S-N300 | – | NF4SWU3400BB |
FR-F840-04320-E3U6 | – | S-N300 | – | NF4SWU3400BB |
FR-F840-04810-E3U6 | – | S-N300 | – | NF6SWU3500BB |
FR-F840-05470-E3U6 | – | S-N400 | – | NF6SWU3600BB |
FR-F840-06100-E3U6 | – | S-N600 | – | NF6SWU3600BB |
FR-F840-06830-E3U6 | – | S-N600 | – | Продукт 700А |
FR-F842-07700-E3U6 | – | S-N600 | – | Продукт 700А |
+ FR-CC2-H315K-60 | ||||
FR-F842-08660-E3U6 | – | S-N600 | – | Продукт 700А |
+ FR-CC2-H315K-60 | ||||
FR-F842-07700-E3U6 | – | S-N600 | – | Продукт 800А |
+ FR-CC2-H355K-60 | ||||
FR-F842-08660-E3U6 | – | S-N600 | – | Продукт 800А |
+ FR-CC2-H355K-60 | ||||
FR-F842-09620-E3U6 | – | S-N600 | – | Продукт 800А |
+ FR-CC2-H355K-60 | ||||
FR-F842-07700-E3U6 | – | S-N800 | – | Продукт 900А |
+ FR-CC2-H400K-60 | ||||
FR-F842-08660-E3U6 | – | S-N800 | – | Продукт 900А |
+ FR-CC2-H400K-60 | ||||
FR-F842-09620-E3U6 | – | S-N800 | – | Продукт 900А |
+ FR-CC2-H400K-60 | ||||
FR-F842-10940-E3U6 | – | S-N800 | – | Продукт 900А |
+ FR-CC2-H400K-60 | ||||
FR-F842-08660-E3U6 | – | Продукт 1000А | – | Продукт 1000А |
+ FR-CC2-H450K-60 | ||||
FR-F842-09620-E3U6 | – | Продукт 1000А | – | Продукт 1000А |
+ FR-CC2-H450K-60 | ||||
FR-F842-10940-E3U6 | – | Продукт 1000А | – | Продукт 1000А |
+ FR-CC2-H450K-60 | ||||
FR-F842-12120-E3U6 | – | Продукт 1000А | – | Продукт 1000А |
+ FR-CC2-H450K-60 | ||||
FR-F842-09620-E3U6 | – | Продукт 1000А | – | Продукт 1200А |
+ FR-CC2-H500K-60 | ||||
FR-F842-10940-E3U6 | – | Продукт 1200А | – | Продукт 1500А |
+ FR-CC2-H560K-60 | ||||
FR-F842-12120-E3U6 | – | Продукт 1400А | – | Продукт 2000А |
+ FR-CC2-H630K-60 |
Ключ к кодам дисплея клавиатуры DU08
Имя функции | Описание | индикация | |
Сообщение об ошибке *2 | Блокировка панели управления | Попытка операции во время блокировки панели управления | |
Ошибка записи параметра | Произошла ошибка при записи параметра | в | |
Ошибка операции копирования | Произошла ошибка при копировании параметра | в | |
Ошибка | Сигнал RES включен или PU и инвертор не могут установить нормальную связь | ||
Предотвращение опрокидывания (перегрузка по току) | Защита от перегрузки по току | ||
Предупреждения *3 |
Предотвращение остановки (Оверволtage) | Оверволtage предотвращение опрокидывания. Появляется, когда активирована функция предотвращения регенерации. | |
Электронное тепловое реле Функция Предварительная тревога | Электронное тепловое реле O/L достигло 85% от указанного значения. | ||
ПУ Стоп | Стоп/сброс на панели управления нажат во время внешнего управления | ||
Выходной сигнал технического обслуживания | Совокупное время подачи питания превысило установленное значение таймера выхода обслуживания. | ||
Незначительный Вина | Ошибка вентилятора *4 | Вентилятор охлаждения неисправен | |
Отключение при перегрузке по току Во время Ускорение | Возник перегруз по току во время разгона | ||
Отключение при перегрузке по току при постоянной скорости | Перегрузка по току во время работы на постоянной скорости | ||
Отключение при перегрузке по току Во время Замедление или остановка | Перегрузка по току во время торможения и при остановке | ||
Регенеративный Оверволtage Отключение при ускорении | Оверволtage произошло во время разгона | ||
Регенеративный Оверволtage Отключение при постоянной скорости | Оверволtage произошло во время работы на постоянной скорости | ||
Регенеративный Оверволtage Отключение во время торможения или Стоп | Оверволtage произошло во время торможения и при остановке | ||
Отключение инвертора при перегрузке (электронный тепловой O/L Реле)*1 | Функция электронного теплового реле для защиты элементов инвертора активирована. | ||
Отключение двигателя при перегрузке (электронный тепловой O/L Реле)*1 | Функция электронного теплового реле для защиты двигателя активирована | ||
Перегрев плавника | Радиатор перегрелся | ||
Серьезные неудачи *5 |
Мгновенный сбой питания Protection | Произошел мгновенный сбой питания на входе источника питания | |
Андерволtage Защита | Основная цепь постоянного тока voltagе стал низким | ||
Сбой входной фазы | Обрыв одной из трех фаз на стороне входа инвертора | ||
Предотвращение остановки | Выходная частота упала до 0.5 Гц в результате торможения из-за чрезмерной нагрузки двигателя. | ||
Замыкание на землю на стороне выхода Защита от перегрузки по току | Произошло замыкание на землю на стороне выхода инвертора. | ||
Защита от обрыва выходной фазы. | Обрыв одной из трех фаз на выходе инвертора | ||
Внешнее тепловое реле Операция *6 | Сработало внешнее тепловое реле, подключенное к клемме ОН. | ||
Работа термистора PTC | Состояние перегрева двигателя определяется в течение 10 с или более с помощью входа внешнего термистора PTC, подключенного к клемме AU. | ||
Аварийный сигнал блока HC | В дополнительной плате возник аварийный сигнал или к клеммам R/L1, S/L2, T/L3 подключен источник питания переменного тока, когда установлено подключение преобразователя высокой мощности. | ||
Ошибка функциональной опции | Произошла ошибка связи в опции связи | ||
Отключение дополнительной карты | Карта отключена или подключена неправильно | ||
Устройство хранения параметров Сигнализация | Нарушилась работа элемента, в котором хранятся параметры (плата управления) | ||
Отключение ПУ | Произошла ошибка связи между PU и инвертором, интервал связи превысил допустимое время во время связи RS-485 с разъемом PU, или ошибки связи превышают количество повторных попыток во время связи RS-485. |
Ноты:
- Сброс инвертора инициализирует встроенные внутренние тепловые данные функции электронного теплового реле.
- Сообщение об ошибке указывает на операционную ошибку. Выход инвертора не отключен.
- Предупреждения — это сообщения, выдаваемые до того, как произойдут серьезные сбои. Выход инвертора не отключен.
- Незначительные неисправности предупреждают оператора о сбоях с выходом. Выход инвертора не отключен.
- При возникновении серьезных сбоев активируются защитные функции, отключающие выход инвертора и выдающие аварийные сигналы.
- Внешний термодатчик работает только тогда, когда сигнал OH установлен в Pr. 178 до Пр. 189 (выбор функции входного терминала).
Опции и аксессуары для FR-F800
Номер модели |
Тип |
Описание |
FR-A8AX | Ввода / вывода | 16-битная карта цифрового ввода |
FR-A8AY | Ввода / вывода | Плата цифрового выхода/расширенного аналогового выхода |
ФР-А8АР | Ввода / вывода | Плата релейных выходов |
FR-A8AC | Ввода / вывода | Вариант управления A/F800 120 В |
ФР-А8АН | Ввода / вывода | Плата ввода/вывода F/A800 4–20 мА |
FR-A8NC | Коммуникация | Коммуникационная карта CC-Link |
ФР-А8НД | Коммуникация | Плата связи DeviceNet |
ФР-А8НП | Коммуникация | Коммуникационная карта Profibus DPV0 |
A8NDPV1 | Коммуникация | Коммуникационная карта Profibus DPV1 |
FR-A8NF | Коммуникация | Коммуникационная карта FL-Net |
A8N-XLT | Коммуникация | Мультипротокольная карта связи RS-485 |
А8НЭИП-2П | Коммуникация | Плата IP-коммуникации EtherNET |
А8НПРТ-2П | Коммуникация | Коммуникационная карта Profinet |
А8НЕКТ-2П | Коммуникация | Коммуникационная карта EtherCAT® |
A8NETH-2P | Коммуникация | Многопротокольная коммуникационная карта EtherNET |
FR-A8NCE | Коммуникация | Коммуникационная карта CC-Link IE |
A8NC-КОН | Коммуникация | Коммуникационная карта CC-Link и разъемы |
FR-LU08 | Аксессуар | Жидкокристаллическая панель управления |
ФР-ПУ07 | Аксессуар | Блок параметров |
ФР-ПУ07-01 | Аксессуар | Единица параметра (тип HVAC) |
FR-PU07BB-L | Аксессуар | Блок параметров с резервным аккумулятором |
FR-CB201 | Аксессуар | Соединительный кабель блока параметров 1 м |
FR-CB203 | Аксессуар | Соединительный кабель блока параметров 3 м |
FR-CB205 | Аксессуар | Соединительный кабель блока параметров 5 м |
FR-АДП | Аксессуар | Блок адаптера клавиатуры для подключения FR-DU08 |
FR-A8TAT | Аксессуар | Адаптер клеммной колодки управления |
ФР-А8ТР | Аксессуар | Опция винтовой клеммной колодки |
FR-HC2 | Аксессуар | Контроллер подавления гармоник |
FR-HEL | Аксессуар | Дроссель звена постоянного тока 240 В |
FR-HEL-H | Аксессуар | Дроссель звена постоянного тока 480 В |
FR-HEL-C | Аксессуар | Дроссель звена постоянного тока 600 В |
FR-Конфигуратор2 | Software | Утилита настройки программного обеспечения для серии 800 |
Знаки и бренды третьих лиц являются собственностью их соответствующих владельцев.
МИЦУБИСИ ЭЛЕКТРИЧЕСКАЯ АВТОМАТИЗАЦИЯ, ИНК.
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Февраль 2022
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