Toshiba ME00070B Remote Starter User Manual

CONTENTS
10.3
CONTENTS
Quick Start
AC53b Utilisation Codes ....................................... 32
2
1. Caution Statements
1.1
Cautions and warnings ............................................ 3
2. General Description
2.1
2.2
Feature list .............................................................. 4
Part Number format ................................................ 4
3. Specifications
3.1
3.2
3.3
3.4
3.5
Current ratings ........................................................
Dimensions & weights .............................................
Semiconductor fuses ..............................................
Power terminations .................................................
General technical data ............................................
5
7
7
8
8
4. Installation
4.1
4.2
4.3
4.4
General layout diagrams ......................................... 9
Power termination configuration .............................. 9
Mounting instructions .............................................. 9
Ventilation ............................................................. 10
5. Power Circuits
5.1
5.2
5.3
5.4
5.5
5.6
5.7
Overview ..............................................................
3 Wire connection .................................................
3 Wire connection (Bypass operation) ...................
6 Wire connection .................................................
6 Wire connection (Bypass operation) ...................
Power factor correction .........................................
Line contactors .....................................................
11
11
11
11
11
11
12
6. Control Circuits
6.1
6.2
6.3
6.4
Electrical Schematic ..............................................
Control Supply ......................................................
Control Wiring .......................................................
RS485 Serial Communication ...............................
13
13
13
14
7. Programming & Operation
7.1
7.2
7.3
7.4
Programming Procedure .......................................
Function List .........................................................
Function Descriptions ...........................................
Operation ..............................................................
17
18
18
24
8. Application Examples
8.1
8.2
8.3
8.4
Installation With Line Contactor .............................
Installation With Bypass Contactor ........................
Soft Braking ..........................................................
Two Speed Motor .................................................
26
26
27
28
9. Trouble Shooting
9.1
9.2
9.3
9.4
Trip Codes ............................................................
Trip Log ................................................................
General Faults ......................................................
Tests and Measurements ......................................
29
30
30
31
10. Appendix
10.1
10.2
Typical Start Current Requirements ...................... 32
AC53a Utilisation Codes ....................................... 32
TMS7 SERIES
ME00070B
1
QUICK START
QUICK START
4.
Use the <UP> and/or <DOWN> keys adjust the FLC
setting to match the FLC of the connected motor.
For simple applications TMS7 soft starters can be installed using
the three simple steps outlined below. For applications with
advanced control, protection or interface requirements a
comprehensive review of this Users Manual is recommended.
5.
Press the <STORE> key to store the new FLC setting.
6.
Exit the programming mode by simultaneously pressing
then releasing the <FUNCTION> and <STORE> keys.
1. Installation & Connection
WARNING - ELECTRICAL SHOCK HAZARD
The TMS7 contains dangerous voltages when connected to
line voltage. Only a competent electrician should carry out
the electrical installation. Improper installation of the motor
or the TMS7 may cause equipment failure, serious injury or
death. Follow this manual and National Electrical Codes
(NEC ®) and local safety codes.
1. Ensure the correct TMS7 model has been selected for the
connected motor and application type.
2. Mount the TMS7 making sure to allow adequate clearance
top and bottom for the free circulation of air through the
starter. (Refer to section 4.3 Mounting Instructions for further
detail.)
3. Connect the supply cables to starter input terminals L1, L2 &
L3.
3. Operation
4. Connect the motor cables to starter output terminals T1, T2
& T3.
The TMS7 is now ready to control the motor. Motor operation
can be controlled using the <START> and <STOP> keys on the
TMS7 local control panel. Two other commonly used functions
that may be useful for basic installations are Function 2. Current
Limit and Function 5. Stop Ramp Time. These functions can be
adjusted in the same manner as described above. (For a more
detailed description of the programming procedure refer to
section 7.1 Programming Procedure.)
5. Connect a control supply to starter input terminals A1 & A2
or A2 & A3. (Refer to section 6.2 Control Supply for further
detail).
(OP TIONAL)
F1
L1
T1
L1B
L2
3 PHASE
SUPPLY
T2
L3
T3
L3B
C45 models
460V
C24 model s
+10
-15
400V
+10
-15
230V
OR
575V
M
L2B
A1
+10
-15
A2
+10
-15
A3
OR
E
Legend
F1
Semiconductor Fuses
2. Programming
Basic application requires only that the TMS7 be programmed
with the connected motor's nameplate full load current (FLC). To
program the TMS7 with the motor's FLC do the following:
1.
Put the TMS7 into program mode by simultaneously
pressing then releasing the <FUNCTION> and <STORE>
keys.
2.
Select Function 1. Motor Full Load Current by holding
down the <FUNCTION> key and then press the <UP> key
until the display shows "1".
3.
Release the <FUNCTION> key to display the currently
stored value of Function 1. Motor Full Load Current.
2
ME00070B
TMS7 SERIES
CAUTION STATEMENTS
Caution Statements
WARNING - ELECTRICAL SHOCK
HAZARD
CAUTION
This symbol is used throughout this manual to
draw attention to topics of special importance
to the installation and operation of the TMS7
soft starter.
The TMS7 contains dangerous voltages when
connected to line voltage. Only a competent
electrician should carry out the electrical
installation. Improper installation of the motor
or the TMS7 may cause equipment failure,
serious injury or death. Follow this manual
and National Electrical Codes (NEC®) and
local safety codes.
GROUNDING AND BRANCH
CIRCUIT PROTECTION
CAUTION
It is the responsibility of the user or person
installing the TMS7 to provide proper
grounding and branch circuit protection
according to the National Electric Code
(NEC ®) and local codes.
It is the installers responsibility to adhere to all instructions in
this manual, to follow good electrical practice and to seek advice
before operating this equipment in a manner other than as
detailed in this manual.
•
Ensure that the TMS7 is completely isolated from the power
supply before attempting any work on the unit.
•
Do not apply voltage to the control input terminals. These
are active 12/24VDC inputs and must be controlled with
potential free circuits.
•
Ensure contacts/switches operating the control inputs are
suitable for low voltage, low current switching ie, gold flash
or similar.
•
Ensure cables to the control inputs are segregated from AC
power and control wiring.
•
Entry of metal swarf into the cabinet can cause equipment
failure.
•
Do not connect Power Factor Correction capacitors to the
output of the TMS7. If static power factor correction is
employed, it must be connected to the supply side of the
TMS7.
•
Before installing the TMS7 without a line contactor ensure
such connection meets local regulations and by -laws.
•
If installing the TMS7 within a non-ventilated enclosure a
bypass contactor must be utilised to prevent excessive heat
build-up.
•
If installing a by-pass contactor ensure phase connections
are correctly made
ie
L1B-T1, L2B-T2, L3B-T3
•
Removing control voltage resets the thermal model.
The examples and diagrams in this manual are included solely for illustrative
purposes. Users are cautioned that the information contained in this manual
is subject to change at any time and without prior notice. In no event will
responsibility or liability be accepted for direct or indirect or consequential
damages resulting from the use or application of this equipment.
TMS7 SERIES
ME00070B
3
GENERAL DESCRIPTION
2.2 Part Number Format
General Description
TMS7-
2.1 Feature List
-
-
-
Enclosure
E0 = IP00
E4 = IP42
Control Supply Voltage
C24 = 230 VAC & 400 VAC
C45 = 460 VAC & 575 VAC
Supply Voltage
V5 = 200 VAC ~ 525 VAC
V7 = 200 VAC ~ 690 VAC
Nominal kW Ratings (@ AC53a 3- 30:70-10)
eg. 4022 = 22kW
Starting
•
Current Limit mode.
•
Ramp Start mode.
Stopping
•
Soft stop.
•
Pump stop.
•
Soft braking.
Protection
•
Overcurrent protection.
•
Motor thermistor input.
•
Current imbalance.
•
Phase rotation.
•
Stall protection.
•
Undercurrent.
•
Supply frequency.
•
Shorted SCR.
•
Power circuit.
•
Motor connection.
•
RS485 failure.
Interface
•
Remote control inputs
(4 x fixed).
•
Relay outputs
(1 fixed, 3 x programmable).
•
4-20mA output (1 x fixed).
•
RS485 link.
Human Interface
•
Local push buttons.
(Start, Stop, Reset, Local/Remote)
•
Local programming buttons.
(Function,Up,Down, Store)
•
LED parameter display
•
Phase indicator LEDs
Power connection.
•
3 Wire
•
6 Wire
•
Bypass connections to retain motor
protection even when bypassed.
•
17 Amps to 1562 Amps (3 Wire)
26 Amps to 2345 Amps (6 Wire)
•
200VAC to 525VAC (V5 models)
•
200VAC to 690VAC (V7 models)
Sundry features
•
IP42 (<253 Amps)
•
IP00 (>302 Amps)
•
Current read-out
•
Motor temperature read-out
•
Fault History (eight position).
•
Multiple function sets.
•
Restart Delay.
•
Low current alarm.
•
High current alarm.
•
Motor overtemperature alarm.
•
Auto-reset.
•
Function lock/Password protection.
•
Load defaults function settings.
4
ME00070B
TMS7 SERIES
SPECIFICATIONS
Specifications
3.1 Current Ratings
TMS7-4007
TMS7-4015
TMS7-4018
TMS7-4022
TMS7-4030
TMS7-4037
TMS7-4045
TMS7-4055
TMS7-4075
TMS7-4090
TMS7-4110
TMS7-4132
TMS7-4150
TMS7-4185
TMS7-4220
TMS7-4250
TMS7-4315
TMS7-4400
TMS7-4500
TMS7-4600
TMS7-4700
TMS7-4800
TMS7 SERIES
17
33
38
44
67
87
94
123
137
198
236
244
302
405
513
585
628
775
897
1134
1385
1563
15
29
34
39
58
75
81
106
119
171
204
211
267
361
456
524
568
710
831
989
1210
1366
14
26
30
35
51
66
71
93
105
151
179
186
233
313
393
450
489
606
706
872
1066
1202
AC53a 3-10:70-10
45oC <1000 metres
12
22
26
30
45
58
62
81
92
132
156
164
201
267
331
376
412
502
578
759
921
1030
TMS7-4007
TMS7-4015
TMS7-4018
TMS7-4022
TMS7-4030
TMS7-4037
TMS7-4045
TMS7-4055
TMS7-4075
TMS7-4090
TMS7-4110
TMS7-4132
TMS7-4150
TMS7-4185
TMS7-4220
TMS7-4250
TMS7-4315
TMS7-4400
TMS7-4500
TMS7-4600
TMS7-4700
TMS7-4800
ME00070B
26
50
57
66
101
131
141
185
206
297
354
366
453
608
770
878
942
1163
1346
1701
2078
2345
Start Current (%FLC)
350%
400%
23
44
51
59
87
113
122
159
179
257
306
317
401
542
684
786
852
1065
1247
1484
1815
2049
21
39
45
53
77
99
107
140
158
227
269
279
350
470
590
675
734
909
1059
1308
1599
1803
450%
AC53a 4.5-30:70-10
45oC <1000 metres
300%
AC53a 4-20:70-10
45oC <1000 metres
450%
AC53a 4.5-30:70-10
45oC <1000 metres
AC53a 4-20:70-10
45oC <1000 metres
Start Current (%FLC)
350%
400%
AC53a 3.5-15:70-10
45oC <1000 metres
AC53a 3-10:70-10
45oC <1000 metres
300%
Continuous Operation (Not Bypassed), 6 Wire Connection
AC53a 3.5-15:70-10
45oC <1000 metres
Continuous Operation (Not Bypassed), 3 Wire Connection
18
33
39
45
68
87
93
122
138
198
234
246
302
401
497
564
618
753
867
1139
1382
1545
5
SPECIFICATIONS
TMS7-4007
TMS7-4015
TMS7-4018
TMS7-4022
TMS7-4030
TMS7-4037
TMS7-4045
TMS7-4055
TMS7-4075
TMS7-4090
TMS7-4110
TMS7-4132
TMS7-4150
TMS7-4185
TMS7-4220
TMS7-4250
TMS7-4315
TMS7-4400
TMS7-4500
TMS7-4600
TMS7-4700
TMS7-4800
6
18
34
41
47
67
88
96
125
141
202
238
254
302
405
513
585
628
775
897
1153
1403
1574
18
34
41
47
62
82
90
120
127
187
224
228
285
395
513
585
626
775
897
1153
1403
1574
16
34
41
47
54
71
78
103
111
162
194
198
245
336
435
504
528
672
798
1006
1275
1474
14
28
34
39
47
61
66
88
96
140
166
172
209
282
356
410
436
542
632
850
1060
1207
ME00070B
TMS7-4007
TMS7-4015
TMS7-4018
TMS7-4022
TMS7-4030
TMS7-4037
TMS7-4045
TMS7-4055
TMS7-4075
TMS7-4090
TMS7-4110
TMS7-4132
TMS7-4150
TMS7-4185
TMS7-4220
TMS7-4250
TMS7-4315
TMS7-4400
TMS7-4500
TMS7-4600
TMS7-4700
TMS7-4800
27
51
62
71
101
132
144
188
212
303
357
381
453
608
770
878
942
1163
1346
1730
2105
2361
27
51
62
71
94
122
136
181
190
281
336
342
427
592
770
878
939
1163
1346
1730
2105
2361
450%
AC53b 4.5-30:330
45oC <1000 metres
Start Current (%FLC)
350%
400%
AC53b 4-20:340
45oC <1000 metres
300%
AC53b 3-10:350
45oC <1000 metres
450%
AC53b 4.5-30:330
45oC <1000 metres
AC53b 4-20:340
45oC <1000 metres
Start Current (%FLC)
350%
400%
AC53b 3.5-15:345
45oC <1000 metres
AC53b 3-10:350
45oC <1000 metres
300%
Bypassed Operation, 6 Wire Connection
AC53b 3.5-15:345
45oC <1000 metres
Bypassed Operation ,3 Wire Connection
24
51
62
71
82
106
117
155
166
243
290
297
368
504
653
756
793
1009
1197
1509
1912
2212
20
42
52
59
71
91
99
132
145
210
250
259
314
424
534
614
654
813
948
1276
1591
1811
TMS7 SERIES
SPECIFICATIONS
3.2 Dimensions & Weights
A
B
mm
mm
3.3
C
a
b
Wei
ght
mm
mm
mm
Kg
Semiconductor fuses can be used with the TMS7 to reduce the
potential of damage to SCRs from transient overload currents
and for Type 2 coordination. Suitable Bussman semiconductor
fuses are detailed below.
IP42/NEMA 1
TMS7-4007
TMS7-4015
TMS7-4018
TMS7-4022
TMS7-4030
TMS7-4037
TMS7-4045
TMS7-4055
TMS7-4075
TMS7-4090
TMS7-4110
TMS7-4132
TMS7-4150
TMS7-4185
TMS7-4220
TMS7-4250
TMS7-4315
TMS7-4400
TMS7-4500
TMS7-4600
TMS7-4700
TMS7-4800
380
185
180
365
130
6
380
185
250
365
130
7
425
270
275
410
200
17.5
425
390
275
410
IP00
300
23
F Series
Fuses
TMS7-4007
TMS7-4015
TMS7-4018
TMS7-4022
TMS7-4030
TMS7-4037
TMS7-4045
TMS7-4055
TMS7-4075
TMS7-4090
TMS7-4110
TMS7-4132
TMS7-4150
TMS7-4185
TMS7-4220
TMS7-4250
TMS7-4315
TMS7-4400
TMS7-4500
TMS7-4600
TMS7-4700
TMS7-4800
42
690
430
294
522
320
49
855
574
353
727
500
120
TMS7-4007 ~ TMS7-4132
o 6 .5
A
170M
Series
Fuses
TMS7-4007
TMS7-4015
TMS7-4018
TMS7-4022
TMS7-4030
TMS7-4037
TMS7-4045
TMS7-4055
TMS7-4075
TMS7-4090
TMS7-4110
TMS7-4132
TMS7-4150
TMS7-4185
TMS7-4220
TMS7-4250
TMS7-4315
TMS7-4400
TMS7-4500
TMS7-4600
TMS7-4700
TMS7-4800
o 12 .0
a
o 6 .5
b
B
C
TMS7-4150 ~ TMS7-4800
o 9 .0
o 16
A a
o 9 .0
b
B
Semiconductor Fuses
C
≤415VAC
63AFE
160AFEE
200FM
200FM
200FM
250FM
250FM
250FM
280FM
500FMM
630FMM
630FMM
630FMM
500FMM
700FMM
*500FMM
*500FMM
*700FMM
-
Supply Voltage
≤525VAC ≤575VAC
63AFE
63AFE
160AFEE 160AFEE
180FM
180FM
180FM
180FM
180FM
180FM
250FM
250FM
250FM
250FM
250FM
250FM
280FM
280FM
450FMM 450FMM
630FMM 630FMM
630FMM 630FMM
500FMM 500FMM
500FMM 500FMM
700FMM 700FMM
*500FMM *500FMM
*500FMM *500FMM
*700FMM *700FMM
-
Starter
I2 t
≤695VAC
63AFE
1,150
160AFEE
10,500
180FM
15,000
180FM
18,000
180FM
15,000
250FM
51,200
250FM
80,000
250FM
97,000
280FM
97,000
450FMM
145,000
630FMM
414,000
630FMM
414,000
500FMM
211,000
500FMM
320,000
700FMM
781,000
*500FMM 1,200,000
*500FMM 1,200,000
*700FMM 2,532,000
4,500,000
4,500,000
6,480,000
12,500,000
Supply Voltage
≤415VAC ≤525VAC ≤575VAC ≤695VAC
170M1315
170M1319
170M1319
170M1319
170M1319
170M3017
170M1322
170M1322
170M1322
170M6141
170M3023
170M3023
170M5144
170M6012
170M6014
170M5017
170M6019
170M6021
170M6021
170M6021
170M6021
170M6021
170M1314
170M1317
170M1318
170M1318
170M1318
170M3017
170M1321
170M1322
170M1322
170M6141
170M3023
170M3023
170M5144
170M4016
170M6014
170M6015
170M6018
170M6020
170M6020
170M6020
170M6021
170M6021
170M1314
170M1317
170M1318
170M1318
170M1318
170M3017
170M1321
170M1322
170M1322
170M6141
170M3023
170M3023
170M5144
170M6011
170M4018
170M6014
170M6017
170M6017
170M6151
170M6151
*170M5018
*170M5018
Starter
I2 t
170M1314
1,150
170M1317
10,500
170M1318
15,000
170M1318
18,000
170M1318
15,000
170M3017
51,200
170M1321
80,000
170M1322
97,000
170M1322
97,000
170M6141
145,000
170M3023
414,000
170M3023
414,000
170M5144
211,000
170M6011
320,000
170M4018
781,000
170M6014 1,200,000
170M6017 1,200,000
170M6017 2,532,000
170M6151 4,500,000
170M6151 4,500,000
*170M5018 6,480,000
*170M5018 12,500,000
*Two parallel connected fuses required per phase
TMS7 SERIES
ME00070B
7
SPECIFICATIONS
3.4
Power Terminations
6 mm
Outputs
Run Output (R34,R33) .......... Normally Open, 5A @ 250VAC/360VA
................................................................... 5A @ 30VDC resistive
Prog. Output A (R44,R43) ..... Normally Open, 5A @ 250VAC/360VA
................................................................... 5A @ 30VDC resistive
Prog. Output B (R24,R23) .... Normally Open, 5A @ 250VAC/360VA,
................................................................... 5A @ 30VDC resistive
Prog Output C (R14,R12,R11) ... Changeover, 5A @ 250VAC/360VA
....................................................................5A @ 30VDC resistive
Analogue Output (C6,C7) .................................................. 4-20mA
6 mm
14 mm
3 mm
1 6 mm
TMS7-4007~ TMS7-4022
(3.5 NM, 2.6 FT- LBS)
4 mm
TMS7-4030~ TMS7-4055
(3.5 NM, 2.6 FT-LBS)
8 mm
8 mm
20 mm
5 mm
26 mm
TMS7- 4075
(8.5 NM, 6.3 FT- LBS)
6 mm
TMS7-4090 ~ TMS7-4110
(8.5 NM, 6.3 FT-LBS)
10.5 mm
10 mm
28 mm
6 mm
32 mm
TMS7-4132
( 17 NM, 12.5 FT- LBS)
13 mm
TMS7-4150 ~ TMS7-4500
12.5 mm
51 mm
16 mm
TMS7-4600 ~ TMS7-4800
3.5 General Technical Data
Supply
Supply voltage (V5 models) ...... 3 x 200~525VAC (3 Wire Connection)
3 x 200~440VAC (6 Wire Connection)
Supply voltage (V7 models) .... 3 x 200~ 690VAC (3 Wire Connection)
3 x 200~440VAC (6 Wire Connection)
Electronics Supply (C24 models) ................... 230VAC (+10%/-15%)
or 400VAC (+10%/-15%)
Electronics Supply (C45 models) ................... 460VAC (+10%/-15%)
or 575VAC (+10%/-15%)
Supply frequency (at start) ......................................... 50Hz (± 2Hz)
or 60Hz (±2Hz)
Supply frequency (during start) ...................... > 45Hz (50Hz supply)
or > 55Hz (60Hz supply)
Supply frequency (during run) .......................... >48Hz (50Hz supply)
or > 58Hz (60Hz supply)
Sundry
Enclosure Rating TMS7-4007~4132 ........................ IP42 (NEMA 1)
Enclosure Rating TMS7-4150~4800 ................. IP00 (Open Chassis)
Rated short- circuit current (with semi-conductor fuses) ............ 100kA
Rated insulation voltage ...................................................... 690 V
Surges ......................................... 2kV line to earth, 1kV line to line
Fast transients ...................................................... 2.0kV / 5.0 kHz
Rated impulse withstand voltage ............................................ 2 kV
Form designation .............................................................. Form 1
Electrostatic discharge ...... 4kV contact discharge, 8 kV air discharge
Equipment class (EMC) ................................................... Class A1
Radio-frequency electromagnetic field 0.15 MHz - 80 MHz: 140dBµV
.................................................................80 MHz - 1 GHz: 10 V/m
Pollution degree ................................................ Pollution Degree 3
Operating Temperatures ............................................ -5oC / +60oC
Relative Humidity ........................... 5 – 95% (max non condensing)
1 This product has been designed for class A equipment. Use of
the product in domestic environments may cause radio
interference, in which case the user may be required to employ
additional mitigation methods.
Standards Approvals
CE ..................................................................... IEC 60947-4-2
UL1 ................................................................................ UL508
C-UL1 ............................................................. CSA 22.2 No.14
Cü .............................................. AS/NZS 3947-4-2, CISPR-11
1 Requires the use of semi-conductor fuses; is applicable for
supply voltages up to 600V; excludes models TMS-4600 ~
TMS7-4800.
Control Inputs
Start (I34,I33) ................ Normally Open, Active 24VDC, 8mA approx.
Stop (I22,I21) ............. Normally Closed, Active 24VDC, 8mA approx.
Reset (I12,I11) ............ Normally Closed, Active 24VDC, 8mA approx.
FLC Select (I44,I43) .......Normally Open, Active 24VDC, 8mA approx.
8
ME00070B
TMS7 SERIES
INSTALLATION
Input/Output
Installation
Output
Input
6.1 General Layout Diagrams
TMS7-4007 ~ TMS7-4055
Input/Output
Input
Output
To adjust the bus bar configuration first remove the TMS7 cover
and main control module. Next loosen and remove the bus bar
fixing bolts. The bus bars can then be removed and reinstalled
into the starter in the desired configuration. The fixing bolts
should then be refitted and tightened to a torque of 8.5NM.
When re-orienting bus bars L1, L2, L3 the current transformers
must also be relocated.
TMS7-4075 ~ TMS7-4132
Care must be taken to ensure that foreign matter does not
contaminate the jointing compound and become trapped
between the bus bar and its mounting plate. If the paste does
become contaminated, clean and replace with a jointing
compound suitable for aluminium to aluminium, or aluminium to
copper joints.
4.3 Mounting Instructions
Models TMS7-4007 ~ 4132 can be wall mounted or installed
inside another enclosure. These models can be mounted side
by side with no clearance but a 100mm allowance must be
made top and bottom for air intake and exhaust.
100mm Minimum Clearance 100mm Minimum Clearance
100mm Minimum Clearance
100mm Minimum Clearance 100mm Minimum Clearance
100mm Minimum Clearance
TMS7-4150 ~ TMS7-4800
Models TMS7-4150 ~ 4800 have an IP00 rating and must be
mounted in another enclosure. These models can be mounted
side by side with no clearance but a 200mm allowance must be
made top and bottom for air intake and exhaust.
200mm Minimum Clearance
200mm Minimum Clearance
4.2 Power Termination Configuration
The bus bars on models TMS7-4150 ~ TMS7-4800 can be
adjusted to provide four different input/output power terminal
configurations.
200mm Minimum Clearance
TMS7 SERIES
ME00070B
200mm Minimum Clearance
9
INSTALLATION
4.4 Ventilation
When installing TMS7 starters in an enclosure there must be
sufficient air flow through the enclosure to limit heat rise within
the enclosure. Temperature within the enclosure must be kept
at, or below, the TMS7 maximum ambient temperature rating.
If installing an TMS7 within a totally sealed enclosure a bypass
contactor must be employed to eliminate heat dissipation from
the soft starter during run.
Soft starters dissipate approximately 4.5 watts per amp. The
table below shows air flow requirements for selected motor
currents. If other heat sources are installed in an enclosure
along with the TMS7 an additional air flow allowance must be
made for these items. Note that heat generation from
semiconductor fuses, if used, can be eliminated by installing
these within the bypass loop.
Motor
Amps
10
20
30
40
50
75
100
125
150
175
200
250
300
350
400
450
500
550
600
10
Heat
(watts)
45
90
135
180
225
338
450
563
675
788
900
1125
1350
1575
1800
2025
2250
2475
2700
Required Airflow
m3/min
m3/hour
5oC 10oC 5oC 10oC
Rise Rise Rise Rise
0.5 0.2
30
15
0.9 0.5
54
27
1.4 0.7
84
42
1.8 0.9
108 54
2.3 1.1
138 69
3.4 1.7
204 102
4.5 2.3
270 135
5.6 2.8
336 168
6.8 3.4
408 204
7.9 3.9
474 237
9.0 4.5
540 270
11.3 5.6
678 339
13.5 6.8
810 405
15.8 7.9
948 474
18.0 9.0
1080 540
20.3 10.1 1218 609
22.5 11.3 1350 675
24.8 12.4 1488 744
27.0 13.5 1620 810
ME00070B
TMS7 SERIES
POWER CIRCUITS
Power Circuits
Connect the three OUTPUT terminals (T1, T2, T3) of the TMS7
to the motor windings ensuring that the connections are made to
one end of each winding only. It is imperative to connect the
output of the TMS7 to the same end of each winding and this is
usually marked on the motor terminations.
5.1 Overview
TMS7 starters can be wired with a number of different power
circuits depending on application requirements.
L1
L2
L3
5.2 3 Wire Connection
This is the standard connection format. Supply voltage is
connected to the starter input terminals L1, L2 & L3. The motor
cables are connected to the soft starter output terminals T1, T2
& T3.
( OPTI ONAL)
K1 M
(OPTIONAL )
F1
L1
T1
MOTOR TERMINALS
6 WIRE CONNECTION
L1B
L2
3 PHASE
SUPPLY
T2
M
L2B
L3
T3
The six terminations to the motor windings are usually arranged
in two rows of three so that the links can be fitted across from
the top three terminations to the lower terminations. In this case
connect the TMS7 to the top terminations only. Connect the
other three motor terminals to the input of the TMS7 in a manner
that connects the end of each winding to a different phase from
the input.
This is most easily achieved by replacing each delta link in the
motor terminal box by one phase of the controller. For example
if the delta links are fitted U1-V2,V1-W2,W1-U2
- Connect the incoming phases to L1,L2,L3 on the TMS7.
- Connect the TMS7 to the motor. T1-U1, T2-V1, T3-W1
- Connect the other motor terminals to the TMS7’S input W2-L1,
U2-L2, V2-L3
L3B
Legend
T1
T2
T3
E
K1 Line Contactor
F1 Semiconductor Fuses
5.3 3 Wire Connection (Bypassed Operation)
TMS7 starters can be bypassed while the motor is running.
Special terminals (L1B, L2B, L3B) are provided for connection of
the bypass contactor. Use of these terminals enables the TMS7
to continue to provide all protection and current monitoring
functions even when bypassed.
The TMS7 Run Output (Terminals R34 & R33) should be used
to control operation of the bypass contactor. The bypass
contactor can be AC1 rated for the motor full load current.
K 2M
5.5 6 Wire Connection (Bypassed Operation)
(OPTIONAL)
K1M
TMS7 units are capable of 6 Wire (Inside Delta) connection and
can be bypassed.
(O PT IONAL)
F1
L1
T1
L1B
L2
3 P HA SE
SUPP LY
T2
M
K2 M
L2B
L3
T3
L3B
E
K1 M
(OPTIONAL )
F1
L1
Run Output
T1
L1B
R33
Legend
K1M Line Contactor
K2M Bypass Contactor
F1
Semiconductor Fuses
3 PHAS E
S UP PLY
R34
U1
L2
T2
L2B
U2
M
W1
L3
K2M
V1
V2
W2
T3
L3B
E
5.4 6 Wire Connection
K 1M Line Con tactor
K 2M Bypass Co ntacto r
F1
Semiconductor Fuses
TMS7 units are capable of 6 Wire (Inside Delta) connection as
well as 3 Wire connection. When connected in this configuration
the soft starter carries only phase current, this means the motor
FLC current can be 50% greater than the soft starter’s FLC
current rating.
K1M
3 PHASE
SUPPLY
L2
U1
T2
L2B
L3
Lege nd
K1 Line Conta ctor
F1 Se micon ducto r Fuses
TMS7 SERIES
V1
W1
K 2M
CAUTION:
Under no circumstance should power factor
correction capacitors be connected between the
CAUTION soft starter and the motor. Connecting power
factor correction capacitors to the output of the
soft starter will result in damage to the soft
starter.
U2
M
R34
If static power factor correction is employed, it must be
connected to the supply side of the soft starter.
T1
L1 B
Run Output
5.6 Power Factor Correction
(OP TIO NA L)
F1
L1
R33
Legend
V2
W2
T3
L3B
E
ME00070B
11
POWER CIRUCITS
5.7 Line contactors
The TMS7 is designed to operate with or without a line
contactor. In many regions there is a statutory requirement that
a line contactor be employed with electronic motor control
equipment. From a safety point of view, this is the preferable
option, however is not necessary for starter operation. An
additional benefit gained by use of a line contactor is isolation of
the starter SCR’s in the off state, when they are most
susceptible to damage from voltage transients.
The TMS7 can directly control a line contactor via the Main
Contactor Control output.
As an alternative to a line contactor, either a circuit breaker with
a no volt release coil operated by the TMS7 trip output, or a
motor operated circuit breaker can be considered. If a motor
operated circuit breaker is used as a line contactor, the potential
delay between the breaker being told to close and phase power
being applied to the TMS7 could cause the TMS7 to trip on
installation faults. Closing the motorized breaker directly and
using the breaker’s auxiliary contacts, or preferably a slave relay
with gold flash contacts, to control the TMS7 can avoid this.
Line contactors must be selected such that their AC3 rating is
equal to or greater than the full load current rating of the
connected motor.
12
ME00070B
TMS7 SERIES
CONTROL CIRCUITS
Control Circuits
Input
Voltages
6.1 Electrical Schematic
(C45
L1
Models)
T1
L2
T2
OR
5 75V
C24 models
+10
-15
400V
+10
-15
2 30V
OR
FLC SELECT
+10
-15
+10
-15
A1
A2
C3
GND
C4
RS48 5 SERIAL
INTERFACE
A3
C5
I44
R44
PROGRAMMABLE
R 43 OUTPUT A
(Main Contactor)
I43
R3 4
I3 4
START
R33
I22
R23
I2 1
995-0083200
RUN OUTPUT
Remote push button control
PROGRAMMABLE
OUTPUT B
(Start/Run)
I44
R 14
I12
R ESET
995-0083100
I3 3
R2 4
STOP
995-0082900
TMS7 operation can be controlled using either the local push
buttons, remote control inputs or the serial communications link.
The <LOCAL/REMOTE> push button can be used to switch
between local and remote control. Refer to Function 20.
Local/Remote Operation for details.
Remote Control Inputs
The TMS7 has four remote control inputs. Contacts used for
controlling these inputs should be low voltage, low current rated
(Gold flash or similar).
E
C45 models
TMS7-4132~
TMS7-4800
6.3 Control Wiring
T3
L3 B
460V
TMS7-4030~
TMS7-4110
TO MOTOR
L2 B
L3
TMS7-4007~
TMS7-4022
110/230
VAC
L1B
3 PHASE
SUPPLY
Part Number
R12
I11
R11
I43
PROGRAMMABLE
OUTPUT C
I34
(Tripped)
I33
MOTOR
THERMISTOR
C1
C6
C2
C7
I22
4-20 mA OUTPUT
(MOTOR CUR RENT)
I21
I12
I11
6.2 Control Supply
R44
R43
R34
(C24
Models)
110/460
VAC
110/575
VAC
TMS7 SERIES
R24
TMS7-4132~
TMS7-4800
995-0082100
995-0082500
995-0082300
995-0082700
995-0082400
995-0082800
I 33
I 22
I 21
I 12
I 11
Start
Stop
Reset
The TMS7 provides four relay outputs, one fixed and three
programmable. Functionality of the programmable outputs is
determined by the settings of Functions 21, 22 & 23.
Part Number
TMS7-4030~
TMS7-4110
Reset
I 34
FLC Select
Relay Outputs
R33
TMS7-4007~
TMS7-40047
Stop
I 43
Ensure cables to the control inputs are
segregated from AC power and control wiring.
Maximum VA
11VA
18VA
24VA
41VA
56VA
For circumstances where the available control supply voltage is
not suitable for direct connection to the TMS7 the following
range of auto-transformers are available as accessories. These
auto-transformers can be mounted within the TMS7 in models.
Input
Voltages
Start
I 44
CAUTION:
Do not apply voltage to the control inputs. The
inputs are active 24VDC and must be controlled
with potential free circuits.
CAUTION
Ensure contacts/switches operating the control
inputs are suitable for low voltage, low current
switching ie, gold flash or similar.
Voltage must be connected to the TMS7 control voltage
terminals. The required control voltage is dependent upon the
TMS7 model ordered.
• TMS7xxxx-xx-C24-xx models: 230VAC (A2-A3) or 400VAC
(A1-A2)
• TMS7xxxx-xx-C45-xx models: 460VAC (A1-A2) or 575VAC
(A2-A3)
TMS7 Model
TMS7-4007~TMS7-4022
TMS7-4030~TMS7-4055
TMS7-4075~TMS7-4110
TMS7-4132~TMS7-4500
TMS7-4600~TMS7-4800
FLC Select
Two wire control
R23
R14
R12
R11
Programmable
Output A
(*Main Contactor)
Run Output
Programmable Output B
(*Start/Run)
Programmable
Output C
Functionality Assignmen
- Tripped
- Overcurrent trip
- Undercurrent trip
- Motor thermistor trip
- St arter overt emperature t
- Phase imbalance trip
- Electronic shearpin trip
- Low current alarm
- High current alarm
- Motor overload alarm
- St art/Run
- Main Contactor
(*Tripped)
* = default functionality
ME00070B
13
CONTROL CIRCUITS
Host controller to TMS7
Start signal
START
Output voltage
SEND TMS7
S LAV E ADDRES S
N
RELAY FUNCTIONS
ACK
N
RECEIV ED
Main contactor
TIMEOUT
Y
Y
D
Start/Run
DATA/ C
COMMA ND
SE ND REQUEST
SEND COMM AND
Run
Y
TI MEOUT
Pre-start Tests
C1
C2
Thermistor Input
Motor thermistors
C1
C2
Thermistor Input
N
ACK
N
RECEIV ED
DATA
RECI EVE D
Y
Y
N
LRC
VALID
Y
LRC
ERROR
TIME OUT
ERROR
E ND
TMS7 to host controller
START
NOTE:
The thermistor circuit must be closed before the
TMS7 will run.
N
EOT
DETECT
Y
RECEIVE
ADDRESS
CAUTION The thermistor circuit should be run in screened
N
cable and must be electrically isolated from earth
and all other power and control circuits.
N
ENQ
EOT
Y
Y
N
L RC
VALI D
If no motor thermistors are connected to the TMS7
thermistor input there must be a link across the
thermistor input terminals C1 & C2.
Y
N
ADDRESS
VALI D
Y
SEND ACK
6.4 RS485 Serial Communication
N
N
STX
EOT
Y
Y
The TMS7 has a non-isolated RS485 serial communication link.
RECEIVE DATA
RS485
TIME OUT
N
RE CE IVE DATA
Motor Thermistors
Motor thermistors (if installed in the motor) may be connected
directly to the TMS7. A trip will occur when the resistance of the
thermistor circuit exceeds approximately 2.8kΩ. The TMS7 can
be reset once the thermistor circuit resistance falls below
approximately 2.8kΩ
No motor thermistors
Y
N
- C3
GND C4
N
N
Y
EOT
ETX
Y
+ C5
N
L RC
VALI D
SEND NAK
Y
NOTE:
Power cabling should be kept at least 300mm away
from communications cabling. Where this cannot
CAUTION be avoided magnetic shielding should be provided
to reduce induced common mode voltages.
Data transmitted to and from the TMS7 must be in 8 bit ASCII,
no parity, 1 stop bit.
Baud rate is set by Function. 61 RS485 Baud Rate.
The TMS7 can be programmed to trip if the RS485 link fails by
setting Function 60. RS485 Timeout.
The starter address is assigned using Function 62. RS485
Satellite Address.
The flow charts below show typical form of communication
between an TMS7 and host controller.
14
N
SEND
DATA
CONTROL TMS7
Y
SEND DATA
SEND ACK
The following code sequences are used in the communications
between the host and the TMS7 (network).
Address slave unit.
ASCII EOT [nn]
ENQ
or
04h
[n1]h [n2]h
05h
LRC
[LRC1]h [LRC2]h
Slave response.
ASCII ACK
or
06h
ME00070B
TMS7 SERIES
CONTROL CIRCUITS
NOTE:
If no TMS7 starter is configured to the specific
slave address, no response will be received by the
host. The host software timeout should be set to a
CAUTION minimum of 250 ms.
Status
Read
ASCII
6=
7=
8=
9=
10 =
NOTE:
Slave address must be two digit, addresses less
than 10 must have a leading zero (0).
11 =
CAUTION
Master command to slave.
ASCII STX [command]
or
02h
[c1]h [c2]h [c3]h
Data Read ASCII
Current
D10
LRC
[LRC1]h [LRC2]h
ETX
03h
Temp
D12
[command] = 3 byte ASCII command (or request) selected from
the tables below.
LRC = Longitudinal Redundancy Check.
Slave response if Command and LRC correct
ASCII ACK
or
06h
Slave response of Read request correct and LRC correct.
ASCII STX [data]
LRC
ETX
or
02h
[d3]h [d2]h [d1]h [d0]h [LRC1]h [LRC2]h
03h
ASCII
STX
B
1
0
Each command, status or data request is a 3 byte string as
detailed below. Invalid command/request strings cause the
TMS7 to respond with a NAK (15h).
ASCII
Status_1
C12
Trip
Version
Trip Code
C14
C16
C18
TMS7 SERIES
C10
Comment
Requests motor current. The data is 4
byte decimal ASCII. Minimum value
0000, Maximum value 9999 Amps.
Requests the calculated value of the
motor thermal model as a % of Motor
Thermal Capacity. The data is 4 byte
decimal ASCII. Minimum value 0000%.
Trip point 0105%.
For example Command String (Start);
ASCII
STX
B
1
or
02h
42h
31h
Slave response if Read request or LRC invalid.
ASCII NAK
or
15h
Status
Read
Status
Phase rotation trip
Stall trip
Power circuit fault
Undercurrent trip
Starter heatsink
overtemperature
Invalid motor connection
Each command string sent to and from the TMS7 includes a
check sum. The form used is the Longitudinal Redundancy
Check (LRC) in ASCII hex. This is an 8-bit binary number
represented and transmitted as two ASCII hexadecimal
characters.
To calculate LRC:
1. Sum all ASCII bytes
2. Mod 256
3. 2's complement
4. ASCII convert
Slave response if Command and LRC incorrect
ASCII NAK
or
15h
Command ASCII
Start
B10
Stop
B12
Reset
B14
Coast to
B16
stop
Comment
Comment
Initiates a start.
Initiates a stop
Resets a trip state
Initiates an immediate removal of
voltage from the motor. Any soft
settings are ignored.
Hex
02h
42h
31h
30h
A5h
A5h
5Ah
01h
5Bh
ASCII 5
or
35h
B
42h
Binary
0000 0010
0100 0010
0011 0001
0011 0000
1010 0101
1010 0101
0101 1010
0101 1011
0101 1011
0
30h
SUM (1)
MOD 256 (2)
1's COMPLEMENT
+1=
2's COMPLEMENT (3)
ASCII CONVERT (4)
LRC CHECKSUM
The complete command string becomes
ASCII STX B
1
0
5
or
02h
42h 31h
30h
35h
Comment
Requests the configuration status of the
TMS7.
Requests the operational status of the
TMS7.
Requests the trip status of the TMS7.
RS485 protocol version number.
255 = No trip
0=
Shorted SCR
1=
Reserved
2=
Motor Thermal model trip
3=
Motor thermistor
4=
Current imbalance trip
5=
Supply frequency trip
ME00070B
B
42h
ETX
03h
To verify a received message containing an LRC;
1. Convert the last two bytes of message from ASCII to
binary.
2. Left shift 2nd to last byte 4 bits.
3. Add this result to the last byte to get the binary LRC.
4. Add up all the bytes of the message, except the last two.
5. Add the binary LRC.
6. The least significant byte should be zero.
For example:
ASCII
STX
ETX
B
1
0
5
B
15
CONTROL CIRCUITS
or
02h
03h
42h
31h
30h
35h
42h
Trip bits (negative logic 0 = true). The table below shows the
complement of these bits to give positive logic (1 = true).
Status Bit
Function
NOT Trip.7
Phase Loss
NOT Trip.6
Undercurrent
NOT Trip.5
Phase Rotation
NOT Trip.4
Overcurrent
NOT Trip.3
Over Temperature
NOT Trip.2
Installation
NOT Trip.1
Stall Protection
NOT Trip.0
Thermistor
1.
35h (ASCII hex) = 5H = 00000101
42h (ASCII hex) = Bh = 00001011
Note: 03h is the EXT character (end of transmission) and is
not part of the message.
2.
00000101 = 01010000
3.
01010000 + 00001011 = 01011011
4.
02h + 42h + 31h + 30h = A5h
5.
A5h + 5Bh = 100h
6.
The least significant byte is zero so the message and
LRC match.
Response or status bytes are sent from the TMS7 as an ASCII
string.
STX
d1 =
d2 =
d3 =
d4 =
[d1]h [d2]h [d3]h [d4]h LRC1 LRC2 ETX
30h
30h
30h plus upper nibble of status byte right shifted by four
binary places.
30h plus lower nibble of status byte.
For example status byte = 1Fh, response is
STX 30h
30h 31h
3Fh LRC1 LRC2 ETX
Status bits (positive logic 1 = true)
Status
Function
Comment
Bit
Status.7
50 Hz
Only one of either Status.7 or
Status.6 can be at logic 1 when the
TMS7 is operating.
Status.6
60 Hz
Status.5
Unallocated
Status.4
Soft stop
Status.3
Positive
Will be at logic 0 when there is a
phase
negative phase rotation.
rotation
Status.2
Unallocated
Status.1
Unallocated
Status.0
Unallocated
Status_1 bits (negative logic 0 = true)
Status Bit Function
Comment
NOT
Status_1.7
NOT
Status_1.6
NOT
Status_1.5
NOT
Restart
Status_1.4
Delay
NOT
Overload
Motor is operating in an overload
Status_1.3
condition.
NOT
Run
Status_1.2
NOT
Output On
Status_1.1
NOT
Power On
Status_1.0
16
ME00070B
TMS7 SERIES
PROGRAMMING
Programming
7.1 Programming Procedure
Step 1.
1.
Enter program mode.
Simultaneously press and release the <FUNCTION> and
<STORE> keys. (When in program mode the three LEDs
to the right of the numeric display will be illuminated.)
Step 4.
1.
2.
Step 2.
1.
2.
3.
Press the <STORE> key to store the displayed setting
into memory.
Verify the new set point has been correctly stored by
pressing and then releasing the <FUNCTION> key. The
LED display should now show the new set point.
Select the function number to be viewed
or adjusted.
Press and hold the <FUNCTION> key.
Using the <UP> and <DOWN> keys select the required
function number. (Function numbers are left justified
and blink).
When the required function number is dispalyed,
release the <FUNCTION> key. The display changes to
show the function set point currently stored in memory.
(Function values are right justified and do not blink)
Step 5.
1.
Step 3.
1.
Store the new function set point.
Exit program mode.
Once all function settings have been made, exit the
programming mode by simultaneously pressing and
releasing the <FUNCTION> and <STORE> keys.
Alter the function set point.
Review the current function set point and, if necessary,
use the <UP> or <DOWN> keys to adjust the setting.
(Pressing the <FUNCTION> key will restore the original
setting).
TMS7 SERIES
ME00070B
17
PROGRAMMING
7.2
Function List
No.
Function
Primary Motor Settings
1
2
3
4
5
6
7
8
9
Motor full load current
Current limit
Minimum current
Start ramp time
Stop ramp time
Motor trip class
Current imbalance sensitivity
Undercurrent protection
Stall protection
7.3
Default
Setting
1.
Soft stop mode
Default Setting: Model Dependant (Amps)
Description: Sets the TMS7 for the connected motor’s full load
current.
Adjustment: Set to the Full Load Current (amps) rating shown
on the motor nameplate.
2.
Local/Remote operation
Relay output A functionality
Relay output B functionality
Relay output C functionality
Default Setting: 350% FLC
Description: Sets the current limit for the Constant Current start
mode.
0
11
10
0
eg. Function 2. Current Limit = 350% x FLC
Protection Settings
30
31
32
Phase rotation
Restart delay
Current imbalance
Current Limit
Range: 100 – 550 % FLC
0
Starter Functionality
20
21
22
23
Motor Full Load Current
Range: Model Dependant (Amps)
350
350
1
0
10
5
20
400
Start/Stop Formats
10
Function Descriptions
700%
0
15
0
500%
Set Points
40
41
42
43
Low current alarm
High current alarm
Motor temperature alarm
Field calibration
50
105
80
100
300%
Analogue Output (Motor Current - % FLC)
50
51
4-20mA output range - max
4-20mA output range - min
100%
100
0
50%
Serial Communications
60
61
62
RS485 timeout
RS485 baud rate
RS485 satellite address
0
4
20
( % Full Speed)
Adjustment: The required setting for the Current Limit function
is installation dependant and should be set such that:
• The motor is supplied with sufficient start current to enable
it to produce torque adequate to easily accelerate the
connected load.
• Desired starting performance is obtained.
• TMS7 ratings are not exceeded.
Auto Reset
70
71
72
73
80
81
82
83
84
85
86
87
88
Auto-reset - configuration
Auto-reset - number of resets
Auto-reset - group A & B delay
Auto-reset - group C delay
Secondary Motor Settings
Motor full load current
Current limit
Minimum current
Start ramp time
Stop ramp time
Motor trip class
Current imbalance sensitivity
Undercurrent protection
Stall protection
0
1
5
5
350
350
1
0
10
5
20
400
3.
Current imbalance trip delay
Minimum Current
Range: 100 – 550 % FLC
Default Setting: 350% FLC
Description: Sets the minimum current level for the Ramp Start
mode.
Function. 2 Current Limit = 350% x FLC
Function. 3 Minimum Current = 200% x FLC
Function. 4 Start Ramp Time = 10 secs
Protection Delays
90
100%
ROTOR SPEED
700%
3
Read Only Data
100 Model Number
101 Fault History
-
500%
Restricted Functions
110
111
112
113
Access code
Update access code
Function lock
Restore function settings
0
0
0
0
300%
100%
50%
100%
ROTOR SPEED
(% Full Speed)
18
ME00070B
TMS7 SERIES
PROGRAMMING
Adjustment: Function 3 Minimum Current and Function 4 Start
Ramp Time are used together to activate and control the Ramp
Start mode.
If the Ramp Start mode is required, set the Minimum Current so
that the motor begins to accelerate immediately a start is
initiated. Ramp Start mode is not required, set the Minimum
Current equal to the Current Limit.
Ramp Start mode should be considered in preference to Current
Limit start mode in applications where:
• Required start torque can vary from start to start. For
example conveyors may start loaded or unloaded. In this
case set Function 3 Minimum Current to a level that will
start motor in the light load condition and Function 2
Current Limit to a level that will start the motor in the high
load condition.
• Starting time of an easily broken away load needs to be
extended, for example pumps.
• A generator set supply is limited and a slower application
of load will allow greater time for the generator set to
respond.
4.
Time or Maximum DOL Start Time. This information is available
from the motor data sheet or direct from the motor supplier.
NOTE:
The TMS7 motor thermal model assumes a
locked rotor current of 600%. If the connected
CAUTION motor’s locked rotor current differs from this,
greater accuracy can be achieved by using a
normalised MTC figure. A normalised MTC
figure can be calculated as follows:
2
 %LRC 
MTC = 
 X Max Start Time
 600 
NOTE:
Setting Function 6 Motor Trip Class according
to the motor’s actual thermal capacity allows
CAUTION safe use of the motor’s full overload capability
both to start the load and ride through overload
conditions. Additionally, a more conservative
approach can be taken by setting a reduced
MTC for easy to start loads that will not
experience transient operating overloads as a
part of normal operation.
Using a reduced MTC figure has the advantage
of maximising motor life. The life of a motor is
strongly influenced by its maximum winding
temperature, with a 'rule of thumb' stating that
the expected life span of a motor is halved for
every ten degree rise in temperature. The
temperature rise is dependent on the motor
losses and the motor cooling. The highest
stress on the motor is during start, and can be
minimised by restricting the duration and
frequency of starts. A reduced MTC setting
(Function 6) will also cause the TMS7
protection to operate before the motor is
thermally stressed.
Start Ramp Time
Range: 1 – 30 Seconds
Default Setting: 1 Second
Description: Sets the ramp time for the Current Ramp start
mode.
Adjustment: Set the Start Ramp Time to optimise start
performance.
5.
Stop Ramp Time
Range: 0 – 100 Seconds
Default Setting: 0 Second (Off)
Description: Sets the soft stop ramp time for soft stopping of
the motor.
Adjustment: Set the Stop Ramp Time to produce the desired
motor stopping performance.
Two soft stop modes are provided by the TMS7. Use Function
10. Soft Stop Mode to select the desired mode.
A suitable reduced MTC figure can be
established by observing the modeled motor
temperature as shown on the TMS7 LED
display, and adjusting the MTC parameter such
that after a normal start which has been
preceded by a period of running at maximum
load, the calculated motor temperature is
approaching 90%.
t(s)
If utilising the Soft Stop function and a line contactor, the
contactor must not be opened until the end of the stop ramp
time. The TMS7 programmable outputs A,B or C can be set for
control of the line contactor. Refer Functions 21, 22, 23 for
programmable output assignment details.
Cold start curves
10000
6.
Motor Trip Class
Range: 0 – 60 Seconds
Default Setting: 10 Seconds
1000
NOTE:
A setting of 0 seconds disables the TMS7 motor
thermal model. Use this setting only if another form
CAUTION of motor protection is used.
Description: Sets the motor thermal capacity used by the TMS7
motor thermal model.
Adjustment: Set the Motor Trip Class (MTC) according to the
motor’s thermal capacity.
100
MTC = 10 Sec
MTC = 5 Sec
A motor’s thermal capacity is expressed as the maximum time
(seconds) a motor can maintain locked rotor current conditions
from cold, and is often referred to as Maximum Locked Rotor
TMS7 SERIES
MTC = 30 Sec
MTC = 20 Sec
10
1
100
ME00070B
300
500
700
I (% FLC)
19
PROGRAMMING
7.
1 = TMS7 Local/Remote push button disabled while motor
running.
2 = Local control only. (TMS7 push buttons enabled, remote
inputs disabled)
3 = Remote control only. (TMS7 push buttons disabled, remote
inputs enabled)
Default Setting: 0 (Local/Remote button enabled)
Current Imbalance Sensitivity
Range: 1 – 10
1 = Highest sensitivity (lowest imbalance)
I
5 = Average sensitivity
I
10 = Lowest sensitivity (highest imbalance)
Description: Sets the sensitivity of the current imbalance
protection.
Description: Enables and disables the local push buttons and
remote control inputs. Also determines when and if the
Local/Remote push button can be used to switch between local
and remote control.
Adjustment: Set as required
Adjustment: The factory setting is suitable for most applications
however the sensitivity can be adjusted to accommodate site
specific tolerances
21.
Default Setting: 5
8.
Relay Output A Functionality
Range: 0 –11
0 = Tripped
1 = Overcurrent trip
2 = Undercurrent trip
3 = Motor thermistor trip
4 = Starter overtemperature trip
5 = Phase imbalance trip
6 = Electronic shearpin trip
7 = Low current alarm
8 = High current alarm
9 = Motor overload alarm
10 = Start/Run
11 = Main contactor.
Undercurrent Protection
Range: 15% – 100% FLC
Default Setting: 20% FLC
Description: Sets the trip point for the TMS7 undercurrent
protection as a percentage of motor full load current.
Adjustment: Set to a level below the motors normal working
range and above the motor’s magnetising (no load) current.
To disable the undercurrent protection make a setting less than
the magneti sing current of the motor, typically 25% - 35% of
rated Full Load Current.
NOTE:
Undercurrent protection is only operative during
‘run’.
Start signal
Output voltage
CAUTION
9.
Stall Protection
RELAY FUNCTIONS
Range: 80% – 550% FLC
Main contactor
Default Setting: 400% FLC
Description: Sets the trip point for the TMS7 stall protection as
a percentage of motor full load current.
Adjustment: Set as required.
Start/Run
Run
Pre-start Tests
NOTE:
Stall protection is operative only during ‘run’.
Default Setting: 11 (Main Contactor)
Description: Assigns the functionality of programmable relay
output A.
Adjustment: Set as required
CAUTION
10.
Soft Stop Mode
22.
Range: 0 – 1
0 = Standard soft stop
1 = Pump control
Range: 0 - 11
Default Setting: 10 (Start/Run)
Default Setting: 0 (Standard soft stop)
Description: Assigns the functionality of programmable relay
output B.
Description: Sets the active soft stop mode.
Adjustment: The standard soft stop mode automatically
monitors motor deceleration and will provide optimum control for
most applications. Pump control may however offer superior
performance in some applications and can be of particular
benefit in some pumping applications.
Adjustment: Refer Function 21 Relay Output A Functionality for
adjustment detail.
23.
Relay Output C Functionality
Range: 0 - 11
Default Setting: 0 (Tripped)
20.
Local/Remote Operation
Range: 0 – 3
0 = TMS7 Local/Remote push button always enabled.
20
Relay Output B Functionality
Description: Assigns the functionality of programmable relay
output C.
ME00070B
TMS7 SERIES
PROGRAMMING
Adjustment: Refer Function 21 Relay Output A Functionality for
adjustment detail.
30.
Adjustment: The motor overtemperature alarm can be assigned
to the Programmable Relay Outputs A, B or C for indication of a
motor temperature (as calculated by the Motor Thermal Model)
in excess of the programmed value.
A trip condition occurs when motor temperature reaches 105%.
Phase Rotation
Range: 0 – 2
0 = Off (forward and reverse rotation accepted)
1 = Forward rotation only (reverse rotation prohibited)
2 = Reverse rotation only (forward rotation prohibited)
Default Setting: 0 (Off)
43.
Default Setting: 100%
Description: Sets the valid phase rotations for the TMS7 phase
rotation protection. The TMS7 examines the incoming three
phases and trips if phase rotation does not match the allowable
rotations specified by Function 30.
Description: Adds a gain to the TMS7 current monitoring
circuits. The TMS7 is factory calibrated with an accuracy of ±
5%. The field calibration function can be used to match the
TMS7 current readout with an external current metering device.
Adjustment: Use the following formula to calculate the setting
required.
Current shown on TMS7 display
Field Calibration
=
(Function 43)
Current measured by external device
Adjustment: Set as required.
31.
Field Calibration
Range: 85% - 115%
Restart Delay
Range: 1 – 254 seconds
Default Setting: 15 Second
Description: Sets the minimum time between the end of a stop
and the beginning of the next start.
Adjustment: Set as required. During the restart delay period the
LEDs to the right of the TMS7 LED display will flash indicating
the motor cannot yet be restarted.
32.
e.g.
112 Amps
CAUTION
50.
4-20mA Output Range - Max
Range: 0 – 255%
Description: Enables or disables the phase imbalance
protection.
Adjustment: Set as required.
Default Setting: 100 %
Description: Determines the value represented by a 20mA
signal from the analogue output.
Adjustment: Set as required to show percentage of motor
current.
Low Current Alarm
Range: 1 – 100% FLC
Default Setting: 50% FLC
51.
Description: Sets the current level (% FLC) at which the low
current alarm operates.
4-20mA Output Range - Min
Range: 0 – 255%
Default Setting: 0 %
Adjustment: The low current alarm can be assigned to the
Programmable Relay Outputs A, B or C for indication of a motor
current lower than the programmed value.
41.
108 Amps
NOTE:
All current based functions are affected by this
adjustment.
Current Imbalance
Range: 0 – 1
0 = On
1 = Off
Default Setting: 0 (On)
40.
96% =
Description: Determines the value represented by a 4mA signal
from the analogue output.
Adjustment: Set as required to show percentage of motor
current.
High Current Alarm
Range: 50 – 550% FLC
Default Setting: 105% FLC
60.
Description: Sets the current level (% FLC) at which the high
current alarm operates.
Range: 0 – 100 Seconds
Adjustment: The high current alarm can be assigned to the
Programmable Relay Outputs A, B or C for indication of a motor
current in excess of the programmed value.
Description: Sets the maximum allowable period of RS485
serial inactivity.
Adjustment: Set as required.
42.
Default Setting: 0 seconds (Off)
NOTE:
A setting of 0 seconds disables the RS485 –
Timeout Protection and enables the TMS7 to
CAUTION continuing operating even if the RS485 link
becomes inactive.
Motor Temperature Alarm
Range: 0 – 105% Motor Temperature
Default Setting: 80%
Description: Sets the temperature (%) at which the motor
overtemperature alarm operates.
TMS7 SERIES
RS485 Timeout
ME00070B
21
PROGRAMMING
61.
Description: Sets maximum number of reset attempts for the
Auto-reset function.
Adjustment: The Auto-reset counter increases by one after
each trip, up to the maximum number of resets set in Function
71. Auto-Reset – Number Of Resets. The fault is then latched
and a manual reset is required.
The Auto-reset counter decreases by one, to a minimum of zero,
after each successful start/stop cycle.
Refer Function 70 Auto-Reset – Configuration for further detail.
RS485 Baud Rate
Range: 1 – 5
1 = 1200 baud
2 = 2400 baud
3 = 4800 baud
4 = 9600 baud
5 = 19200 baud
Default Setting: 4 (9600 baud)
Description: Sets the baud rate for RS485 serial activity.
72.
Adjustment: Set as required.
Auto-Reset – Group A & B Delay
Range: 5 – 999 seconds
62.
RS485 Satellite Address
Default Setting: 5 seconds
Range: 1 - 99
Description: Sets the delay for resetting of Group A & B trips.
Default Setting: 20
Adjustment: Refer Function 70 Auto-Reset – Configuration for
further detail.
Description: Assigns the TMS7 an address for RS485 serial
communication.
Adjustment: Set as required.
70.
73.
Range: 5 – 60 minutes
Auto-Reset - Configuration
Default Setting: 5 minutes
Description: Sets the delay for resetting of Group C trips.
Adjustment: Refer Function 70 Auto-Reset – Configuration for
further detail.
Range: 0 – 3
0 = Off
1 = Reset Group A trips
2 = Reset Group A & B trips
3 = Reset Group A, B & C trips
Default Setting: 0 (Off)
Description: Determines which trips will be automatically reset.
TMS7 soft starters can be programmed with two separate
sets of motor data. The primary motor settings are adjusted
using Functions 1 ~ 9. The secondary motor settings are
adjusted using Functions 80 ~ 88.
When commanded to start the TMS7 checks the state of the
FLC Select input (Terminals I43 & I44). In the event of an
open circuit the primary motor settings are used. In the
event of a closed circuit the secondary motor settings are
used.
Adjustment: A setting of other than 0 causes the TMS7 to
automatically reset, and after a delay if the start signal is still
present, attempt to start the motor. The Auto-reset function can
be programmed to reset faults according to the table below:
Trip Group
A
B
C
Auto-Reset – Group C Delay
Trip Conditions
Phase imbalance, Phase loss
Undercurrent, Electronic shearpin
Overcurrent, Motor thermistor, Starter
overtemperature
80.
Motor Full Load Current
Range: Model Dependant (Amps)
Default Setting: Model Dependant (Amps)
Operation of the Auto-reset function is controlled according to
the following function settings:
Description: Sets the TMS7 for the connected motor’s full load
current.
Adjustment: Refer to Function 1 for further detail.
Function 70. Auto-reset – Configuration
Function 71. Auto-reset – Number of resets
Function 72. Auto-reset – Group A & B Delay
Function 73. Auto-reset – Group C Delay
81.
Range: 100 – 550 % FLC
Default Setting: 350% FLC
Description: Sets the current limit for the Constant Current start
mode.
CAUTION:
Operation of the auto-reset function will reset a
trip state and if the start signal is still present,
CAUTION allow the motor to restart. Ensure that personal
safety is not endangered by such operation and
that all relevant safety measures and/or
regulations are complied with before utilising this
function.
71.
Adjustment: Refer to Function 2 for further detail.
82.
Minimum Current
Range: 100 – 550 % FLC
Default Setting: 350% FLC
Description: Sets the minimum current level for the Ramp Start
mode.
Adjustment: Refer to Function 3 for further detail.
Auto-Reset – Number Of Resets
Range: 1 - 5
Default Setting: 1
22
Current Limit
ME00070B
TMS7 SERIES
PROGRAMMING
83.
Default Setting: 3 Seconds
Start Ramp Time
Description: Sets the delay period between detection of a
phase imbalance greater than allowed by the setting made in
Function 7 & 86. Current Imbalance Sensitivity and a trip
condition.
Adjustment: Set as required.
Range: 1 – 30 Seconds
Default Setting: 1 Second
Description: Sets the ramp time for the Current Ramp start
mode.
Adjustment: Refer to Function 4 for further detail.
84.
100.
Stop Ramp Time
Range: 1 - 22
Default Setting: Model Dependant
Range: 0 – 100 Seconds
Default Setting: 0 Second (Off)
Description: A diagnostic parameter used to identify the power
assembly type.
Description: Sets the soft stop ramp time for soft stopping of
the motor.
Adjustment: Refer to Function 5 for further detail.
85.
101.
Default Setting: n/a
Description: Displays the TMS7 Fault History.
Adjustment: Use the <UP> and <DOWN> keys to scroll
through the trip log.
Refer to Section 9, Trouble Shooting Procedure for a description
of the trip log and fault conditions.
Default Setting: 10 Seconds
NOTE:
A setting of 0 seconds disables the TMS7 motor
thermal model. Use this setting only if another form
of motor protection is used.
CAUTION
Description: Sets the motor thermal capacity used by the TMS7
motor thermal model.
Adjustment: Refer to Function 6 for further detail.
110.
Default Setting: 0
Description: Entering the correct password does two things
1. Temporarily changes the function lock to Read/Write
irrespective of the state specified by Function 112 Function
Lock. This allows function settings to be adjusted during the
current programming session. On exit of the current
programming session function settings are again protected
according to Function 112. Function Lock.
2. Provides access to parameters 111 - 113.
Adjustment: Enter password. The default password is 0.
Contact your supplier if the password is lost or forgotten
Current Imbalance Sensitivity
Default Setting: 5
Description: Sets the sensitivity of the current imbalance
protection.
111.
Default Setting: 0
Description: Changes the current password.
Adjustment: Set as required, remembering to make note of the
new password.
Undercurrent Protection
Range: 15% – 100% FLC
Default Setting: 20% FLC
112.
Description: Sets the trip point for the TMS7 undercurrent
protection as a percentage of motor full load current.
Adjustment: Refer to Function 8 for further detail.
Stall Protection
Default Setting: 400% FLC
Description: Sets the trip point for the TMS7 stall protection as
a percentage of motor full load current.
Adjustment: Refer to Function 9 for further detail.
113.
Current Imbalance Trip Delay
Restore Function Settings
Range: 0, 50
Range: 3 – 254 Seconds
TMS7 SERIES
Function Lock
Range: 0 – 1
0 = Read/Write
1 = Read Only
Default Setting: 0 (Read / Write)
Description: Allows protection of all function settings. Note that
when this function has been changed from 0 (Read/Write) to 1
(Read Only) the new setting takes effect only when program
mode is exited.
Adjustment: Set as required.
Range: 80% – 550% FLC
90.
Update Password
Range: 0 - 999
Adjustment: Refer to Function 7 for further detail.
88.
Password
Range: 0 - 999
Range: 1 – 10
1 = Highest sensitivity (lowest imbalance)
I
5 = Average sensitivity
I
10 = Lowest sensitivity (highest imbalance)
87.
Fault History
Range: n/a
Motor Trip Class
Range: 0 – 60 Seconds
86.
Model Number
ME00070B
23
PROGRAMMING
Default Setting: 0
Description: Allows function adjustments be returned to the
factory defaults.
Adjustment: Set to 50 to load default parameter settings.
7.4 Operation
Once installed, wired and programmed according to the
instructions earlier in this manual the TMS7 can be operated.
Local control panel.
1.
2.
3.
Numeric LED Display: The information being displayed is
indicated by the LEDs to the right of the display. During
operation either motor current (Amps) or the calculated
motor temperature (%) can be displayed. Use the <UP> or
<DOWN> keys select what information is displayed. In the
event of a trip state the relevant trip code will be shown.
If motor current exceeds the maximum current able to be
shown on the numeric display, the display will show
dashes.
Starter Status LEDs:
Start: Voltage is being applied to the motor terminals.
Run: Full voltage is being applied to the motor terminals.
Trip: The TMS7 has tripped.
Remote: The TMS7 is in remote control mode.
Operational Push Buttons: These push buttons can be
used to control TMS7 operation when in local control
mode. The <LOCAL/REMOTE> push button can be used
to switch between local and remote control.
NOTE:
When control power is applied to the TMS7 it may
be in either local or remote control mode according
to the mode it was in when control power was
CAUTION removed. The factory default is local control.
24
ME00070B
TMS7 SERIES
PROGRAMMING
NOTE:
Function 20. Local/Remote Operation can be used
to limit operation to either local or remote mode
operation. If the <LOCAL/REMOTE> push button is
CAUTION used in an attempt to switch to a prohibited mode
the numeric display will show 'OFF'.
NOTE:
Simultaneously pressing the <STOP> and
<RESET> push buttons causes the TMS7 to
immediately remove voltage from the motor,
CAUTION resulting in a coast to stop. Any soft settings are
ignored.
circuit the primary motor settings are used. In the event of a
closed circuit the secondary motor settings are used.
Primary Motor Settings
Function Settings 1 ~ 9
I44
Primary Motor Settings
Function Settings 80 ~ 88
I44
I43
I43
FLC Select
FLC Select
4. Programming Buttons: Refer to section 7.1.
5. Remote Control Inputs Status: These LEDs indicate the
state of the circuits across the TMS7 remote control inputs.
NOTE:
All LEDs and the Numeric display are illuminated
for approx imately 1 second to test their operation
CAUTION when control power is first applied .
Remote control.
TMS7 operation can be controlled via the remote control inputs
when the soft starter is in remote mode. Use the
<LOCAL/REMOTE> push button to switch between local and
remote modes. Refer to section 6.3 Control Wiring for further
detail.
Restart delay.
Function 31. Restart Delay sets the delay period between the
end of a stop and the beginning of the next start. During the
restart delay period the LEDs to the right of the numeric display
will flash indicating that a restart cannot yet be attempted.
Pre-start tests.
Before applying voltage to the motor when a start is initiated, the
TMS7 first performs a series of tests to check the motor
connection and supply conditions.
Secondary motor settings.
TMS7 starters can be programmed with two motor parameter
sets. The primary motor parameters are set using functions 1~9.
The secondary motor parameters are set using functions 80~88.
When commanded to start the TMS7 checks the state of the
FLC Select input (Terminals I43 & I44). In the event of an open
TMS7 SERIES
ME00070B
25
APPLICATION EXAMPLES
Application Examples
8.1 Installation With Line Contactor
K1M
F1
8.2 Installation With Bypass Contactor
K1M
L1
T1
L1B
L2
3 PHASE
SUPPLY
T2
TO MOTOR
L2B
F1
L3
460V
OR
575V
+10
-15
+10
-15
C24 mo dels
400V
OR
230V
+10
-15
+10
-15
E
A1
A2
A3
C3
G ND
L3
C4
TO MO TOR
T3
L3B
C5
E
C4 5 mod els
CO NT ROL
SUPPLY
R43
R34
T2
L2B
R44
I34
L2
3 PHASE
SUPPLY
I44
I43
T1
L1B
L3B
C45 mode ls
L1
T3
460V
OR
575V
K1M
C 24 mo dels
+10
-15
400V
+10
-15
230V
OR
A1
+10
-15
A2
+10
-15
A3
C3
GND
C4
C5
R33
I33
S1
I22
R24
I44
R23
I43
I21
S2
I12
I11
R34
R14
S3
R12
C1
C6
C2
C7
I34
R24
S2
I2 2
I21
S1
I12
I11
Legend
K1M
S1
S2
F1
Line Contactor
Start Contact
Reset Pushbutton
Semiconductor Fuses (optional)
MOT OR
THERMIST OR
Description:
The TMS7 is applied with a line contactor (AC3 rated). The line
contactor is controlled by the TMS7 Main Contactor output,
which by default is assigned to RELAY OUTPUT A (terminals
R44, R43).
The control supply must be sourced from before the contactor.
K1M
R23
R14
R12
R11
C1
C6
C2
C7
L egend
K1M Bypass Co ntactor
S1
Reset Pushbutton
S2
Stop Pushbutton
S3
Start Pushbutton
F1
Semi conductor Fuses (optional)
Description:
The TMS7 is applied with a bypass contactor (AC1 rated). The
bypass contactor is controlled by the TMS7 RUN OUTPUT
(terminals R34, R33).
Function Settings:
Function 21. Relay Output A Functionality = 11
(Assigns the Main Contactor function to Relay Output A)
26
CONT ROL
SUPPLY
R33
I33
R11
MOTOR
THERMISTOR
R44
R43
Function Settings:
- no special settings required.
ME00070B
TMS7 SERIES
APPLICATION EXAMPLES
8.3 Soft Braking
3 PHASE
SUPPLY
CO NTR OL
SUPPLY
THERMISTO R
IN PUT
A1 A2 A3
CONTROL
SUPPLY
C1 C2
THERMISTO R
IN PUT
F1
L1
L2
L3
FLC SELECT START
T1
T2
T3
E
I44
K3 A
K2M
I 43
I34
I33
STO P
I2 2
K2A
R11
RELAY
OUTPUT C
RESET
I 21
I12
I11
R12
S3
K1 A
K3A
S2
K2T
K1T
S1
K4 A
CON TRO L
SUPPLY
A2
K1 M
K1 A K1M
K2M K1A
K1 M
Y1
Y2
CO NTACTORS TO BE
MECHANICAL LY
INTERL OCKED
K1 M
K2M
K1A
K2A
K3A
K1T K2M
Y1
K2 T
Y2
K4 A
M1
LEG EN D
A2
F1
K1 A
K2 A
K3 A
K4 A
SHAFT RO TATION SEN SO R
SEMI -CO NDUCTOR FUSES ( OPTION AL)
RUN RELAY
START RELAY
BRAKE RELAY
ROTATIO N SENSING REL AY
K1M
K2M
K1T
K2T
S1
S2
S3
LINE CONTACTO R ( RUN)
LINE CONTACTO R ( BR AKE)
RUN DEL AY TIMER
BR AKE DELAY TI MER
START PUSHBUTTO N
STOP PU SHBUTTON
RESET PUSHBU TTON
Description:
For high inertia loads that require more braking torque than is available from the D.C.Brake feature, the TMS7 can be configured for 'Soft
Braking'.
In this application the TMS7 is employed with forward run and braking contactors. On receipt of a start signal (pushbutton S1) the TMS7
closes the forward run contactor (K1M) and controls the motor according to the programmed Primary Motor Settings.
On receipt of a stop signal (pushbutton S2) the TMS7 opens the forward run contactor (K1M) and closes the braking contactor (K2M) after a
delay of approximately 2-3 seconds (K1T). K3A is also closed to activate the Secondary Motor Settings which should be user programmed
for the desired stopping performance characteristics.
When motor speed approaches zero the shaft rotation sensor (A2) stops the soft starter and opens the braking contactor (K2M).
Function Settings:
- Function 23. Relay Output C Functionality = 0 (Assigns the Trip function to Relay Output C)
- Functions 1~9 (Sets starting performance characteristics)
- Functions 80~88 (Sets braking performance characteristics)
TMS7 SERIES
ME00070B
27
APPLICATION EXAMPLES
8.4 Two Speed Motors
K3M
SEE NOT E1.
T4
T5
T6
K2M
L1
L1B
L2
L2B
L3
L3B
3 PHASE
SUPPLY
T1
T1
TO DUAL SPEED MOTOR
DAHLANDER T YPE
T2
T2
T3
T3
K1M
E
A1
CONTROL
SUPPLY
K1A
A2
SUPPLY
A3
I44
C1
I43 FLC SELECT THERM.
C2
MOT OR
THERM ISTOR
I34
K1M
K2M
I33 START
I22
I21 STO P
S1
I12
K3M
K1M
I11 RESET
R11
OUT PUT C
K2A
K2M
K1A
K3M
K3M
R14
R12
K1M
K2M
CONTROL SUPPLY
K2A
REM OTE LOW SPEED
START INPUT
LEGEND
K1A
K1A
REMOTE HIGH SPEED
START INPUT
K2A
K1A
K2A
K1M
K2M
K3M
S1
REM OTE START RELAY (LOW SPEED)
REMO TE START RELAY (HIGH SPEED)
LINE CONTACTOR (HIGH SPEED)
LINE CONTACT OR (LO W SPEED)
STAR CONTACT OR (HIGH SPEED)
RESET PUSHBUTT ON
1. NOTES
CONTACTORS K2M AND K3M MUST BE
MECHANICALLY INTERLOCKED.
Description:
The TMS7 can be configured for control of dual speed Dahlander type motors. In this application the TMS7 is employed with a High Speed
contactor (K1M), Low Speed contactor (K2M) and a Star contactor (K3M).
On receipt of a High Speed start signal the High Speed contactor (K1M) and Star contactor (K3M) are closed. The TMS7 then controls the
motor according to the Primary Motor Parameter set. (Function Numbers 1~9)
On receipt of a Low Speed start signal the Low Speed contactor (K2M) is closed. The relay contact across Input A is also closed causing
the TMS7 to control the motor according to the Secondary Parameter set (Function Numbers 80~88).
Function Settings:
- Function 23. Relay Output C Functionality = 0 (Assigns the Trip function to Relay Output C)
28
ME00070B
TMS7 SERIES
TROUBLE SHOOTING
Section 9
Code
Trouble Shooting
9.1 Trip Codes
When the TMS7 enters the trip state the cause of the trip is
indicated on the LED display panel.
Code
Description
0
Shorted SCR
The TMS7 has detected a shorted SCR(s).
1. Determine the affected phase using the 3 phase
indicators LEDs located on the left hand side of
the TMS7 cover. Damaged SCRs are indicated by
an extinguished phase indicator LED (all phase
indicator LEDs should be illuminated when input
voltage is present but the motor is not running).
SCR damage can be verified using the Power
Circuit Test described in the Test & Measurement
chapter of this section.
2. Replace the damaged SCR.
Overcurrent trip
The motor has been overloaded and the motor’s
thermal limit, as calculated by the TMS7 motor thermal
model, has been reached.
1. Remove the cause of the overload and let the
motor cool before restarting.
3
Motor thermistor trip
The motor thermistors have indicated an
overtemperature situation.
1. Identify and correct the cause of the motor
overheating.
2. If no thermistors are connected to the TMS7,
ensure there is a closed circuit across the motor
thermistor input (terminals C1 & C2).
4
5
Current imbalance trip
An imbalance in the phase currents has exceeded the
limits set in Function 7. Current Imbalance Sensitivity.
1. Monitor the supply voltage
2. Check the motor circuit
Supply frequency trip
Supply frequency has varied outside the TMS7’s
specified range.
1. Correct the cause of the frequency variations.
2. Check the three phase supply to the TMS7. Loss
of all three phases is seen by the TMS7 as a 0Hz
situation and may be the cause of a supply
frequency trip.
3. Check the three phase supply to the TMS7 is
connected to input terminals L1, L2, L3. Incorrect
connection of the incoming supply to the output
terminals T1, T2, T3 means there is no supply
connected to the TMS7 input. This will be seen as
TMS7 SERIES
6
Phase rotation trip
The TMS7 has detected a phase rotation that has
been prohibited by the setting made in Function 30.
Phase Rotation Protection.
1. Change the incoming phase rotation.
7
Stall trip
The TMS7 has measured a current equal to the limit
set in Function 9. Stall Protection.
1. Identify and correct the cause of the
instantaneous overload event.
8
Power circuit fault
The TMS7 has detected a fault in the power circuit.
1. Ensure that the motor is correctly connected to
the TMS7 and verify the circuit.
2. Check that voltage is correctly applied to all three
TMS7 input terminals (L1, L2 & L3).
3. Reset the trip condition by removing and
reapplying control voltage to the TMS7.
2
Description
connected to the TMS7 input. This will be seen as
a 0Hz situation and may the cause of a supply
frequency trip.
9
Undercurrent trip
The TMS7 has measured a run current lower than the
limit set in Function 8. Undercurrent Protection.
1. Identify and correct the cause of the undercurrent
event.
F
Heatsink overtemperature trip
The TMS7 heatsink temperature sensor has indicated
and excess heatsink temperature.
1. Verify that the TMS7 has sufficient ventilation.
2. Verify that cooling air is able to freely circulate
through the TMS7.
3. Verify that the TMS7 cooling fans (if fitted) are
working.
P
Invalid motor connection
The TMS7 cannot detect a valid motor circuit.
1. Ensure the motor is connected to the TMS7 in a
valid configuration. Refer to Section 5 Power
Circuits for further detail.
C
RS485 communication fault
The RS485 link connected to the TMS7 has been
inactive for a period of time greater than set in
Function 60. RS485 – Timeout Protection.
1. Restore the RS485 link.
E
EEPROM read/write failure
The TMS7 has failed to read or write to the internal
EEPROM.
Reset the TMS7. If the problem persists contact your
supplier.
Out of range FLC
The TMS7 has detected that the motor is connected in
the 3 Wire configuration and that Function 1. Motor
FLC or Function 80 Motor FLC (secondary motor
settings) has been set in excess of the TMS7’s
maximum capability for this connection format.
1. Reduce the motor FLC setting and then reset the
TMS7. Note that the TMS7 cannot be reset until
the FLC setting has been corrected.
2. Alternatively, remove control voltage from the
TMS7 and reconnect the motor in 6 Wire.
ME00070B
29
TROUBLE SHOOTING
Code
9.3 General Faults
Description
TMS7 and reconnect the motor in 6 Wire.
Symptom
Incorrect main control module.
The TMS7 is fitted with an incompatible main control
module.
1. Fit a suitable main control module.
u
Uncontrolled start. Power factor correction capacitors
connected to the TMS7 output. Remove
any power factor correction from the output
of the soft starter. Connection of power
factor correction capacitors to the output of
a soft starter can result in damage to the
SCRs so they should be checked by using
the SCR test described in section 9.4 Tests
and Measurements.
CPU error
Reset the TMS7. If the problem persists contact your
supplier.
9.2 Fault History
Damaged SCRS. Verify soft starter
operation using the SCR test described in
section 9.4 Tests and Measurements.
The TMS7 includes a Fault History Log that records the last
eight trip events. Each trip is numbered. Trip number 1 is the
most recent trip with trip number 4 being the oldest.
1-4
Trip Code
Trip Number
Cause
Damaged firing circuit. Verify the TMS7
SCR firing circuit using the Power Circuit
Test described in section 9.4 Tests and
Measurements.
1 = Most recent trip
2 = Previous trip
TMS7 will not
operate.
.
.
.
4 = Oldest trip
Local push buttons not active. The TMS7
may be in remote control mode. (Refer to
Function 20. Local/Remote Operation)
Remote control inputs not active. The
TMS7 may be in local control mode. (Refer
to Function 20. Local/Remote Operation)
The Fault History can be viewed by selecting Function 101.
Fault History and using the <UP> and <DOWN> keys to scroll
through the Fault History.
Faulty start signal. Verify any circuits
connected to the TMS7 remote control
inputs. The state of the remote circuits is
indicated by the TMS7 remote control input
LEDs. The LEDs are illuminated when there
is a closed circuit. For there to be a
successful start there must be a closed
circuit across the start, stop and reset
circuits.
NOTE:
The TMS7 records trips in the Fault History log
immediately after they are detected, this requires
CAUTION control voltage to be present after the trip. Trips
caused by or involving a loss of control voltage
may not be recorded.
A ‘marker’ can be inserted into the Fault History log to identify
trips that have occurred after placement of the ‘marker’. To
insert a ‘marker’ enter the programming mode and move to
Function 101. Fault History. Then simultaneously depress the
<UP> and <DOWN> and <STORE> keys. The marker is added
as the most recent fault and is displayed as three horizontal
lines as shown below.
No, or incorrect control voltage. Ensure
the correct control voltage is applied to the
inputs A1, A2, A3.
Restart delay active. The TMS7 cannot be
started during the restart delay period. The
period of the restart delay is set using
Function 31. Restart Delay.
Auto-reset function active. If there has
been a trip and the auto-reset function is
active the fault must be manually reset
before a manual restart can be attempted.
(Refer to Functions 70, 71, 72 & 73 )
NOTE:
Trip makers must be separated by at least one trip
and cannot be placed consecutively.
TMS7 in programming mode. The TMS7
will not run while in programming mode.
CAUTION
The motor will not
accelerate to full
speed.
Start current too low. Check the load is
not jammed. Increase start current using
Function 2. Current Limit.
Function setting
Incorrect programming procedure.
cannot be made or Function settings must be stored using the
are not recorded. <STORE> button. Refer to section 7.1
Programming Procedure for further detail.
Function settings are locked. Ensure that
Function 112. Function Lock is set for
Read/Write.
30
ME00070B
TMS7 SERIES
TROUBLE SHOOTING
Symptom
Erratic motor
operation and
tripping.
Test
Cause
SCRs not latching. SCRs require a
minimum current flow to ‘latch’ on. In
situations where very small motors are
being controlled by large soft starters the
current drawn may be insufficient to latch on
the SCRs. Increase motor size or reduce
soft start size.
Soft stop ends
before the
programmed ramp
time.
Motor will not stall. The TMS7 has
significantly reduced the voltage applied to
the motor without detecting a reduction in
motor speed. This indicates that with
present motor loading further control of the
voltage will be ineffectual, hence the soft
stop function has halted.
TMS7 display
shows a ‘h’
The START button on the local control
panel is stuck. Release the button to
restore normal operation.
TMS7 will not enter The TMS7 is running. The TMS7 must be
the programming stopped before programming mode can be
mode.
accessed.
No, or incorrect control voltage. Ensure
the correct control voltage is applied to the
inputs A1, A2, A3.
Procedure
2.
Remove the motor cables from the
output terminals of the TMS7 (T1, T2
& T3).
3.
Use a 500 VDC insulation tester to
measure the resistance between the
input and output of each phase of the
TMS7 (L1-T1, L2-T2, L3-T3). Note that
low voltage ohm meters or multimeters are not adequate for this
measurement.
4.
The measured resistance should be
close to 33kΩ and approximately
equal on all three phases.
5.
If a resistance of less than about
10kΩ is measured across the SCR,
the SCR should be replaced.
6.
If a resistance greater than about
60kΩ is measured across the SCR
there could be a fault with the TMS7
control module or firing loom.
9.4 Tests & Measurements
Test
Run performance
test.
Procedure
This test verifies correct operation of the
TMS7 during run.
1.
Control input test
Measure the voltage drop across each
phase of the TMS7 (L1–T1, L2–T2,
L3–T3). The voltage drop will be less
than approximately 2 VAC when the
TMS7 is operating correctly.
This test verifies circuits connected to the
TMS7 remote control inputs. (Start, Stop,
Reset & FLC Select)
1.
Measure the voltage across each
input. With the remote circuit closed
there should be 0VDC measured. If
24VDC is measured the switch/control
is incorrectly connected or faulty.
Start performance This test verifies correct operation of the
test.
TMS7 during start.
Power circuit test.
1.
Determine the expected start current
by multiplying the settings made in
Function 1. Motor Full Load Current
and Function 2. Current Limit.
2.
Start the motor and measure the
actual start current.
3.
If the expected start current and the
actual start current are the same, the
TMS7 is performing correctly.
This test verifies the TMS7 power circuit
including the SCR, firing loom and control
module.
1.
TMS7 SERIES
Remove the incoming supply from the
TMS7 (L1, L2, L3 and control supply).
ME00070B
31
APPENDIX
Appendix
10.1
The above table is intended as a guide only. Individual machine
and motor characteristics will determine the actual start current
requirements.
Typical Start Current Requirements
10.2
Compressor - Screw (loaded)
—
Compressor - Screw (unloaded)
—
Conveyor - Belt
—
Conveyor - Roller
—
Conveyor - Screw
—
Crusher - Cone
—
Crusher - Jaw
—
—
—
Crusher - Rotary
Crusher - Vertical Impact
Debarker
—
Dryer
—
—
—
Dust Collector
Edger
Fan - Axial (Damped)
10.3
—
Fan - Axial (Un-damped)
—
Fan - Centrifugal (Damped)
Fan - High Pressure
90 A: AC-53b 3.5-15 : 345
—
—
Grinder
Hydraulic Power Pack
Off Time (seconds)
Start Time (seconds)
Start Current (multiple of FLC)
Starter Current Rating (Amps)
—
—
—
—
—
—
Mill
Mill - Ball
Mill - Hammer
Mill - Roller
Mixer
Palletiser
Starter Current Rating: The Full Load Current rating of soft
starter given the parameters detailed in the remaining sections
of the utilisation code.
Start Current: The maximum available start current given the
parameters detailed in the remaining sections of the utilisation
code.
Start Time: The maximum available start time given the
parameters detailed in the remaining sections of the utilisation
code.
Off Time: The minimum allowable time between end of one start
and the beginning of the next start given the parameters detailed
in the remaining sections of the utilisation code.
—
—
Planer
Press
—
—
Pump - Centrifugal
Pump - Positive Displacement
—
—
—
Pump - Slurry
Re-pulper
AC53b Utilisation Codes
AC53b Utilisation Category Format
—
—
Fan - Centrifugal (Un-damped)
—
—
Rotary Table
Sander
—
Saw - Bandsaw
—
Saw - Circular
—
—
Separator
Shredder
32
Starter Current Rating: The Full Load Current rating of soft
starter given the parameters detailed in the remaining sections
of the utilisation code.
Start Current: The maximum available start current given the
parameters detailed in the remaining sections of the utilisation
code.
Start Time: The maximum available start time given the
parameters detailed in the remaining sections of the utilisation
code.
On-load Duty Cycle: The maximum permissible percentage of
each operating cycle that the soft starter can operate given the
parameters detailed in the remaining sections of the utilisation
code.
Starts Per Hour: The maximum available number of starts per
hour given the parameters detailed in the remaining sections of
the utilisation code.
—
—
Compressor - Recip (unloaded)
Slicer
Starts Per Hour
On-load Duty Cycle (% )
Start Time (seconds)
Start Current (multiple of FLC)
Starter Current Rating (Amps)
—
—
—
Chipper
Compressor - Recip (loaded)
Tumbler
78 A: AC-53a 3.5-15 : 50-10
—
Centrifuge
Pump - Bore
450%
400%
350%
300%
Atomiser
Bottle Washer
AC53a Utilisation Category Format
—
—
Agitator
AC53a Utilisation Codes
—
—
ME00070B
TMS7 SERIES

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