programming manual - weg manual 10/2015 summary quick reference for parameters, faults and...

Software Version: 2.0XDocument: 10001773425 / 02Language: English

PROGRAMMING MANUAL

Series: CFW-11 RB

Language: English

Software Version: 2.0X

Document: 10001773425 / 02

PROGRAMMING

MANUAL

10/2015

Summary

QUICK REFERENCE FOR PARAMETERS, FAULTS AND ALARMS ........... 0-1

1 SAFETY INSTRUCTIONS .................................................................. 1-11.1 SAFETY WARNINGS IN THIS MANUAL ........................................................1-11.2 SAFETY WARNINGS ON THE PRODUCT ......................................................1-11.3 PRELIMINARY RECOMMENDATIONS ...........................................................1-2

2 GENERAL INFORMATION ............................................................... 2-12.1 ABOUT THE MANUAL .................................................................................2-12.2 TERMINOLOGY AND DEFINITIONS .............................................................2-1

2.2.1 Terms and Definitions Used in the Manual .........................................2-12.2.2 Numerical Representation ..................................................................2-32.2.3 Symbols to Describe Parameter Properties ........................................2-3

3 ABOUT THE CFW-11 RB .................................................................. 3-13.1 ABOUT THE CFW-11 RB ..............................................................................3-1

4 HMI ................................................................................................ 4-14.1 HMI .............................................................................................................4-1

5 PROGRAMMING BASIC INSTRUCTIONS ......................................... 5-15.1 PARAMETER STRUCTURE .............................................................................5-15.2 GROUPS ACCESSED IN THE OPTION MENU IN THE MONITORING MODE .5-15.3 ADJUSTMENT OF THE PASSWORD IN P0000 ..............................................5-25.4 HMI [22] .....................................................................................................5-35.5 DATE AND TIME SETTING ...........................................................................5-65.6 SETTING OF DISPLAY INDICATIONS IN THE MONITORING MODE .............5-7

6 IDENTIFICATION OF THE REGENERATIVE CONVERTER MODEL AND ACCESSORIES .................................................................................... 6-1

6.1 DATA OF THE REGENERATIVE CONVERTER [27] .........................................6-1

7 SETTINGS ....................................................................................... 7-17.1 BACKUP PARAMETERS [04] ..........................................................................7-1

8 USED CONTROL ............................................................................. 8-18.1 USED CONTROL .........................................................................................8-18.2 VECTOR CONTROL .....................................................................................8-18.3 DC LINK REGULATOR [93] ..........................................................................8-18.4 CURRENT REGULATOR [90] .........................................................................8-38.5 REACTIVE REGULATOR [91] ........................................................................8-48.6 CURRENT LIMITS [92] ..................................................................................8-68.7 START-UP ..................................................................................................8-8

Summary

9 DIGITAL AND ANALOG INPUTS AND OUTPUTS ............................ 9-19.1 I/O CONFIGURATION [05] .........................................................................9-1

9.1.1 Analog Outputs [24] ...........................................................................9-19.1.2 Digital Inputs [25] ..............................................................................9-59.1.3 Digital / Relay Outputs [26] ................................................................9-7

10 FAULT AND ALARMS .................................................................. 10-110.1 PROTECTIONS [28] .................................................................................10-1

11 READING PARAMETERS [07] ....................................................... 11-111.1 FAULT HISTORY [06] ...............................................................................11-5

Quick Reference for Parameters, Faults and Alarms

CFW-11 RB | 0-1

0Param. Description Adjustable Range Factory Setting

User’s Setting

Prop. Groups Page

P0000 Access to Parameters 0 to 9999 0 - - - 5-2P0002 Line Voltage 0 to 2000 V - - ro 07 11-1P0003 Input Current 0.0 to 4500.0 A - - ro 07 11-1P0004 DC Link Voltage (Ud) 0 to 2000 V - - ro 07, 20 11-1P0006 Converter Status 0 = Ready

1 = Run 2 = Undervoltage3 = Fault4 = Configuration

- - ro 07 11-2

P0007 Input Voltage 0 to 2000 V - - ro 07 11-2P0010 Input Power 0.0 to 6553.5 kVA - - ro 07 11-2P0012 DI8 to DI1 Status Bit 0 = DI1

Bit 1 = DI2Bit 2 = DI3Bit 3 = DI4Bit 4 = DI5Bit 5 = DI6Bit 6 = DI7Bit 7 = DI8

- - ro 07, 25 9-5

P0013 DO5 to DO1 Status Bit 0 = DO1Bit 1 = DO2Bit 2 = DO3Bit 3 = DO4Bit 4 = DO5

- - ro 07, 26 9-7

P0014 AO1 Value 0.00 to 100.00 % - - ro 07, 24 9-1P0015 AO2 Value 0.00 to 100.00 % - - ro 07, 24 9-1P0016 AO3 Value -100.00 to 100.00 % - - ro 07, 24 9-1P0017 AO4 Value -100.00 to 100.00 % - - ro 07, 24 9-1P0023 Software Version 0.00 to 655.35 - - ro 07, 27 6-1P0027 Accessory Configuration 1 0000h to FFFFh - - ro 07, 27 6-2P0028 Accessory Configuration 2 0000h to FFFFh - - ro 07, 27 6-2P0029 Power Hardware Configuration Bit 0 to 5 = Rated Current

Bit 6 and 7 = Rated VoltageBit 8 and 9 = ReservedBit 10 = (0)24V/(1) DC Link Bit 11 = (0)RST/(1) DC Link Bit 12 = ReservedBit 13 = SpecialBit 14 and 15 = Reserved

- - ro 07, 27 6-3

P0030 IGBTs Temperature U -20.0 to 150.0 °C - - ro 07, 28 10-1P0031 IGBTs Temperature V -20.0 to 150.0 °C - - ro 07, 28 10-1P0032 IGBTs Temperature W -20.0 to 150.0 °C - - ro 07, 28 10-1P0034 Internal Air Temperature -20.0 to 150.0 °C - - ro 07, 28 10-1P0035 Air Temperature Control -20.0 to 150.0 °C - - ro 07, 28 10-1P0036 Fan Speed 0 to 15000 rpm - - ro 07 11-4P0042 Time Powered 0 to 65535 h - - ro 07 11-4P0043 Time Enabled 0.0 to 6553.5 h - - ro 07 11-4P0044 kVAh Counter 0 to 65535 kVAh - - ro 07 11-4P0045 Fan Enabled Time 0 to 65535 h - - ro 07 11-5P0048 Current Alarm 0 to 999 - - ro 07 11-5P0049 Current Fault 0 to 999 - - ro 07 11-5P0050 Last Fault 0 to 999 - - ro 06 11-6P0051 Last Fault Day/Month 00/00 to 31/12 - - ro 06 11-7P0052 Last Fault Year 00 to 99 - - ro 06 11-8P0053 Last Fault Time 00:00 to 23:59 - - ro 06 11-8P0054 Second Fault 0 to 999 - - ro 06 11-6P0055 Day/Month Second Fault 00/00 to 31/12 - - ro 06 11-7P0056 Second Fault Year 00 to 99 - - ro 06 11-8P0057 Second Fault Time 00:00 to 23:59 - - ro 06 11-8P0058 Third Fault 0 to 999 - - ro 06 11-6P0059 Third Fault Day/Month 00/00 to 31/12 - ro 06 11-7P0060 Third Fault Year 00 to 99 - - ro 06 11-8

QUICK REFERENCE FOR PARAMETERS, FAULTS AND ALARMS


0-2 | CFW-11 RB

0 Param. Description Adjustable Range Factory SettingUser’s Setting

Prop. Groups Page

P0061 Third Fault Time 00:00 to 23:59 - - ro 06 11-8P0062 Fourth Fault 0 to 999 - - ro 06 11-6P0063 Fourth Fault Day/Month 00/00 to 31/12 - - ro 06 11-7P0064 Fourth Fault Year 00 to 99 - - ro 06 11-8P0065 Fourth Fault Time 00:00 to 23:59 - - ro 06 11-8P0066 Fifth Fault 0 to 999 - - ro 06 11-6P0067 Fifth Fault Day/Month 00/00 to 31/12 - - ro 06 11-7P0068 Fifth Fault Year 00 to 99 - - ro 06 11-8P0069 Fifth Fault Time 00:00 to 23:59 - - ro 06 11-8P0070 Sixth Fault 0 to 999 - - ro 06 11-6P0071 Sixth Fault Day/Month 00/00 to 31/12 - - ro 06 11-7P0072 Sixth Fault Year 00 to 99 - - ro 06 11-8P0073 Sixth Fault Time 00:00 to 23:59 - - ro 06 11-8P0074 Seventh Fault 0 to 999 - - ro 06 11-6P0075 Seventh Fault Day/Month 00/00 to 31/12 - - ro 06 11-7P0076 Seventh Fault Year 00 to 99 - - ro 06 11-8P0077 Seventh Fault Time 00:00 to 23:59 - - ro 06 11-8P0078 Eighth Fault 0 to 999 - - ro 06 11-6P0079 Eighth Fault Day/Month 00/00 to 31/12 - - ro 06 11-7P0080 Eighth Fault Year 00 to 99 - - ro 06 11-8P0081 Eighth Fault Time 00:00 to 23:59 - - ro 06 11-8P0082 Ninth Fault 0 to 999 - - ro 06 11-6P0083 Ninth Fault Day/Month 00/00 to 31/12 - - ro 06 11-7P0084 Ninth Fault Year 00 to 99 - - ro 06 11-8P0085 Ninth Fault Time 00:00 to 23:59 - - ro 06 11-9P0086 Tenth Fault 0 to 999 - - ro 06 11-6P0087 Tenth Fault Day/Month 00/00 to 31/12 - - ro 06 11-7P0088 Tenth Fault Year 00 to 99 - - ro 06 11-8P0089 Tenth Fault Time 00:00 to 23:59 - - ro 06 11-9P0090 Current at Last Fault 0.0 to 4000.0 A - - ro 06 11-9P0091 DC Link at Last Fault 0 to 2000 V - - ro 06 11-9P0092 Line Voltage Last Fault 0 to 2000 V - - ro 06 11-9P0093 I Reactive Last Fault 0.0 to 4000.0 A - - ro 06 11-10P0095 Input Voltage Last Fault 0 to 2000 V - - ro 06 11-10P0096 DIx Status Last Fault 0 to 255 - - ro 06 11-10P0097 DOx Status Last Fault 0 to 31 - - ro 06 11-11P0100 Setpoint Filter 0.00 to 3.00 s 1.00 s - Vector 20, 93 8-2P0121 I Reactive Reference 0.0 to 4500.0 A 0.0 A - Vector 91 8-4P0151 Setpoint Voltage B DC 322 to 394 V

556 to 858 V556 to 858 V556 to 858 V556 to 858 V768 to 1029 V768 to 1029 V878 to 1234 V878 to 1234 V

358 V (P0296 = 0)618 V (P0296 = 1)650 V (P0296 = 2)715 V (P0296 = 3)780 V (P0296 = 4)853 V (P0296 = 5)935 V (P0296 = 6)975 V (P0296 = 7)

1122 V (P0296 = 8)

- Vector 20, 93 8-2

P0161 DC Link Proportional Gain 0.0 to 15.9 5.0 - Vector 93 8-2P0162 DC Link Integral Gain 0.000 to 9.999 0.009 - Vector 93 8-3P0167 Current Proportional Gain 0.000 to 1.999 0.450 - Vector 90 8-3P0168 Current Integral Gain 0.000 to 1.999 0.110 Vector 90 8-3P0169 Max. Current Rectification 0.0 to 350.0 % 125.0 % - - 92 8-6P0170 Max. Corrent Regeneration 0.0 to 350.0 % 125.0 % - - 92 8-6P0175 Reactive Proportional Gain 0.0 to 31.9 2.0 - Vector 91 8-4P0176 Reactive Integral Gain 0.000 to 1.999 0.020 - Vector 91 8-4P0179 Maximum Reactive 0 to 120 % 120 % - Vector 91, 92 8-4P0180 Reactive Generation Point 85 to 110 % 95 % - Vector 91, 92 8-5


CFW-11 RB | 0-3

0Param. Description Adjustable Range Factory SettingUser’s Setting

Prop. Groups Page

P0193 Day of the Week 0 = Sunday1 = Monday2 = Tuesday3 = Wednesday4 = Thursday5 = Friday6 = Saturday

0 - - 22 5-3

P0194 Day 01 to 31 01 - - 22 5-3P0195 Month 01 to 12 01 - - 22 5-3P0196 Year 00 to 99 06 - - 22 5-3P0197 Time 00 to 23 00 - - 22 5-3P0198 Minutes 00 to 59 00 - - 22 5-3P0199 Seconds 00 to 59 00 - - 22 5-4P0200 Password 0 = Inactive

1 = Active2 = Change Password

1 - - 22 5-4

P0201 Language 0 = Português1 = English2 = Español3 = Deutsch

0 - - 22 5-4

P0204 Load/Save Parameters 0 = Not used1 = Not used2 = Reset P00453 = Reset P00434 = Reset P00445 = Load Default

0 - cfg 04 7-1

P0205 Read Parameter Sel. 1 0 = Inactive1 = Line Voltage #2 = Input Current #3 = DC Link Voltage #4 = Input Voltage#5 = Power #6 = Line Voltage -7 = Input Current -8 = DC Link Voltage -9 = Input Voltage -10 = Power -

2 - - 22 5-5

P0206 Read Parameter Sel. 2 See options in P0205 3 - - 22 5-5P0207 Read Parameter Sel. 3 See options in P0205 1 - - 22 5-5P0213 Full Scale Read 1 0.0 to 200.0 % 100.0 % - cfg 22 5-5P0214 Full Scale Read 2 0.0 to 200.0 % 100.0 % - cfg 22 5-5P0215 Full Scale Read 3 0.0 to 200.0 % 100.0 % - cfg 22 5-5P0216 HMI Display Contrast 0 to 37 27 - - 22 5-6P0251 AO1 (Output) Function 0 = Not Used

1 = Line Voltage2 = Not Used3 = DC Link Voltage 4 = Input Current5 = Reactive Current6 = Active Current7 = Input Power

3 - - 24 9-2

P0252 AO1 Gain 0.000 to 9.999 1.000 - - 24 9-3P0253 AO1 Signal Type 0 = 0 to 10 V / 20 mA

1 = 4 to 20 mA2 = 10 V / 20 mA to 03 = 20 to 4 mA

0 - cfg 24 9-4

P0254 AO2 Function See options in P0251 4 - - 24 9-2P0255 AO2 Gain 0.000 to 9.999 1.000 - - 24 9-3P0256 AO2 Signal Type 0 = 0 to 10 V / 20 mA

1 = 4 to 20 mA2 = 10 V / 20 mA to 03 = 20 to 4 mA

0 - cfg 24 9-4


0-4 | CFW-11 RB


Prop. Groups Page

P0257 AO3 Function 0 to 7 = See options in P02518 = Not Used9 = Not Used10 = Not Used11 = Not Used12 = Vab13 = Vca14 = Ualpha15 = Ubeta16 = Phi17 = Isa18 = Isb19 = Ia20 = Ib21 = COSPHI22 = SINPHI23 = U_Diff24 = IsdRef25 = Ulinksol_Fil26 = IsqRef227 = Usd28 = Usq29 = UsdFilt30 = UD DIFF

3 - - 24 9-2

P0258 AO3 Gain 0.000 to 9.999 1.000 - - 24 9-3P0259 AO3 Signal Type 0 = 0 to 20 mA

1 = 4 to 20 mA2 = 20 to 0 mA3 = 20 to 4 mA4 = 0 to 10 V5 = 10 to 0 V6 = -10 to +10 V

4 - cfg 24 9-4

P0260 AO4 Function See options in P0257 4 - - 24 9-2P0261 AO4 Gain 0.000 to 9.999 1.000 - - 24 9-3P0262 AO4 Signal Type 0 = 0 to 20 mA

1 = 4 to 20 mA2 = 20 to 0 mA3 = 20 to 4 mA4 = 0 to 10 V5 = 10 to 0 V6 = -10 to +10 V

4 - cfg 24 9-4

P0263 DI1 (Input) Function 0 = Not Used1 = Not Used2 = General Enable3 to 17 = Not Used18 = No Ext. Alarm19 = No Ext. Fault20 = Reset21 to 31 = Not Used

2 - cfg 25 9-6

P0264 DI2 Function See options in P0263 0 - cfg 25 9-6P0265 DI3 Function See options in P0263 0 - cfg 25, 28 9-6P0266 DI4 Function See options in P0263 0 - cfg 25, 28 9-6P0267 DI5 Function See options in P0263 0 - cfg 25, 28 9-6P0268 DI6 Function See options in P0263 0 - cfg 25, 28 9-6P0269 DI7 Function See options in P0263 0 - cfg 25, 28 9-6P0270 DI8 Function See options in P0263 0 - cfg 25, 28 9-6P0275 DO1(RL1) Function 0 to 24 = Not Used

25 = Preload OK26 to 35 = Not Used

25 - ro 26 9-8


CFW-11 RB | 0-5


Prop. Groups Page

P0276 DO2 (RL2) Function 0 to 10 = Not Used11 = Run12 = Ready13 = No Fault14 to 20 = Not Used21 = Rectifying (+)22 = Not Used23 = Not Used24 = Not Used25 = Preload OK26 to 34 = Not Used35 = No Alarm

11 - cfg 26 9-8

P0277 DO3 (RL3) Function See options in P0276 13 - cfg 26 9-8P0278 DO4 Function See options in P0276 0 - cfg 26 9-8P0279 DO5 Function See options in P0276 0 - cfg 26 9-8P0295 ND/HD Converter Rated

Current0 = 3.6 A / 3.6 A1 = 5 A / 5 A2 = 6 A / 5 A3 = 7 A / 5.5 A4 = 7 A / 7 A5 = 10 A / 8 A6 = 10 A / 10 A7 = 13 A / 11 A8 = 13.5 A / 11 A9 = 16 A / 13 A10 = 17 A / 13.5 A11 = 24 A / 19 A12 = 24 A / 20 A13 = 28 A / 24 A14 = 31 A / 25 A15 = 33.5 A / 28 A16 = 38 A / 33 A17 = 45 A / 36 A18 = 45 A / 38 A19 = 54 A / 45 A20 = 58.5 A / 47 A21 = 70 A / 56 A22 = 70.5 A / 61 A23 = 86 A / 70 A24 = 88 A / 73 A25 = 105 A / 86 A26 = 427 A / 340 A27 = 470 A / 380 A28 = 811 A / 646 A29 = 893 A / 722 A30 = 1217 A / 969 A31 = 1340 A / 1083 A32 = 1622 A / 1292 A33 = 1786 A / 1444 A34 = 2028 A / 1615 A35 = 2232 A / 1805 A36 = 2 A / 2 A37 = 640 A / 515 A38 = 1216 A / 979 A39 = 1824 A / 1468 A40 = 2432 A / 1957 A41 = 3040 A / 2446 A42 = 600 A / 515 A43 = 1140 A / 979 A44 = 1710 A / 1468 A45 = 2280 A / 1957 A46 = 2850 A / 2446 A47 = 105 A / 88 A48 = 142 A / 115 A49 = 180 A / 142 A50 = 211 A / 180 A51 = 242 A / 211 A52 = 312 A / 242 A53 = 370 A / 312 A54 = 477 A / 370 A55 = 515 A / 477 A56 = 601 A / 515 A

- - ro 27 6-5


0-6 | CFW-11 RB


Prop. Groups Page

57 = 720 A / 560 A58 = 2.9 A / 2.7 A59 = 4.2 A / 3.8 A60 = 7 A / 6.5 A61 = 8.5 A / 7 A62 = 10 A / 9 A63 = 11 A / 9 A64 = 12 A / 10 A65 = 15 A / 13 A66 = 17 A / 17 A67 = 20 A / 17 A68 = 22 A / 19 A69 = 24 A / 21 A70 = 27 A / 22 A71 = 30 A / 24 A72 = 32 A / 27 A73 = 35 A / 30 A74 = 44 A / 36 A75 = 46 A / 39 A76 = 53 A / 44 A77 = 54 A / 46 A78 = 63 A / 53 A79 = 73 A / 61 A80 = 80 A / 66 A81 = 100 A / 85 A82 = 107 A / 90 A83 = 108 A / 95 A84 = 125 A / 107 A85 = 130 A / 108 A86 = 150 A / 122 A87 = 147 A / 127 A88 = 170 A / 150 A89 = 195 A / 165 A90 = 216 A / 180 A91 = 289 A / 240 A92 = 259 A / 225 A93 = 315 A / 289 A94 = 312 A / 259 A95 = 365 A / 315 A96 = 365 A / 312 A97 = 435 A / 357 A98 = 428 A / 355 A99 = 472 A / 388 A100 = 700 A / 515 A101 = 1330 A / 979 A102 = 1995 A / 1468 A103 = 2660 A / 1957 A104 = 3325 A / 2446 A105 = 795 A / 637 A106 = 877 A / 715 A107 = 1062 A / 855 A108 = 1141 A / 943 A109 = 584 A / 504 A110 = 478 A / 410 A111 = 625 A / 540 A112 = 518 A / 447 A113 = 758 A / 614 A114 = 628 A / 518 A115 = 804 A / 682 A116 = 703 A / 594 A117 = 760 A / 600 A118 = 760 A / 560 A

P0296 Line Rated Voltage 0 = 200 / 240 V1 = 380 V2 = 400 / 415 V3 = 440 / 460 V4 = 480 V5 = 500 / 525 V6 = 550 / 575 V7 = 600 V8 = 660 / 690 V

According to converter model

- cfg 27 6-7


CFW-11 RB | 0-7


Prop. Groups Page

P0297 Switching Frequency 0 = 2.5 kHz1 = 5.0 kHz2 = 10.0 kHz3 = 2.0 kHz

0 - cfg 27 6-8

P0298 Application 0 = Normal Duty (ND)1 = Heavy Duty (HD)

0 - cfg 27 6-8

P0317 Oriented Start-up 0 = No1 = Yes

0 - cfg 02 8-9

P0318 Copy Function MemCard 0 = Off1 = Converter → MemCard2 = MemCard → Converter

0 - cfg 04 7-2

P0319 Copy Function HMI 0 = Off1 = Converter → HMI2 = HMI → Converter

0 - cfg 04 7-2

P0340 Auto-Reset Time 0 to 255 s 0 s - - 28 10-1P0343 Ground Fault Configuration 0 = Off

1 = On0 - cfg 28 10-2

P0352 Fan Control Configuration 0 = VD-OFF, VI-OFF1 = VD-ON, VI-ON2 = VD-CT, VI-CT3 = VD-CT, VI-OFF4 = VD-CT, VI-ON5 = VD-ON, VI-OFF6 = VD-ON, VI-CT7 = VD-OFF, VI-ON8 = VD-OFF, VI-CT9 = VD-CT, VI-CT * 10 = VD-CT, VI-OFF *11 = VD-CT, VI-ON *12 = VD-ON, VI-CT *13 = VD-OFF, VI-CT *

2 - cfg 28 10-2

P0353 IGBT/Air Overtemperature Configuration

0 = D-F/A, AR-F/A1 = D-F/A, AR-F2 = D-F, AR-F/A3 = D-F, AR-F4 = D-F/A, AR-F/A *5 = D-F/A, AR-F *6 = D-F, AR-F/A *7 = D-F, AR-F *

0 - cfg 28 10-3

P0354 Fan Speed Configuration 0 = Alarm1 = Fault

1 - cfg 28 10-4

P0356 Dead Time Compensation 0 = Alarm1 = On

1 - cfg 28 10-4

P0357 Time Fault Line Phase 0.01 to 3.00 s 2.00 s - - 28 10-4P0360 Temp. Imb. Conf. 0 = Fault/Alarm

1 = Fault0 Frame H and

cfg28 10-4

P0800 Temper. U-B1/IGBT U1 -20.0 to 150.0 °C - - CFW-11M,Frame H and

ro

07, 28 10-5

P0801 Temper. V-B1/IGBT V1 -20.0 to 150.0 °C - - CFW-11M,Frame H and

ro

07, 28 10-5

P0802 Temper. W-B1/IGBT W1 -20.0 to 150.0 °C - - CFW-11M,Frame H and

ro

07, 28 10-5

P0803 Temper. U-B2/IGBT U2 -20.0 to 150.0 °C - - CFW-11M,Frame H and

ro

07, 28 10-5

P0804 Temper. V-B2/IGBT V2 -20.0 to 150.0 °C - - CFW-11M,Frame H and

ro

07, 28 10-5

P0805 Temper. W-B2/IGBT W2 -20.0 to 150.0 °C - - CFW-11M,Frame H and

ro

07, 28 10-5

P0806 Temper. U-B3/IGBT U3 -20.0 to 150.0 °C - - CFW-11M and ro

07, 28 10-5

P0807 Temper. V-B3/IGBT V3 -20.0 to 150.0 °C - - CFW-11M and ro

07, 28 10-5


0-8 | CFW-11 RB

0Param. Description Adjustable Range Factory Setting

User’s Setting

Prop. Groups Page

P0808 Temper. W-B3/IGBT W3 -20.0 to 150.0 °C - - CFW-11M and ro

07, 28 10-5


07, 28 10-5


07, 28 10-5


07, 28 10-5


07, 28 10-6


07, 28 10-6


07, 28 10-6

P0815 Current U-B1/IGBT U1 -1000.0 to 2000.0 A - CFW-11M,Frame H and ro

07, 28 10-6

P0816 Current V-B1/IGBT V1 -1000.0 to 2000.0 A - CFW-11M,Frame H and ro

07, 28 10-6

P0817 Current W-B1/IGBT W1 -1000.0 to 2000.0 A - CFW-11M,Frame H and ro

07, 28 10-6

P0818 Current U-B2/IGBT U2 -1000.0 to 2000.0 A - CFW-11M,Frame H and ro

07, 28 10-6

P0819 Current V-B2/IGBT V2 -1000.0 to 2000.0 A - CFW-11M,Frame H and ro

07, 28 10-6

P0820 Current W-B2/IGBT W2 -1000.0 to 2000.0 A - CFW-11M,Frame H and ro

07, 28 10-6

P0821 Current U-B3/IGBT U3 -1000.0 to 2000.0 A - CFW-11Mand ro

07, 28 10-6

P0822 Current V-B3/IGBT V3 -1000.0 to 2000.0 A - CFW-11Mand ro

07, 28 10-6

P0823 Current W-B3/IGBT W3 -1000.0 to 2000.0 A - CFW-11Mand ro

07, 28 10-6


07, 28 10-6


07, 28 10-6


07, 28 10-7


07, 28 10-7


07, 28 10-7


07, 28 10-7

P0832 DIM1 (Input) Function 0 = Not Used1 = External Fault2 = Refrig. Fault

0 - CFW-11M 28 10-7

P0833 DIM2 Function 0 = Not Used1 = External Fault2 = Refrig. Fault

0 - CFW-11M 28 10-7

P0834 DIM2 to DIM1 Status Bit 0 = DIM1Bit 1 = DIM2

- - CFW-11M and ro

07, 25 10-7

Notes:ro = Read-only parameter.cfg = Configuration parameter, it can only be changed with a disabled converter.CFW-11M = Parameter only available for Modular Drive models.Frame H = Parameter only available for Frame H models.


CFW-11 RB | 0-9

0ALARMS, FAULTS AND POSSIBLE CAUSES

Fault/Alarm Description Possible Causes

F006 (10)Deseq./Fault of the Line Phase

Phase loss fault on the supply line or wrong phase sequence.

; Check connections of the CSR11 card. ; Check connections of the synchronism transformers. ; Check line connection.

F021 Undervoltage bar DC

Undervoltage fault on the intermediate circuit. ; Supply voltage too low, producing voltage on the DC bar below the minimum value (read value in P0004 Parameter):Ud < 223 V - Supply voltage 200 / 240 V (P0296 = 0). Ud < 385 V – Supply voltage 380 V (P0296 = 1).Ud < 405 V – Supply voltage 400 / 415 V (P0296 = 2). Ud < 446 V – Supply voltage 440 / 460 V (P0296 = 3). Ud < 487 V – Supply voltage 480 V (P0296 = 4).Ud < 530 V – Supply voltage 500 / 525 V (P0296 = 5). Ud < 580 V – Supply voltage 550 / 575 V (P0296 = 6). Ud < 605 V – Supply voltage 600 V (P0296 = 7).Ud < 696 V – Supply voltage 660 / 690 V (P0296 = 8).

; Phase loss in the input. ; Fault in the pre-load circuit. ; P0296 Parameter selected for use above the line rated voltage.

F022 Overvoltage bar DC

Overvoltage fault on the intermediate circuit. ; Supply voltage too high, producing voltage on the DC bar above the maximum value:Ud > 400 V - Models 220 / 230 V (P0296 = 0).Ud > 800 V - Models 380 / 480 V (P0296 = 1, 2, 3 or 4). Ud > 1000 V - Models 500 / 600 V (P0296 = 5, 6 or 7). Ud > 1200 V - Models 660 / 690 V (P0296 = 8).

; Inertia of the driven load too high or very quick deceleration.

; P0151 too high.F030 (13)Arm U Fault

Desaturation fault in the IGBTs of phase U. ; Short-circuit between phases U and V or U and W of the input.

F034 (13)Arm V Fault

Desaturation fault in the IGBTs of phase V. ; Short-circuit between phases V and U or V and W of the input.

F038 (13)Arm W Fault

Desaturation fault in the IGBTs of phase W. ; Short-circuit between phases W and U or W and V of the input.

A047 (1)Overload on the IGBTs

IGBT overload alarm. ; High current at the converter input.

F048 (1)Overload on the IGBTs

IGBT overload fault. ; High current at the converter input.

A050 (1)IGBT High Temperature U

High temperature alarm detected by the temperature sensors on the phase U IGBT.Note:It may be disabled by setting P0353 = 2 or 3.

; Surrounding ambient temperature of the converter is high (> 40 °C (104 ºF) or 45 °C (113 ºF) depending on the model – see item 3.1 of CFW-11M user’s manual) and high input current.

; Blocked or defective fan. ; Very dirty heatsink.

F051 (1)IGBT Overtemperature

Overtemperature fault on the phase U IGBTs.

A053 (12)IGBT High Temperature V

High temperature alarm detected by the temperature sensors on the phase V IGBT.Note:It may be disabled by setting P0353 = 2 or 3.

F054 (12)IGBT Overtemperature V

Overtemperature fault on the phase V IGBTs.

A056 (12)IGBT High Temperature W

High temperature alarm detected by the temperature sensors on the phase W IGBT.Note:It may be disabled by setting P0353 = 2 or 3.

F057 (12)IGBT Overtemperature V

Overtemperature fault on the phase W IGBTs.


0-10 | CFW-11 RB

0 Fault/Alarm Description Possible Causes

F062 (15)Thermal Imbalance

Fault of power module temperature imbalance. ; The temperature difference between IGBT modules of the same phase (U, V, W) was above 15 °C (59 ° F).

; The temperature difference between IGBT modules of different phases (U and V, U and W, V and W) was above 20 °C (68 ° F).

F070 (10)Overcurrent/Short-

Overcurrent or short-circuit at the input in the DC Link. ; IGBT modules are shorted.

F071 Input overcurrent

Overcurrent fault at the input. ; Very low input reactance. ; Very high adjustment of P0169 and P0170.

F074 Ground Fault

Ground overcurrent fault.Note:It may be disabled by setting P0343 = 0.

; Shorted ground in +UD or -UD.

F080 CPU Fault (Watchdog)

Microcontroller watchdog fault. ; Electrical noise.

F082 Copy Function Fault

Fault on the parameter copy. ; Attempt to copy the HMI parameters for the converter with different software versions.

F084 Auto-diagnosis Fault

Auto-diagnosis Fault. ; Defect in the converter internal circuitry.

A088 Communication Lost

HMI communication fault with the control board. ; Loose keypad cable connection. ; Electrical noise in the installation.

A090 External Alarm

External alarm via Digital Input (DI).Note:It is necessary to set a DI to "no external alarm".

; Open wiring in the inputs from DI1 to DI8 (set to “No External Alarm”).

F091 External Fault

External fault via digital input (DI).Note:It is necessary to set a DI to "no external fault".

; Open wiring in the inputs from DI1 to DI8 (set to “No External Fault”).

F099 Invalid Current Offset

Current measurement circuit is measuring a wrong value for null current.

; Defect in the converter internal circuitry.

F101Invalid Voltage Offset

Input voltage measurement circuit (synchronism) has value outside the range.

; Main contactor closed before completing the preload.

; CPU was reset and the main contactor did not open.

A105 Injection of Reactive Power in the Line

Alarm of injection of reactive current in the line ; Line voltage excessively above the rated voltage. ; P0180 very low.

F151FLASH Memory Module Fault

FLASH Memory Module Fault (MMF-01).

; Defective FLASH Memory Module. ; FLASH Memory Module is not seated properly.

A152Internal Air High Temperature

Alarm indicating that the internal air temperature is high.Note:It may be disabled by setting P0353 = 1 or 3.

; Surrounding ambient temperature of the converter is high (> 40 °C (104 ºF) or 45 °C (113 ºF) depending on the model – see item 3.1 of CFW-11M user’s manual) and high input current.

; Defective fan. ; Very dirty heatsink.

F153 Internal Air Overtemperature

Internal air overtemperature fault.

A155 Undertemperature

Only one sensor indicates temperature below -30 °C. ; Ambient temperature around the converter ≤ 30 °C.

F156 Undertemperature

Undertemperature fault in the IGBTs measured by the temperature sensors (below –30 °C).

; Surrounding ambient temperature of the converter ≤ –30 °C (-22 ºF).

; Defective internal circuits of books (source, cables).

F174 (6)Left fan speed fault

Heatsink left fan speed fault. ; Dirt on the blades and in the bearings of the fan. ; Defective fan. ; Defective fan power supply connection.F175 (7)

Center fan speed faultHeatsink center fan speed fault.

F176 (6)Right fan speed fault

Heatsink right fan speed fault.

A177 Fan Replacement

Fan replacement alarm (P0045 > 50000 hours).Note:It may be disabled by setting P0354 = 0.

; Maximum number of operating hours for the heatsink fan has been reached.

A178 Heatsink fan speed alarm

This alarm indicates a problem with the heatsink fan. ; Dirt on the blades and in the bearings of the fan. ; Defective fan. ; Defective fan power supply connection.

F179Fan speed fault

Speed fault below the minimum limit. ; Dirt or blocked fan.


CFW-11 RB | 0-11

0Fault/Alarm Description Possible Causes

A181 Invalid clock value

Invalid clock value alarm. ; It is necessary to set the date and time in P0194 to P0199. ; Keypad battery is discharged, defective or not installed.

F182 Pulse feedback fault

Pulse feedback fault. ; Defect in the converter internal circuitry. ; Defective fiber optics. ; Defect in the cables XC10A, B, C, D or E.

F183 IGBT Overload +Temperature

Overtemperature related to the IGBT overload protection.

; High ambient temperature around the converter. ; Operation with overload.


0-12 | CFW-11 RB


A300 (10)High temperature at IGBT U B1

High temperature alarm measured with the temperature sensor (NTC) of the book 1 U phase IGBT.

; High ambient temperature (> 40 °C (104 ºF) or 45 °C (113 ºF) depending on the model, see item 3.1 of CFW-11M user’s manual) and high current.

; Blocked or defective fan. ; Fins of the book heatsink too dirty, impairing the air flow.

F301 (10)Overtemperature at IGBT U B1

Overtemperature fault measured with the temperature sensor (NTC) of the book 1 U phase IGBT.

A303 (10)High temperature at IGBT V B1

High temperature alarm measured with the temperature sensor (NTC) of the book 1 V phase IGBT.

F304 (10)Overtemperature at IGBT V B1

Overtemperature fault measured with the temperature sensor (NTC) of the book 1 V phase IGBT.

A306 (10)High temperature at IGBT W B1

High temperature alarm measured with the temperature sensor (NTC) of the book 1 W phase IGBT.

F307 (10)Overtemperature at IGBT W B1

Overtemperature fault measured with the temperature sensor (NTC) of the book 1 W phase IGBT.


















































CFW-11 RB | 0-13


A345 (10)High load at IGBT U B1

Overload alarm at book 1 U phase IGBT.

; High current at the converter input (see figure 8.1 of CFW-11M user’s manual).

F346 (10)Overload at IGBT U B1

Overload fault at book 1 U phase IGBT.

A348 (10)High load at IGBT V

Overload alarm at book 1 V phase IGBT.

F349 (10)Overload at IGBT V B1

Overload fault at book 1 V phase IGBT.

A351 (10)High load at IGBT W

Overload alarm at book 1 W phase IGBT.

F352 (10)Overload at IGBT W B1

Overload fault at book 1 W phase IGBT.





A357 (10)High load at IGBT V B2




A360 (10)High load at IGBT W B2









































0-14 | CFW-11 RB


A390 (10)Current Unbalance at Phase U B1

Phase U book 1 current unbalance alarm. It indicates a 20 % unbalance in the current distribution between this phase and the smallest current of the same phase in other book, only when the current in this phase is higher than 75 % of its nominal value.

; Bad electric connection between the DC Link and the power unity.

; Bad electric connection between power unit input and the line links.

Note: In case of fast acceleration or braking, one of these alarms may be indicated momentarily, disappearing after 3 seconds. This is not an indication of any anomaly in the converter.If the alarm persists when the motor is operating at a constant speed, it is an indication of an anomaly in the current distribution among the power units.

A391 (10)Current Unbalance at Phase V B1

Phase V book 1 current unbalance alarm. It indicates a 20 % unbalance in the current distribution between this phase and the smallest current of the same phase in other book, only when the current in this phase is higher than 75 % of its nominal value.

A392 (10)Current Unbalance at Phase W B1

Phase W book 1 current unbalance alarm. It indicates a 20 % unbalance in the current distribution between this phase and the smallest current of the same phase in other book, only when the current in this phase is higher than 75 % of its nominal value.






















CFW-11 RB | 0-15




; Bad electric connection between the DC Link and the power unity.

; Bad electric connection between power unit input and the line links.

Note: In case of fast acceleration or braking, one of these alarms may be indicated momentarily, disappearing after 3 seconds. This is not an indication of any anomaly in the converter.

If the alarm persists when the motor is operating at a constant speed, it is an indication of an anomaly in the current distribution among the power units.



F408 (10)Refrigeration System Fault

Faults related to the settings of parameters P0832 or P0833.

; DIM 1 Input Function. ; DIM 2 Input Function.

; Electrical connection fault between the digital input and the sensor.

; Corresponding sensor fault. ; Fault of the device whose sensor is monitoring. ; Open DIM1 or DIM2.

F410 (10)External Fault

F416 (15)IGBT Curr. Imb. Fault

Fault of current imbalance on the IGBTs. ; IGBTs of the same phase presented a current imbalance above 15 %.

A417 (15)Thermal Imbalance

Alarm of power module temperature imbalance. ; The temperature difference between IGBT modules of the same phase (U, V, W) was above 10 °C (50 ° F).

; The temperature difference between IGBT modules of different phases (U and V, U and W, V and W) was above 10 °C (50 ° F).

F418 (15)Air Control Overtemp.

Fault of overtemperature of the internal air on thecontrol board.

; Temperature of the internal air of the control board is above 85 °C (185 ° F).

A419 (15)Control Air TemperatureHigh Alarm

Alarm of overtemperature of the internal air on thecontrol board.

; When the temperature of the internal air of the control board is above 70 °C (158 °F).

Models which may occur:

(1) All the models of frames A to G.

(2) Non-applicable.

(3) All the models of frames D and E.

(4) All the models of frames A, B and C.

(5) Non-applicable.

(6) Models CFW110370T4, CFW110477T4 and all the models of frame G.

(7) All the models of frame G.

(8) Non-applicable.

(9) Non-applicable.

(10) All the models of CFW-11M/CFW-11W.

(11) Non-applicable.

(12) All the models of frames F and G.

(13) All the models of frames D, E, F, G and CFW-11M/CFW-11W.

Note: In the case of CFW-11M/CFW-11W the IPS1 card indicates which of the power unities is presenting the

fault. The signaling is done through LEDs that remain on when the fault occurs. When reset is done, the LED that

indicates the fault turns off (Refer to Figure 0.1 on page 0-16).

(14) A very long flexible cord of the motor, with over 100 meters (328.08 ft), will present a high stray capacitance to

the ground wire. The circulation of eddy currents in these capacitances may cause the activation of the ground

fault circuit and, consequently, F074 blocking, immediately after enabling the converter.


0-16 | CFW-11 RB

0

Figure 0.1 - Fault indicator LEDs

(15) All the models of frame H.

Safety Instructions

CFW-11 RB | 1-1

1

1 SAFETY INSTRUCTIONS

This manual contains information necessary for the correct use of the regenerative converter CFW-11 RB.

It was developed to be used by people with proper technical training or qualification to operate this kind of

equipment.

1.1 SAFETY WARNINGS IN THIS MANUAL

In this manual, the following safety warnings are used:

DANGER!The procedures recommended in this warning aim at protecting the user against death, serious

injuries and considerable material damages.

ATTENTION!The procedures recommended in this warning aim at preventing material damages.

NOTE!The text aims at providing important information for the full understanding and proper operation of

the product.

1.2 SAFETY WARNINGS ON THE PRODUCT

The following symbols are fixed to the product, as a safety warning:

High voltages present.

Components sensitive to electrostatic discharges.

Do not touch them.

Mandatory connection to the protection grounding (PE).

Connection of the shield to the grounding.

Hot surface.

Safety Instructions

1-2 | CFW-11 RB

1

1.3 PRELIMINARY RECOMMENDATIONS

DANGER!Only qualified personnel, familiar with the regenerative converter CFW-11 RB and related equipment

must plan or perform the installation, commissioning, operation and maintenance of this equipment.

The personnel must follow the safety instructions described in this manual and/or defined by local

standards.

The noncompliance with the safety instructions may result in death risk and/or equipment damage.

NOTE!For the purposes of this manual, qualified personnel are those trained in order to be able to:

1. Install, ground, power up and operate the CFW-11 RB in accordance with this manual and the

safety legal procedures in force.

2. Use the protective equipment in accordance with the relevant standards.

3. Give first aid.

DANGER!Always disconnect the general power supply before touching any electrical component connected

to the converter.

Many components may remain loaded with high voltages and/or moving (fans), even after the AC

power supply input is disconnected or turned off. Wait for at least ten minutes so as to guarantee

the full discharge of the capacitors.

Always connect the frame of the equipment to the proper protection grounding (PE).

ATTENTION!The electronic boards have components sensitive to electrostatic discharges. Do not touch the

components or connectors directly. If necessary, first touch the grounded metallic frame or use

proper grounding strap.

Do not carry out any applied potential test on regenerative converter!If necessary, contact WEG.

NOTE!Regenerative converters may interfere in other electronic equipment. Observe the recommendations

of chapter 3 - Installation and Connection of the user’s manual in order to minimize these effects.

NOTE!Read the user’s manual completely before installing or operating the regenerative converter.

General Information

CFW-11 RB | 2-1

2

2 GENERAL INFORMATION

2.1 ABOUT THE MANUAL

This manual presents information necessary for the configuration of all the functions and parameters of the

regenerative converter CFW-11 RB. This manual must be used together with the user’s manual of the CFW-11 RB.

The text provides additional information so as to make the use and programming of the CFW-11 RB easier, in

certain applications.

2.2 TERMINOLOGY AND DEFINITIONS

2.2.1 Terms and Definitions Used in the Manual

Normal Overload Duty (ND): the so-called Normal Duty (ND); converter operation duty that sets the

value of maximum current for continuous duty Inom-ND and overload of 110 % per minute. It is selected by

programming P0298 (Application) = 0 (Normal Duty (ND)).

The duty of the inverter overload reflects on the regenerative converter.

Imom-ND: rated current of the regenerative converter for use with normal overload duty (ND = Normal Duty).

Overload: 1.1 x Inom-ND / 1 minute.

Heavy Overload Duty (HD): the so-called Heavy Use or from English: “Heavy Duty” (HD); converter operation

duty that sets the value of maximum current for continuous duty Inom-HD and overload of 150 % per minute. It is

selected by programming P0298 (Application) = 1 (Heavy Duty (HD)).

The duty of the inverter overload reflects on the regenerative converter.

Inom-HD: rated current of the regenerative converter for use with heavy overload duty (HD= Heavy Duty).

Overload: 1.5 x Inom-HD / 1 minute.

Regenerative Converter: three-phase switched converter of “boost type” (amplifier) that converts the alternating

current (AC) of the line in DC voltage (DC Bus). It is able to absorb energy from the line (AC) or return energy

to it, being used as DC voltage source that feeds one or more output inverters.

Output Converter: frequency inverter with power circuit supplied by the DC Link that comes from the regenerative

converter. It in charge of the control of the motor.

Pre-Charge Circuit: it loads the capacitors of the DC link with limited current, sending greater current peaks

at the energizing of the converter.

DC Link: intermediate circuit of the regenerative converter; voltage in direct current obtained by rectifying the

alternate power supply voltage or through an external source; it supplies the output inverter bridge.

U, V and W Arm: set of two IGBTs of the input phases R, S, T of the regenerative converter.

IGBT: “Insulated Gate Bipolar Transistor”; it is a basic component of the U, V and W arms. It operates like an

electronic key in the saturated (closed switch) and cut (open switch).

General Information

2-2 | CFW-11 RB

2

NTC: resistor whose resistance value in ohms decreases proportionally to the increase of the temperature;

it is used as a temperature sensor in power modules.

HMI: Human-Machine Interface; it is a device that allows visualization and modification of the parameters of

the regenerative converter. It features keys to control the regenerative converter, navigation keys and graphic

LCD display.

MMF (Flash Memory Module): it is the nonvolatile memory that can be electrically written and erased.

RAM Memory: it is the volatile memory of the “Random Access Memory”.

USB: it is a type of connection in the perspective of the “Plug and Play” concept.

PE: Protective Earth.

RFI Filter: Radio Frequency Interference Filter – It is a filter that avoids interference in the radiofrequency band.

PWM: “Modulation”; it is a pulse width modulation, a pulsing voltage in the input of the regenerative converter.

Switching Frequency: commutating frequency of the IGBTs, normally expressed in kHz.

General Enable: when activated, the PWM pulses in the input of the regenerative converter are enabled.

When deactivated, the PWM pulses will be immediately blocked. It can be commanded through digital input

programmed for that function.

Heatsink: metal part designed to dissipate the heat produced by power semiconductors.

Amp, A: ampere.

°C: celsius degree.

°F: fahrenheit degree.

AC: alternate current.

DC: direct current.

CFM: “Cubic feet per minute”; it is a flow measurement unit.

cm: centimeter.

CV: Cavalo-Vapor = 736 Watts (Brazilian unit of measurement of power, normally used to indicate mechanical power of electric motors).

HP: Horse Power = 746 watts (unit of measurement of power, normally used to indicate mechanical power of electric motors).

Hz: hertz.

General Information

CFW-11 RB | 2-3

2

l/s: liters per second.

kg: kilogram = 1000 grams.

kHz: kilohertz = 1000 hertz.

m: meter.

mA: milliampere = 0.001 ampere.

min: minute.

mm: millimeter.

ms: millisecond = 0.001 second.

Nm: Newton meter; torque measurement unit.

rms: “Root Mean Square”; effective value.

rpm: Revolutions per minute; speed measurement unit.

s: second.

V: volts.

Ω: ohms.

2.2.2 Numerical Representation

The decimal numbers are represented by means of digits without suffix. Hexadecimal numbers are represented

with the letter “h” after the number.

2.2.3 Symbols to Describe Parameter Properties

RO Read parameter only.CFG Parameter only modified with a disabled regenerative converter.CFW-11M Parameter visible on the HMI only when available in the Modular Drive, version RB.FRAME H Parameter only available for Frame H models.

General Information

2-4 | CFW-11 RB

2

About the CFW-11 RB

CFW-11 RB | 3-1

3

3 ABOUT THE CFW-11 RB

3.1 ABOUT THE CFW-11 RB

The regenerative converter CFW-11 RB is a high performance product that makes it possible the rectification

of three-phase lines presenting the following advantages:

Low harmonics distortion in the input current.

Capability of returning energy to the line (regeneration) enabling high braking torques.

Line voltage (P0002)

Line

Circuit breaker

(LC filter) L boost

A B C

R S T

Input voltage (P0007)

CFW11 RB

CSR11

XC1:1

XC50

XC50

X2H1T1

T2

H1

X1

X1H2

H2

X2

2

3

4

5

CC11

Figure 3.1 - Synchronism connection diagram

NOTES:1. The line voltage (indicated in P0002) is the voltage measured through the synchronism board (CSR11) before

the input filter (Refer to Figure 3.1 on page 3-1).

2. The input voltage (indicated in P0007) is the voltage on the terminals R, S, T of the converter (after the input

filter), calculated by the software from PWM applied to these terminals.

About the CFW-11 RB

3

3-2 | CFW-11 RB

UP11

UP11

Capa-citor bank

Capa-citor bank

DC Link Feedback- voltage- current

Pre--charge

Inputfilter

Lboost

Line

(P0002) (P0007)

220 V Ext.

Power

PE

+

-

FLASH memory module (Slot 5)

Digital inputs (DI1 to DI6)

IPS1 Power supplies for electronics and for interface between power and controlUSB

CSR 11

UC11 - control

HMI

CC11

Control board with

CPU32 bit"RISC"

Analog outputs (AO1

and AO2)

Digital outputs DO1 (RL1) to DO3 (RL3)

HMI (remote)

Accessories

I/O expansion (Slot 1 – white)

Figure 3.2 - Block diagram of CFW-11 RB

About the CFW-11 RB

CFW-11 RB | 3-3

3

USB Connector

USB LED Off: No USB connection On/flashing: USB communication active

Status LED (STATUS)Green: normal operation No fault or alarmYellow: in the alarm conditionRed Flashing: in the fault condition

1

1

3

3

22

Figure 3.3 - LEDs and USB connector

About the CFW-11 RB

3

3-4 | CFW-11 RB

HMI

CFW-11 RB | 4-1

4

4 HMI

4.1 HMI

Through the HMI, it is possible to control the converter, visualize and adjust all the parameters. It presents a

navigation manner similar to the one used in cell phones, without the option to access the parameters sequentially

or by means of groups (menu).

Not used.

Not used.

Left “Soft key”: function defined by the text directly above on the display.

1. Increases the parameter content.2. Previous group of the Parameter Group List.

Not used.

1. Decreases the parameter content.2. Selects the next Group of the Parameter Group List.

Right “Soft Key”: function defined by the text directly above on the display.

Not used.

Allows:1. Fault Reset.2. Exit routine of oriented star-up.

Figure 4.1 - HMI keys

NOTE!The battery is necessary only maintain the internal clock operation when the converter is de-energized.

In the event of the battery being discharged, or not installed in the keypad (HMI), the clock time

becomes incorrect and the indication A181 – “Clock with invalid value” will occur every time the

converter is powered.

The life expectation of the battery is of approximately 10 years. Replace the battery, when necessary, by another

of the CR2032 type.

HMI

4-2 | CFW-11 RB

4

4 5 6

Remove the battery with the help of a screwdriver

positioned in the right side

HMI without the battery Install the new battery positioning it first at the left

side

7 8

Press the battery for its insertion

Put the cover back and rotate it clockwise

1 2 3

Location of the cover for battery access

Press and rotate the cover counterclockwise

Remove the cover

Cover

Figure 4.2 - HMI battery replacement

NOTE: At the end of the useful life, do not dispose the battery in common garbage, but in a proper place for batteries.

Programming Basic Instructions

CFW-11 RB | 5-1

5

5 PROGRAMMING BASIC INSTRUCTIONS

5.1 PARAMETER STRUCTURE

When the right “soft key” in the monitoring mode (“MENU”) is pressed, the first 4 parameters groups are showed on the display. An example of the parameter group structure is presented in the Table 5.1 on page 5-1. The number and the name of the groups may change depending on the used software.

NOTE!The converter leaves the factory with the keypad (HMI) language, frequency and voltage adjusted

according to the market.

Table 5.1 - CFW-11 RB parameter group structure

Level 0 Level 1 Level 2 Level 3

Monitoring

00 ALL PARAMETERS

01 PARAMETER GROUPS

20 Link Voltage

21 Control

90 Current Regulator91 Reactive Regulator92 Current Limits93 DC Link Regulator

22 HMI24 Analog Outputs25 Digital Inputs26 Digital Outputs27 Converter Data28 Protections

02 ORIENTED START-UP 03 CHANGED PARAMETERS04 BACKUP PARAMETERS

05 I/O CONFIGURATION 24 Analog Outputs25 Digital Inputs26 Digital Outputs

06 FAULT HISTORY07 READ ONLY PARAMETERS

5.2 GROUPS ACCESSED IN THE OPTION MENU IN THE MONITORING MODE

In the monitoring mode access the groups of the option “Menu” by pressing the right "soft key".

Table 5.2 - Parameter groups accessed in the option menu of the monitoring mode

Group Contained Parameters or Groups 00 ALL PARAMETERS All parameters.01 PARAMETER GROUPS Access to groups divided by functions.02 ORIENTED START-UP Parameter for entering “Oriented Start-up” mode.03 CHANGED PARAMETERS Only parameters whose content is different from the factory settings.

04 BACKUP PARAMETERSParameters related to functions of parameter copy via FLASH Memory Module, keypad (HMI) and software update.

05 I/O CONFIGURATION Groups related to digital and analog, inputs and outputs.06 FAULT HISTORY Parameters with information on the 10 last faults.07 READ ONLY PARAMETERS Parameters used only for reading.


5-2 | CFW-11 RB

5

5.3 ADJUSTMENT OF THE PASSWORD IN P0000

P0000 – Access to Parameters

AdjustableRange:

0 to 9999 Factory Setting:

0

Properties:

Access groups via HMI:

00 ALL PARAMETERS

In order to be able to change the content of the parameters, it is necessary to set correctly the password in

P0000, as indicated below. Otherwise the content of the parameters can only be visualized.

It is possible to customize the password by means of P0200. Refer to the description of this parameter in the

Section 5.4 HMI [22] on page 5-3 of this manual.

Seq. Action/Result Display Indication

1

- Monitoring mode.

- Press “Menu”

(right soft key).

RUN RB + LOC 618 V

15:45 Menu

400 A618 V380 V

2

- The group “00 ALL

PARAMETERS” is already

selected.

- Press “Selec.”.

RUN RB + LOC 618 V

Exit 15:45 Select

00 ALL PARAMETERS01 PARAMETER GROUPS02 ORIENTED START-UP 03 CHANGED PARAMETERS

3

- The parameter “Access

to Parameters P0000: 0”

is already selected.

- Press “Select”.

RUN RB + LOC 618 V

Exit 15:45 Select

Access to ParametersP0000: 0Line VoltageP0002: 380 V

4

- In order to set the

password, press

until the number 5

appears on the display.

RUN RB + LOC 618 V

Exit 15:45 Save

P0000Access to Parameters 0

5- When number 5 shows,

press “Save”.

RUN RB + LOC 618 V

Exit 15:45 Save

P0000Access to Parameters 5

6

- If the setting was

correctly done, the display

must show “Access to

Parameters P0000: 5”.

- Press “Exit”

(left soft key).

RUN RB + LOC 618 V

Exit 15:45 Select

Access to ParametersP0000: 5Line VoltageP0002: 380 V


CFW-11 RB | 5-3

5

Seq. Action/Result Display Indication

7 - Press “Exit”.

RUN RB + LOC 618 V

Exit 15:45 Select


8- The display goes backt

o the Monitoring Mode.

RUN RB + LOC 618 V

15:45 Menu

400 A618 V380 V

Figure 5.1 - Sequence for allowing parameter change via P0000

5.4 HMI [22]

In the group “22 HMI” are the parameters related to the presentation of information on the keypad (HMI)

display. See detailed description below of the possible settings of those parameters.

P0193 – Day of the Week

AdjustableRange:

0 = Sunday1 = Monday2 = Tuesday3 = Wednesday4 = Thursday5 = Friday6 = Saturday

Factory Setting:

00

P0194 – Day

AdjustableRange:


01

P0195 – Month

AdjustableRange:


01

P0196 – Year

AdjustableRange:


06

P0197 - Hour

AdjustableRange:


00

P0198 – Minutes


5-4 | CFW-11 RB

5

P0199 – Seconds

AdjustableRange:


P0198 = 00P0199 = 00

Properties:

Access Groups via HMI:

01 PARAMETER GROUPS

22 HMI

Description:

These parameters set the date and time of the real time clock of the CFW-11 RB. It is important to set them with the correct date and time so that the fault and alarm record occurs with current date and time information.

P0200 – Password

AdjustableRange:

0 = Inactive1 = Active2 = Change

Factory Setting:

1

Properties:


01 PARAMETER GROUPS

22 HMI

Description:

It allows changing the password and or setting its status, configuring it as active or inactive. For more details on each option, see Table 5.3 on page 5-4 described next.

Table 5.3 - Options of parameter P0200

P0200 Type of Action0 (Inactive) It allows changing the content of the parameters regardless of P0000.

1 (Active) It only allows changing the content of the parameters when P0000 is equal to the value of the password.

2 (Change Password) It opens a window for changing the password.

When the option 2 is selected (Change Password) and the Save "Soft Key" is pressed, the converter opens a window for changing the password, allowing the selection of a new value for it. After the adjustment is done, press Save "Soft Key", so that the new password is accepted. The P0200 content changes for Active, automatically.

P0201 – Language

AdjustableRange:

0 = Português1 = English2 = Español3 = Deutsch

Factory Setting:

0

Properties:


01 PARAMETER GROUPS

22 HMI

Description:

It determines the language in which information will be presented on the keypad (HMI).


CFW-11 RB | 5-5

5

P0205 – Reading Parameter Selection 1



AdjustableRange:

0 = Inactive1 = Line Voltage #2 = Input Current #3 = DC Link Voltage #4 = Input voltage #5 = Power #6 = Line Voltage -7 = Input Current -8 = DC Link Voltage -9 = Input voltage -10 = Power -

Factory Setting:

P0205 = 2P0206 = 3P0207 = 1

Properties:


01 PARAMETER GROUPS

22 HMI

Description:

These parameters define which variables and in what manner they will be shown on the keypad (HMI) in the monitoring mode.

The options that present the symbol “#” at the end indicate that the variable will be displayed in absolute numerical values. The options ended with the symbol “–”, configure the variable to be displayed as a bar graph, in percentage values. More details on this programming can be seen in the Section 5.6 SETTING OF DISPLAY INDICATIONS IN THE MONITORING MODE on page 5-7 below.

P0213 – Full Scale Reading Parameter 1



AdjustableRange:

0.0 to 200.0 % Factory Setting:

100.0 %

Properties: cfg


01 PARAMETER GROUPS

22 HMI

Description:

These parameters configure the full scale of the reading variables 1, 2 and 3 (selected through P0205, P0206 and P0207), when they are programmed to be presented as bar graphs.


5-6 | CFW-11 RB

5

P0216 – HMI Display Contrast

AdjustableRange:


27

Properties:


01 PARAMETER GROUPS

22 HMI

Description:It allows setting the keypad (HMI) display contrast level. Higher values configure a higher contrast level.

5.5 DATE AND TIME SETTING

Seq. Action/Result Display Indication Seq. Action/Result Display Indication

1

- Monitoring Mode.

- Press “Menu”

(right "soft key").

Run RB + LOC 618 V

16:10 Menu

400 A618 V380 V

2



selected.

Run RB + LOC 618 V

Exit 16:10 Select

00 ALL PARAMETERS01 PARAMETER GROUPS02 ORIENTED START-UP03 CHANGED PARAMETERS

3

- The group “01

PARAMETERS GROUPS” is

selected.


Run RB + LOC 618 V

Exit 16:10 Select


4

- A new list of groups is

showed on the display,

with the group “20 Link

Voltage” selected.

- Press until the

group "22 HMI" is select.

Run RB + LOC 618 V

Exit 16:10 Select

20 Link Voltage21 Control22 HMI23 Analog Inputs

5

- The group "22 HMI" is

selected.


Run RB + LOC 618 V

Exit 16:10 Select


6

- The parameter “Day

P0194” is already selected.

- If necessary, set P0194

according to the current day.

Therefore, press “Select”.

- For changing P0194

contents or

.

- Proceed in the same way

for adjusting the parameters

from “Month P0195” to

“Seconds P0199”.

Run RB + LOC 618 V

Exit 16:10 Select

DayP0194: 06MonthP0195: 10

7

- When P0199 is finished,

the Real Time Clock will be

adjusted.

- Press “Exit” (left "soft key").

Run RB + LOC 618 V

Exit 18:11 Select

MinutesP0198: 11SecondsP0199: 34


Run RB + LOC 618 V

Exit 18:11 Select



Run RB + LOC 618 V

Exit 18:11 Select


10- The display returns to the

Monitoring Mode.

Run RB + LOC 618 V

18:11 Menu

400 A618 V380 V

Figure 5.2 - Date and time setting


CFW-11 RB | 5-7

5

5.6 SETTING OF DISPLAY INDICATIONS IN THE MONITORING MODE

Whenever the converter is energized, the display goes to the Monitoring Mode. In order to make it easier the

reading of the main parameters, the keypad (HMI) display can be configured to show them in 3 different modes.

Content of the 3 parameters in numerical form:

Selection of the parameters via P0205, P0206 and P0207. That mode can be seen in the Figure 5.3 on page

5-7.

Loc./Rem. Indication Inactive.

Indication of the time. Adjusted in: P0197, P0198 and P0199.

Run RB + LOC 618V

12:35 Menu

400 A 618 V 380 V

DC Link Voltage in Volts.

Monitoring parameters:- Input Current in Amps.- DC Link Voltage in V.- Line Voltage in V (P0002).

P0205, P0206 and P0207: selection of the parameters that will be shown in the Monitoring Mode.

Function of the right soft key.

Function of the left soft key.

Converter status

- Run

- Ready

- Configuration

- Last Fault: FXXX

- Last Alarm AXXX

- etc.

Real Power:+ Rectifying.- Regenerating.

RB Control.

Figure 5.3 - Monitoring mode screen at the factory setting

Content of the parameters in bar graphs:

Selection of the parameters via P0205, P0206 and/or P0207 is showed in percentage values by means of

horizontal bars. This mode is illustrated in the Figure 5.4 on page 5-7.

The full scale of each parameter is adjusted by means of P0213, P0214 and P0215.

RUN RB + LOC 618 V

12:35 Menu

A

V

V

Monitoring parameters:- Input current.- DC Link Voltage.- Line Voltage in V (P0002).

P0205, P0206 and P0207: selection of the parameters that will be shown in the Monitoring Mode.

100%

77..%

100%

Figure 5.4 - Monitoring mode screen with bar graphs

In order to configure the bar graph monitoring mode, access the parameters P0205, P0206 and/or P0207 and

select the options ended with the symbol "-" (values in the range from 6 to 10). Thus, the respective variable

is configured to be show as a bar graph.

The Figure 5.5 on page 5-8 presented next, illustrates the procedure for the modification of one of the

variables to the bar graph mode.


5-8 | CFW-11 RB

5


1

- Monitoring Mode.

- Press “Menu”

(right "soft key").

Run RB + LOC 618 V

16:10 Menu

380 V618 V400 A

2



selected .

Run RB + LOC 618 V

Exit 16:10 Select


3

- The group “01

PARAMETER GROUPS” is

selected.


Run RB + LOC 618 V

Exit 16:10 Select


4

- A new list of groups is

showed on the display,

with the group “20 Link

Voltage” selected.

- Press until

the group “22 HMI” is

selected.

Run RB + LOC 618 V

Exit 16:10 Select


5

- The group “22 HMI” is

selected.


Run RB + LOC 618 V

Exit 16:10 Select


6

- The parameter “Day

P0194” is already selected.

- Press until

Selecting Sel. Reading

Parâm. 1 P0205”.

Run RB + LOC 618 V

Exit 16:10 Select

DayP0194: 06Month P0195: 10

7

- Parameter “Sel.

Reading Param. 1

P0205” is selected.


Run RB + LOC 618 V

Exit 16:10 Select

LanguageP0201 : EnglishRead Parameter Sel. 1P0205 : Corr. Entr. #

8

- Press until

selecting the option

“[6] Line Voltage -”.

- Press “Save”.

Run RB + LOC 618 V

Exit 16:10 Save

P0205Read Parameter Sel. 1[6] Line Voltage -


Run RB + LOC 618 V

Exit 16:10 Select

LanguageP0201 : EnglishRead Parameter Sel. 1P0205 : Line Voltage -


Run RB + LOC 618 V

Exit 16:10 Select



Exit 16:10 Select

Run RB + LOC 618 V


12

The display returns to the

Monitoring mode with the

Line Voltage indicated by

graph bar.

Run RB + LOC 618 V

16:10 Menu

V 618 V400 A

100 %

Figure 5.5 - Configuration of the monitoring in the bar graph mode

In order to return to the standard Monitoring Mode (numerical), you only have to select the options ended with

the signal “#” (values from 1 to 5) in the parameters P0205, P0206 and/or P0207.

Content of the parameter P0205 in the numerical form with bigger characters:

Program the reading parameters P0206 and P0207 in zero (inactive) and P0205 with value from 1 to 5 (an

option ended with the symbol “#”). Thus, P0205 starts being displayed in bigger characters. The Figure 5.6

on page 5-8 illustrates this monitoring mode.

Run RB + LOC 618 V

11:23 Menu

Content of the parameter defined in P0205, with bigger characters.The parameters P0206 and P0207 must be programmed with 0 (zero).

A 400

Figure 5.6 - Example of screen in the monitoring mode with P0205 in bigger characters

Identification of the Regenerative Converter Model and Accessories

CFW-11 RB | 6-1

6

6 IDENTIFICATION OF THE REGENERATIVE CONVERTER MODEL AND ACCESSORIES

In order to identify the model of the converter, verify the code existent on the product identification labels, located

in the interior of the panel. The figure below shows an example of this label.

Rated data of the power supply (voltage, number of phases, rated currents for operation with normal overload duty (ND) and heavy overload duty (HD), overload currents for 1 min and 3 s and frequency range).

Rated data of the DC Link (voltage, rated current for operation with ND

and HD overload duty, frequency)

Current specifications for operation with heavy overload duty (HD)

Current specifications for operation with normal overload duty (ND)

Maximum ambient temperature around the converterManufacturing date (day/month/year)

UP11 Model Serial NumberWEG part number

Converter net weight

Available certifications

Figure 6.1 - Identification label of CFW-11 RB

Once the converter model identification code is verified, it is necessary to interpret it in order to understand its

meaning. Refer to the table 2.1 present in the section 2.4 of the CFW-11 user’s manual and in the section 2.6

of the CFW-11M RB user’s manual.

6.1 DATA OF THE REGENERATIVE CONVERTER [27]

In this group are the parameters related to the converter information and characteristics, such as converter

model, accessories identified by the control circuit, software version, switching frequency, etc.

P0023 – Software Version

AdjustableRange:

0.00 to 655.35 Factory Setting:

Properties: ro


01 PARAMETER GROUPS

27 Inverter Data

Description:

It indicates the software version installed in the FLASH memory of the microcontroller located on the control card.


6-2 | CFW-11 RB

6

P0027 – Configuration of Accessories 1


AdjustableRange:

0000h to FFFFh Factory Setting:

Properties: ro


01 PARAMETER GROUPS

27 Converter Data

Description:

Those parameters identify by means of a hexadecimal code the accessories that are installed on the control module.

For the accessories installed in the slots 1 and 2 the identification code is informed at the parameter P0027. In case of modules connected in the slots 3, 4 or 5, the code will be shown through the parameter P0028.

The following table shows the codes presented in these parameters regarding the main CFW-11 RB accessories.

Table 6.1 - Identification codes of the CFW-11 RB accessories

Name Description SlotIdentification CodeP0027 P0028

IOA-01Module with 2 14 bit analog inputs, 2 digital inputs, 2 14 bit analog outputs in voltage or current, 2 open collector digital outputs.

1 FD-- ----

IOB-01Module with 2 insulated analog inputs, 2 digital inputs, 2 insulated analog outputs in voltage and current, 2 open collector digital outputs.

1 FA-- ----

MMF-01 FLASH Memory Module. 5 ---- ----(2)

Table 6.2 - Formation of the two first codes of the parameter P0028

Bits7 6 5 4 3 2 1 0

Not

use

d

FLAS

H M

emor

y M

odul

e

Not used 0 0 0 0

2nd Hexadecimal Code 1st Hexadecimal Code

(1) Bit 7: not used, fixed at 0.

(2) Bit 6: indicates the presence of the FLASH memory module (0 = without memory module, 1 = with memory module).

Bit 5: not used, fixed at 0.Bit 4: not used, fixed at 0.

Bits 3, 2, 1 and 0: are fixed at 0000, and always form the code “0” in hexadecimal.

Example: for a converter equipped with the modules IOA-01 and FLASH memory module, the hexadecimal code presented in the parameters P0027 and P0028 is FD00 and 0040 (Table 6.3 on page 6-2).

Table 6.3 - Example of the first two characters of the code showed in P0028 for FLASH memory module

7 6 5 4 3 2 1 0

0 1 0 0 0 0 0 0

4 0


CFW-11 RB | 6-3

6

P0029 – Power Hardware Configuration

AdjustableRange:

Bit 0 to 5 = Rated Current Bit 6 and 7 = Rated Voltage Bit 8 and 9 = ReservedBit 10 = (0)24 V/(1) DC Link Bit 11 = (0)RST/(1) DC Link Bit 12 = ReservedBit 13 = SpecialBits 14 and 15: Reserved

Factory Setting:

Properties: ro


01 PARAMETER GROUPS

27 Inverter Data

Description:

In a similar way than parameters P0027 and P0028, the parameter P0029 identifies the converter model and the present accessories. The codification is formed by the combination of binary digits, and presented in the keypad (HMI) in hexadecimal format.

The bits that compose the code are detailed in the next table.

Table 6.4 - Formation of the parameter code P0029

Bits15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0

1 1 0

Res

erve

d

0 1 0 0

Voltage

00 = 200...240 V01 = 380...480 V10 = 500...600 V11 = 660...690 V

Current

4th Hexadecimal Code 3rd Hexadecimal Code 2nd Hexadecimal Code 1nd Hexadecimal Code

Bits 15, 14 and 13: are fixed in 110.

Bit 12: reserved.

Bit 11: always 0.

Bit 10: not used, always in 1.



Bits 7 and 6: indicate the converter power supply (00 = 200...240 V, 01 = 380...480 V, 10 = 500...600 V,

11 = 660...690 V).

Bits 5, 4, 3, 2, 1 and 0: together with the voltage indication bits (7 and 6), they indicate the converter rated current

(ND). The next table presents the available combinations for these bits.


6-4 | CFW-11 RB

6

Table 6.5 - Codification of the current for the parameter P0029

380 V / 480 V7 6 5 4 3 2 1 0

0 1

1 0 1 0 0 0 600 A1 0 1 0 0 1 1140 A1 0 1 0 1 0 1710 A1 0 1 0 1 1 2280 A1 0 1 1 0 0 2850 A

500 V / 600 V7 6 5 4 3 2 1 0

1 0

1 0 0 1 0 1 470 A1 0 0 1 1 0 893 A1 0 0 1 1 1 1340 A1 0 1 0 0 0 1786 A1 0 1 0 0 1 2232 A

660 V / 690 V7 6 5 4 3 2 1 0

1 1

1 0 0 1 0 1 427 A1 0 0 1 1 0 811 A1 0 0 1 1 1 1217 A1 0 1 0 0 0 1622 A1 0 1 0 0 1 2028 A

Example: for a CFW-11 RB of 600 A, 380…480 V, the hexadecimal code presented in keypad (HMI) for the parameter P0029 is C468 (refer to Table 6.6 on page 6-4).

Table 6.6 - Example of the code at P0029 for a specific converter model

15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0

1 1 0 0 0 1 0 0 0 1 1 0 1 0 0 0

C 4 4 8


CFW-11 RB | 6-5

6

P0295 – ND/HD Rated Current of the Converter

AdjustableRange:

0 = 3.6 A / 3.6 A1 = 5 A / 5 A2 = 6 A / 5 A3 = 7 A / 5.5 A4 = 7 A / 7 A5 = 10 A / 8 A6 = 10 A / 10 A7 = 13 A / 11 A8 = 13.5 A / 11 A9 = 16 A / 13 A10 = 17 A / 13.5 A11 = 24 A / 19 A12 = 24 A / 20 A13 = 28 A / 24 A14 = 31 A / 25 A15 = 33.5 A / 28 A16 = 38 A / 33 A17 = 45 A / 36 A18 = 45 A / 38 A19 = 54 A / 45 A20 = 58.5 A / 47 A21 = 70 A / 56 A22 = 70.5 A / 61 A23 = 86 A / 70 A24 = 88 A / 73 A25 = 105 A / 86 A26 = 427 A / 340 A27 = 470 A / 380 A28 = 811 A / 646 A29 = 893 A / 722 A30 = 1217 A / 969 A31 = 1340 A / 1083 A32 = 1622 A / 1292 A33 = 1786 A / 1444 A34 = 2028 A / 1615 A35 = 2232 A / 1805 A36 = 2 A / 2 A37 = 640 A / 515 A 38 = 1216 A / 979 A39 = 1824 A / 1468 A40 = 2432 A / 1957 A41 = 3040 A / 2446 A42 = 600 A / 515 A43 = 1140 A / 979 A44 = 1710 A / 1468 A45 = 2280 A / 1957 A46 = 2850 A / 2446 A47 = 105 A / 88 A48 = 142 A / 115 A49 = 180 A / 142 A50 = 211 A / 180 A51 = 242 A / 211 A52 = 312 A / 242 A53 = 370 A / 312 A54 = 477 A / 370 A55 = 515 A / 477 A56 = 601 A / 515 A

Factory Setting:

According tothe converter model


6-6 | CFW-11 RB

6

57 = 720 A / 560 A58 = 2.9 A / 2.7 A59 = 4.2 A / 3.8 A60 = 7 A / 6.5 A61 = 8.5 A / 7 A62 = 10 A / 9 A63 = 11 A / 9 A64 = 12 A / 10 A65 = 15 A / 13 A66 = 17 A / 17 A67 = 20 A / 17 A68 = 22 A / 19 A69 = 24 A / 21 A70 = 27 A / 22 A71 = 30 A / 24 A 72 = 32 A / 27 A73 = 35 A / 30 A74 = 44 A / 36 A75 = 46 A / 39 A76 = 53 A / 44 A77 = 54 A / 46 A78 = 63 A / 53 A79 = 73 A / 61 A80 = 80 A / 66 A81 = 100 A / 85 A82 = 107 A / 90 A 83 = 108 A / 95 A84 = 125 A / 107 A85 = 130 A / 108 A86 = 150 A / 122 A87 = 147 A / 127 A88 = 170 A / 150 A89 = 195 A / 165 A90 = 216 A / 180 A91 = 289 A / 240 A92 = 259 A / 225 A93 = 315 A / 289 A94 = 312 A / 259 A95 = 365 A / 315 A96 = 365 A / 312 A97 = 435 A / 357 A98 = 428 A / 355 A99 = 472 A / 388 A100 = 700 A / 515 A101 = 1330 A / 979 A102 = 1995 A / 1468 A103 = 2660 A / 1957 A104 = 3325 A / 2446 A105 = 795 A / 637 A106 = 877 A / 715 A107 = 1062 A / 855 A108 = 1141 A / 943 A109 = 584 A / 504 A110 = 478 A / 410 A111 = 625 A / 540 A112 = 518 A / 447 A113 = 758 A / 614 A114 = 628 A / 518 A


CFW-11 RB | 6-7

6

115 = 804 A / 682 A116 = 703 A / 594 A117 = 760 A / 600 A118 = 760 A / 560 A

Properties: ro


01 PARAMETER GROUPS

27 Converter Data

Description:

This parameter presents the converter rated current for the normal overload duty (ND) and for the heavy overload duty (HD). The converter operating mode, if it is HD or ND, is defined by the content of P0298.

P0296 – Power supply Rated Voltage

AdjustableRange:

0 = 220 / 240 V1 = 380 V2 = 400 / 415 V3 = 440 / 460 V4 = 480 V5 = 500 / 525 V6 = 550 / 575 V7 = 600 V8 = 660 / 690 V

Factory Setting:

According tothe converter model

Properties: cfg


01 PARAMETER GROUPS

27 Converter Data

Description:Adjustment according to the power supply voltage of the regenerative converter.

The allowed adjustable range depends on the model of the regenerative converter as described in the Table 6.7 on page 6-7, which also presents the factory default value.

NOTE!When adjusted via the keypad (HMI), this parameter may change automatically the parameter P0151.

Table 6.7 - P0296 adjustment according to the CFW-11 RB converter modelConverter Model Adjustable Range Factory Setting

200 / 240 V 0 = 200 / 240 V 0

380 / 480 V

1 = 380 V2 = 400 / 415 V3 = 440 / 460 V4 = 480 V

3

500 / 600 V5 = 500 / 525 V6 = 550 / 575 V7 = 600 V

6

660 / 690 V 8 = 660 / 690 V 8


6-8 | CFW-11 RB

6

P0297 – Switching Frequency

AdjustableRange:

0 = 2.5 kHz1 = 5.0 kHz2 = 10.0 kHz3 = 2.0 kHz

Factory Setting:

0

Properties: cfgAccess groups via HMI:

01 PARAMETER GROUPS

27 Converter Data

Description:Refer to the allowed current data for switching frequency, different from the default in the tables available in chapter 8 of the CFW11 RB and CFW-11M RB user’s manual.

The converter switching frequency may be adjusted according to the needs of the application. Higher switching frequency imply in lower acoustic noise in the filter, however, the selection of the switching frequency results in a compromise between the filter acoustic noise, the losses in the converter IGBTs and the maximum allowed currents.

The reduction of the switching frequency reduces the leakage current to the ground, preventing the actuation of the faults F074 (Ground Fault) or F070 (Input overcurrent or short circuit).

P0298 – Application

AdjustableRange:

0 = Normal Duty (ND)1 = Heavy Duty (HD)

Factory Setting:

0

Properties: cfg


01 PARAMETER GROUPS

27 Converter Data

Description:Set the content of this parameter according to the application.

The normal overload duty (ND) defines the maximum current for continuous operation (Inom-ND) and the overload of 110 % during 1 minute.

The heavy overload duty (HD) defines the maximum current for continuous operation (Inom-ND) and the overload of 150 % during 1 minute.

In both cases, it is necessary to use the same drive output converter duty.

The currents Inom-ND and Inom-HD are presented in P0295. For more details regarding these operation Duties, refer to chapter 8 of the CFW11 RB and CFW-11M RB user’s manual.

Settings

CFW-11 RB | 7-1

7

7 SETTINGS

7.1 BACKUP PARAMETERS [04]

The CFW-11 RB BACKUP functions allow saving the converter current parameter contents in a specific memory,

or vice-versa (overwrite the current parameters with the memory content). Besides, there is a function exclusive

for software update, by means of the FLASH Memory Module.

P0204 – Load/Save Parameters

AdjustableRange:

0 = Not Used1 = Not Used2 = Reset P00453 = Reset P00434 = Reset P00445 = Load Default

Factory Setting:

0

Properties: cfg


04 BACKUP PARAMETERS

Description:It allows saving the converter current parameters in an area of the EEPROM memory of the control module or the opposite, loading the parameters with the content of this area. It also allows resetting the Enabled Time (P0043), kVAh (P0044) and Fan Enabled Time (P0045) counters. The Table 7.1 on page 7-1 describes the actions perfor-med by each option.

Table 7.1 - Options of the parameter P0204

P0204 Action0, 1 Not used: no action.

2 Reset P0045: resets the enabled fan hour counter.3 Reset P0043: resets the enabled hour counter.4 Reset P0044: resets the kVAh counter.5 Load Default.

Factory setting (WEG

standard)

Converter current

parameters

P0204 = 5

Figure 7.1 - Parameter transfer

NOTE!When P0204 = 5, the parameters P0296 (Rated voltage), P0297 (Switching frequency) and P0201

(Language), will not be changed by the factory settings.

Settings

7-2 | CFW-11 RB

7

P0318 – Copy Function Memory Card

AdjustableRange:

0 = Inactive 1 = Converter → Memory Card2 = Memory Card → Converter

Factory Setting:

0

Properties: cfg



Description:

This function allows saving the contents of the converter writing parameters in the FLASH Memory Module (MMF), or vice-versa, and can be used to transfer the contents of the parameters from one converter to another.

Table 7.2 - Options of the parameter P0318P0318 Action

0 Inactive: no action.1 Converter → MemCard: transfers the current content of the converter parameters to the MMF.

2MemCard → Converter: transfers the content of the parameters stored in the MMF to the converter control board. After the transfer has been finished, a converter reset occurs. The content of P0318 returns to 0 (zero).

After storing the parameters of the converter in a FLASH Memory Module, it is possible to pass them to another converter through this function. However, if the converters are from different models or with incompatible software versions, the keypad (HMI) will exhibit the message: “FLASH Memory Module with invalid parameters” and will not allow the copy.

NOTE!During the converter operation, the modified parameters are saved in the FLASH Memory Module,

regardless of a user’s command. This ensures that the MMF will always have an updated copy of

the converter parameters, if P0318 = 1.

NOTE!When the converter is powered and the memory module is present, the current parameter contents

is compared with the contents of the parameters saved in the MMF and, in case they are different,

the keypad (HMI) will exhibit the message “FLASH Memory Module with different parameters”,

after 3 seconds the message is replaced by P0318 parameter menu. The user has the option of

overwriting the contents of the memory module (choosing P0318 = 1) or overwriting the converter

parameters (choosing P0318 = 2), or even ignoring the message by programming P0318 = 0.

P0319 – Copy Function HMI

AdjustableRange:

0 = Inactive 1 = Converter → HMI2 = HMI → Converter

Factory Setting:

0

Properties: cfg



Settings

CFW-11 RB | 7-3

7

Description:

The Copy function HMI is similar to the previous function, and is also used to transfer the contents of the parameters from one converter to another (others). The converters must have the same software version. If the versions are different, by programming P0319 = 2, the HMI will show the message: “Incompatible software version”. The content of P0319 returns to zero after removing the message from the HMI.

Table 7.3 - Options of the parameter P0319P0319 Action

0 Inactive: no action.

1Converter → HMI: transfers the current content of the converter parameters to the HMI nonvolatile memory (EEPROM). The converter current parameters remain unchanged.

2 HMI → Converter: transfers the content of the HMI nonvolatile memory (EEPROM) to the converter current parameters.

NOTE!In case the keypad (HMI) had been previously loaded with the parameters from a version “different”

from that of the converter where it is trying to copy the parameters, the operation will not be carried

out and the keypad (HMI) will indicate the fault F082 (Copy Function Fault). It is understood as

“different”, version those ones which are different in “x” or “y”, assuming that the software version

numbers be described as Vx.yz.

Example: version V1.60 → (x = 1, y = 6 and z = 0) previously stored in the keypad HMI.

Converter Version: V1.75 → (x’ = 1, y’ = 7 and z’ = 5)

P0319 = 2 → F082 [(y = 6) → (y’ = 7)]

Converter Version: V1.62 → (x’ = 1, y’ = 6 and z’ = 2)

P0319 = 2 → normal copy [(y = 6) = (y’ = 6)] and [(x = 1) = (x' = 1)]

In order to copy the parameters from one converter to another, one must proceed in the following manner:

1. Connect the keypad (HMI) to the converter from which one wishes to copy the parameters (Converter A).

2. Set P0319 = 1 (Conversation → HMI) to transfer the parameter of the Conversation A to HMI.

3. Press the key right soft key “Save”. P0319 returns automatically to 0 (Inactive) as soon as the transfer is

finished.

4. Disconnect the keypad (HMI) from the converter.

5. Connect the same keypad (HMI) to the converter to which one wants to transfer the parameters (Converter B).

6. Set P0319 = 2 (HMI → Converter) to transfer the content of the keypad (HMI) nonvolatile memory (EEPROM

with the Converter A parameters) to the Converter B.

7. Press the key right soft key “Save”. When P0319 returns to 0 the transfer of the parameters has been finished.

From that moment on the Converters A and B will have parameters with the same content.

Settings

7-4 | CFW-11 RB

7

Note:

In case the converters A and B are not from the same model, verify the values of P0296 (Rated Voltage) and

P0297 (Switching Frequency) at the Converter B.

8. In order to copy the contents of the Converter A parameters to other converters, repeat the same procedures

5 to 7 described previously.

CONVERTERA

Parameters

EEPROM

HMI

CONVERTER → HMI HMI → CONVERTER

EEPROM

HMI

CONVERTERB

Parameters

Figure 7.2 - Copy of the parameters from the “Converter A” to the “Converter B”

NOTE!As long as the keypad (HMI) is performing the reading or writing procedure, it will not be possible

to operate it.

CFW-11 RB | 8-1

8

Used Control

8 USED CONTROL

8.1 USED CONTROL

The regenerative converter (RB) connects to the line trough the input filter. In order to control the power flow

through it and make the line “notice” the installation as a resistive load, it is necessary an appropriate control

in the converter.

The control used in the converter is the vector type oriented by the line to which it is connected.

In this chapter the vector control and its related parameters will be described.

8.2 VECTOR CONTROL

In this control the components are obtained from the apparent current Is (P0003):

Active Current Id: current oriented with the line voltage vector.

Reactive Current Iq: current perpendicular to the active current.

Since these currents are represented by vectors that rotate at the synchronous speed (line), when observed from

a referential in the same synchronous speed (referential transformation), these vectors are represented by their

amplitudes (continuous values over time). Controlling their amplitudes it is possible to control the power flow

through the converter, which simplifies the control.

The active current is related to the real power in the converter, i.e., the power is effectively converted into work.

As the regenerative converter operates in four quadrants, this current can be positive (converter consuming

energy from the line) or negative (converter regenerating energy to the line).

Since the reactive current is related to the reactive power, it is exchanged periodically between the line and the

regenerative converter. If it is positive, the converter presents characteristics of capacitive load to the line. The

current leads in relation to the line voltage. If this current is negative, the converter presents characteristics of

inductive load, the current lags behind the line voltage.

The Figure 8.1 on page 8-7 shows the control block diagram. The line voltages and the currents will be used

for the vector orientation. Since the control is oriented to the line, it is necessary to obtain the amplitude values

of the line voltages in time in order to have the position of the voltage vector in time.

8.3 DC LINK REGULATOR [93]

This group shows the parameters related to the DC Link control of the converter. From the measured voltage

on the DC Link, the control sets the real power flow through the converter.

Used Control

8-2 | CFW-11 RB

8

P0100 – Setpoint Filter

AdjustableRange:

0.00 to 3.00 s Factory Setting:

1.00 s

Properties: Vector


01 PARAMETER GROUPS

21 Control

93 DC Link Regulator

Description:

It sets the time constant for the DC Link reference filter. This filter function is to make a smooth transition between the DC Link value when the converter is disabled until the value set in P0151 (DC Link voltage setpoint) when the converter is enabled.

P0151 – DC Link Voltage Setpoint

AdjustableRange:

It depends on the line voltage. Refer to table 8.1 Factory Setting:

According to table 8.1.

Properties: Vector


01 PARAMETER GROUPS

21 Control


Description:

It defines the DC Link Voltage when the converter is operating. In order to get a good flow regulation in the converter power, this value is adjusted to 15 % above the peak value of the line voltage of the line programmed in P0296. The formula for this calculus is presented in the following equation.

P0151 = 1.15 x √2 x P0296

Table 8.1 - P0151 setting according to the line voltageEffective Line

Voltage of the Line P0296

P0151 Default ValueP0151 Minimum

ValueP 0151 Maximum

Value

200 V / 220 V 358 V 322 V 394 V380 V 618 V 556 V 858 V

400 V / 415 V 650 V 556 V 858 V440 V / 460 V 715 V 556 V 858 V

480 V 780 V 556 V 858 V500 V / 525 V 853 V 768 V 1029 V550 V / 575 V 935 V 768 V 1029 V

600 V 975 V 878 V 1234 V660 V / 690 V 1122 V 878 V 1234 V

P0161 – DC Link Proportional Gain

AdjustableRange:


5.0

CFW-11 RB | 8-3

8

Used Control

P0162 – DC Link Integral Gain

AdjustableRange:


0.009

Properties: Vector


01 PARAMETER GROUPS

21 Control


Description:

The DC Link regulator gains are defined with the factory setting. However, these gains can be set to improve the response of DC Link regulator.

Values for high gains must be avoided, because a very fast transient response of the DC Link control can lead to distortions in the wave form of the converter current causing loss of power factor.

If during a fast acceleration/braking of the motor, in the output drive, there is a DC Link undervoltage/overvoltage fault, the gains can be increased to avoid this condition. In case of a gain setting, it is recommended to start with the setting of the proportional gain (P0161) and repeat the test. If this setting is not sufficient, proceed with the integral gain setting (P0162).

8.4 CURRENT REGULATOR [90]

The setting parameters of the current regulator are presented in this group. These gains will be responsible for

a good dynamic setting of the current and its harmonics distortion.

P0167 – Current Proportional Gain

AdjustableRange:


0.450

P0168 – Current Integral Gain

AdjustableRange:


0.110

Properties: Vector


01 PARAMETER GROUPS

21 Control

90 Current Regulator

Description:

These gains present a factory setting. These values should allow proper operation of the converter for all the available powers.

The increase in the proportional gain (P0167) and reduction in the integral gain (P0168) tends to decrease the distortion of the current. However, if the load has fast transients (braking/acceleration), the gain setting, made to improve the wave form of the current, must be verified. It may cause the converter operating fault during transients.

Used Control

8-4 | CFW-11 RB

8

NOTE!Do not modify the content of these parameters. For more information, refer to WEG.

8.5 REACTIVE REGULATOR [91]

In this group you can set the control of the reactive injection and cause the converter to simulate the line, a

load with inductive characteristics.

P0121- Reactive Current Reference

AdjustableRange:

0.0 to 4500.0 A (*) Factory Setting:

0.0 A

Properties: Vector


01 PARAMETER GROUPS

21 Control

91 Reactive Regulator

Description:

Setting this parameter will cause the converter to process the inductive reactive current, simulating an inductive load.

NOTE!The total current of the converter is the sum of the active and reactive currents, so when the value of this parameter is different from zero, the active current that the converter can process will be proportionally lower.

(*) Depending on the HD current of the converter, where the maximum value is limited in 2 x P0295 (HD).

P0175 – Proportional Gain of the Control of Reactive Injection

AdjustableRange:


2.0

P0176 – Integral Gain of the Control of Reactive Injection

AdjustableRange:


0.020

P0179 – Maximum Reactive

AdjustableRange:

0 to 120 % Factory Setting:

120 %

CFW-11 RB | 8-5

8

Used Control

P0180 – Reactive Generation Point

AdjustableRange:

85 to 110 % Factory Setting:

95 %

Properties: Vector


01 PARAMETER GROUPS

21 Control

91 Reactive Regulator

Description:

With the increase of the line voltage amplitude, it becomes more difficult for the converter to control the power flow until the point it does not occur anymore, causing a converter fault. One way of ensuring that the converter will keep controlling the power flow in this condition is to generate the inductive reactive current needed.

The generation point of the reactive current is defined by the parameter P0180. The value of this parameter is pro-portional to the line voltage according to the equation described below.

Generation Point = P0180 x 1.15 x P0296

Example: considering a condition of the rated system:

Line voltage = 380 V.

DC Link voltage = 618 V.

Rated load.

P0180 = 95 %.

In this condition the converter is able to put an effective line voltage of 437 V in its output. This voltage will be sufficient to maintain the power flux (the power flux is controlled by the difference between the line voltage and the output voltage of the converter, which in this case is 57 V).

1.15 x 380 V = 437 V437 V - 380 V = 57 V

In case the line increases to 410 V, the DC Link voltage will not be changed (618 V), because the DC Link controller will maintain the value set in P0151. Thus, the maximum voltage that can be taken at the VSD output will continue in 437 V. In this new configuration the maximum possible voltage difference between the line and the output voltage of the converter drops to 27 V, which is not sufficient to maintain the same power flux for the load condition, causing the appearing of the alarm A105 on the HMI.

Generation Point = 0,95 x 437 V = 415 V

When the converter output voltage is 95 % of the maximum allowed (415 V), the converter will start to inject reactive in the system, maintaining its stability.

NOTE!The P0180 standard value avoids the injection of reactive current in normal operating conditions.

A value close to 100 % will cause loss of performance during transient loading. A very low value

in P0180 will cause unnecessary injection of reactive current and thus, decrease the total active

current that the converter can operate.

The value of P0179 is the maximum reactive current that the converter will be able to inject in

relation to HD.

Used Control

8-6 | CFW-11 RB

8

8.6 CURRENT LIMITS [92]

The settings of the current limits are in this group.

P0169 – Maximum Rectification Current

AdjustableRange:


125.0 %

P0170 – Maximum Regeneration Current

AdjustableRange:


125.0 %

Properties: Vector


01 PARAMETER GROUPS

21 Control

92 Current Limit

Description:

The converter power flux is oriented at the convention generator-receiver (Positive Power = consuming energy from the line. Negative power = regenerating energy to the line). Thus the parameter P0169 defines which the maximum active current towards converter → line will be (current lagged in 180º of the line voltage). Its value is proportional to the ND current of the converter.

The parameter P0170 defines which the maximum active current towards line → converter will be (current in phase with the line voltage). Its value is proportional to the ND current of the converter.

CFW-11 RB | 8-7

8

Used Control

Ref.

cor.

reat

iva

Max

. rea

ctiv

e =

P01

79M

in. r

eact

ive

= 0

Line

3Ø

P000

2Pre-

char

ge

P000

7IdIq

Iq

Ud

Uac

Ud

Usd

t

Filte

r

Usd

filte

r (A

Ox

= 2

9)

Reac

tive

curr

ent

regu

lato

r

Activ

e cu

rren

t re

gula

tor

DC

Lin

k re

f. vo

ltage

Refe

renc

efil

ter

DC

Lin

k re

g.

P012

1

Usq

PWM

Max

reg

. cur

rent

. = P

0170

Gp

= P

0167

Gp

= P

0167

Gp

= P

0161

Gp

= P

0175

1.15

P010

0

P029

6

P018

0

P015

1

Max

rec

t cur

rent

. = P

0169

Gi =

P01

68

Gi =

P01

68G

i = P

0162

Gi =

P01

76Tr

ansf

.

Tran

sf.Ph

i

Line

vo

ltage

(A

Ox=

1)

Line

volta

ge

I V, I W

UAB

VC

A

N

Usd

filt.

reat

Vcc

Figure 8.1 - Block diagram of the vector control

Used Control

8-8 | CFW-11 RB

8

8.7 START-UP

NOTE!Read all the CFW-11RB user’s manual before installing, powering up or operating the converter.

Sequence for installation, verification, power-up and start-up:

a. Install the converter: according to Chapter 3 Installation and Connection of the CFW-11RB user’s

manual, making all the power and control connections.

b. Prepare the drive and power up the converter: according to the item 5 of the CFW-11RB user’s manual.

c. Set the password P0005 = 5: according to the Section 5.3 ADJUSTMENT OF THE PASSWORD IN P0000

on page 5-2 of this manual.

d. Set the inverter to operate with the application line: through the Menu “Oriented Star-up” access P0317 and change its content to 1, in order to initiate the Oriented Start-up sequence.

The Oriented Start-up routine presents the main parameters in a logical sequence on the HMI.

The setting of these parameters prepares the converter for an operation with the application line. Look at the

sequence step by step in the Figure 8.2 on page 8-9.

The setting of these parameters presented in this operating mode causes the automatic modification of the

content of other parameters and/or internal variables of the converter, as show in Figure 8.2 on page 8-9.

Thus it is obtained a stable operation of the control circuit with suitable values for best performance.

During the Oriented Start-up routine the “Config” (Configuration) status will be indicated on the top left part

of the HMI display.

e. Setting of specific parameters and functions for the application: program the digital inputs and outputs

and analog outputs, according to the application.

CFW-11 RB | 8-9

8

Used Control


1- Monitoring Mode.

- Press “Menu” (right "soft key").

Ready

13:48 Menu

0.0 A0 V0 V

2

- The group “00

ALL PARAMETERS” is already

selected.

Ready

Exit 13:48 Select

00 ALL PARAMETERS01 PARAMETER GROUPS 02 ORIENTED START-UP 03 CHANGED PARAMETERS

3

- The group “01 PARAMETER

GROUPS”, is selected.

Ready

Exit 13:48 Select


4

- The group “02 ORIENTED

START-UP” is then selected.


Ready

Exit 13:48 Select

00 ALL PARAMETERS01 PARAMETER GROUPS 02 ORIENTED START-UP03 CHANGED PARAMETERS

5

- The parameter “Oriented

Start-up P0317: No” is

already selected.


Ready

Exit 13:48 Select

Oriented Start-up P0317: No

6

- The content of

“P0317 = [000] No”

is shown.

Ready

Exit 13:48 Save

P0317Oriented Start-up [000] No

7

- The content of the

parameter is changed to

“P0317 = [001] Yes”.

- Press “Save”.

Ready

Exit 13:48 Save

P0317Oriented Start-up [001] Yes

8

- At this time the routine of

Oriented Start-up is started and

the status “Config” is indicated

at the top left of the keypad

(HMI).

- The parameter “Language

P0201: English” is already

selected.

- If necessary, change the

language by pressing “Select”,

and then or

to select the language and

press “Save”.

Config RB ± LOC 513

Reset 13:48 Select

LanguageP0201: English

9

- Set the content of P0263 by pressing “Select”. - Then press until selecting the desired option.

- Then press "Save".

Config

Reset 13:48 Select

Language P0201: EnglishDI1 FunctionP0263: General Enable

10


content of P0296 according to

the used line voltage. For this,

press “Select”. This change will

affect P0151.

Config

Reset 13:48 Select

DI1 FunctionP0263: General EnableLine Rated VoltageP0296: 440 - 460 V

11- If necessary, set the content

of P0297.

Config

Reset 13:48 Select

Line Rated VoltageP0296: 440 - 460 VSwitching FrequencyP0297: 2.5 kHz

12

For this, press “Select”.


content of P0298 according

to the converter application.

For this, press “Select”. This

change will affect P0169,

P0170. The time and level of

actuation of the IGBT overload

protection will also be affected.

Config

Reset 13:48 Select

Switching FrequencyP0297: 2.5 kHzApplicationP0298: Normal Duty (ND)

Figure 8.2 - Oriented Start-up

Used Control

8-10 | CFW-11 RB

8

CFW-11 RB | 9-1

Digital and Analog Inputs and Outputs

9

9 DIGITAL AND ANALOG INPUTS AND OUTPUTS

9.1 I/O CONFIGURATION [05]

9.1.1 Analog Outputs [24]

Two analog outputs (AO1 and AO2), are available in the CFW-11 RB standard configuration, and two other

(AO3 and AO4) can be added with the Accessory IOA-01. The parameters related to these outputs are described

below.

P0014 – AO1 Value

P0015 – AO2 Value

AdjustableRange:


P0016 – AO3 Value

P0017 – AO4 Value

AdjustableRange:

-100.00 to 100.00 % Factory Setting:

Properties: ro


05 I/O CONFIGURATION or 01 PARAMETER GROUPS

24 Analog Outputs 24 Analog Outputs

Description:

Those read-only parameters indicate the value of the analog outputs AO1 to AO4 in percentage of the full scale. The indicated values are those obtained after the multiplication by the gain. Check the description of the parameters P0251 to P0261.


9-2 | CFW-11 RB

9

P0251 – AO1 Function


AdjustableRange:

0 = Not Used1 = Line Voltage2 = Not Used3 = DC Link Voltage4 = Input Current5 = Reactive Current6 = Active Current7 = Input Power

Factory Setting:

P0251 = 3P0254 = 4



AdjustableRange:

0 to 7 = Refer to options in P0251 8 = Not Used 9 = Not Used 10 = Not Used 11 = Not Used 12 = Vab13 = Vca14 = Ualpha15 = Ubeta16 = Phi17 = Isa18 = Isb19 = Ia20 = Ib21 = COSPHI22 = SINPHI23 = U_Diff24 = IsdRef25 = Ulinksol_Fil26 = IsqRef227 = Usd28 = Usq29 = UsdFilt30 = UD_DIFF

Factory Setting:

P0257 = 3P0260 = 4

Properties:




Description:

These parameters set the functions of the analog outputs. Note: The output feature 11 other variables for WEG’s use.

CFW-11 RB | 9-3


9

P0252 – AO1 Gain

P0255 – AO2 Gain

P0258 – AO3 Gain

P0261 – AO4 Gain

AdjustableRange:


1.000

Properties:




Description:

Set the gain of the analog outputs. Refer to Figure 9.1 on page 9-3.

FunctionAO1 - P0251AO2 - P0254AO3 - P0257AO4 - P0260

AOx

Input Power

Active Current

Reactive Current

Input Current

DC Link Voltage

Line Voltage GainAO1 - P0252AO2 - P0255AO3 - P0258AO4 - P0261

SignalAO1 - P0253AO2 - P0256AO3 - P0259AO4 - P0262

ValueAO1 - P0014AO2 - P0015AO3 - P0016AO4 - P0017

Figure 9.1 - Block diagram of the analog outputs

Table 9.1 - Full scale

Scale of the Analog Outputs IndicationsVariable Full Scale

Line Voltage 1.1 x P0296DC Link Voltage Level E01Input Current 2.0 x InomHD

Reactive Current P0179xInomHD

Active Current 2.0 x InomHD

Input Power 1.5 x √3 x P0295 x P0296P0296 Level E01

0 = 200 / 240 V 400 V1 = 380 V

800 V2 = 400 / 415 V3 = 440 / 460 V4 = 480 V5 = 500 / 525 V

1000 V6 = 550 / 575 V7 = 600 V8 = 660 / 690 V 1200 V

(*) When the signal is inverse (10 to 0 V, 20 to 0 mA or 20 to 4 mA)

the values in the table become the beginning of the scale.


9-4 | CFW-11 RB

9

P0253 – AO1 Signal Type


AdjustableRange:

0 = 0 to 10 V / 20 mA1 = 4 to 20 mA2 = 10 V / 20 mA to 03 = 20 to 4 mA

Factory Setting:

0



AdjustableRange:

0 = 0 to 20 mA1 = 4 to 20 mA2 = 20 mA to 03 = 20 to 4 mA4 = 0 to 10 V5 = 10 to 0 V6 = -10 to +10 V

Factory Setting:

4

Properties: cfg




Description:

Those parameters configure if the analog output signal will be in current or voltage with direct or reverse reference.

Besides setting those parameters, it is also necessary to position the “DIP switches” of the Control Board or the Ac-cessory Board IOA, according to Table 9.2 on page 9-4, Table 9.3 on page 9-4 and Table 9.4 on page 9-4.

Table 9.2 - “DIP switches” related to the analog outputs

Parameter Output Switch LocationP0253 AO1 S1.1

Control BoardP0256 AO2 S1.2P0259 AO3 S2.1

IOAP0262 AO4 S2.2

Table 9.3 - Configuration of the analog outputs AO1 and AO2 signals

P0253, P0256 Output Signal Switch Position - S1.X0 (0 to 10) V / (0 to 20) mA On/Off1 (4 to 20) mA Off2 (10 to 0) V / (20 to 0) mA On/Off3 (20 to 4) mA Off

Table 9.4 - Configuration of the analog outputs AO3 and AO4 signals

P0259, P0262 Output Signal Switch Position - S2.X0 0 to 20 mA Off1 4 to 20 mA Off2 20 to 0 mA Off3 20 to 4 mA Off4 0 to 10 V Off5 10 to 0 V Off6 -10 to +10 V On

CFW-11 RB | 9-5


9

For AO1 and AO2, when current signals are used, the switch corresponding to the desired output must be set in the “OFF” position.

For AO3 and AO4, when current signals are used, the outputs AO3 (I) and AO4 (I) must be used. For voltage signals, use the outputs AO3 (V) and AO4 (V). The switch corresponding to the desired output must be set in “ON” only in order to use the range from -10 to +10 V.

9.1.2 Digital Inputs [25]

To use the digital inputs, the CFW-11 RB has 6 ports in the standard version of the product, and other 2 can

be added with the accessories IOA-01 and IOB-01. The parameters that set these inputs are presented below.

P0012 – DI8 to DI1 Status

AdjustableRange:

Bit 0 = DI1Bit 1 = DI2 Bit 2 = DI3 Bit 3 = DI4 Bit 4 = DI5 Bit 5 = DI6 Bit 6 = DI7 Bit 7 = DI8

Factory Setting:

Properties: ro



25 Digital Inputs 25 Digital Inputs

Description:

By means of this parameter it is possible to visualize the status of the 6 control board digital inputs (DI1 to DI6) and of the 2 accessory board digital inputs (DI7 and DI8).

The indication is done by means of the numbers 1 and 0, representing, respectively, the “Active” and “Inactive” status of the inputs. The status of each input is considered as one digit in the sequence, where DI1 represents the least significant digit.

Example: in case the sequence 10100010 in presented on the keypad (HMI), it will correspond to the following status of the DIs:

Table 9.5 - Status of the digital inputs

DI8 DI7 DI6 DI5 DI4 DI3 DI2 DI1

Active(+24 V)

Inactive(0 V)

Active(+24 V)

Inactive(0 V)

Inactive(0 V)

Inactive(0 V)

Active(+24 V)

Inactive(0 V)


9-6 | CFW-11 RB

9

P0263 – DI1 Function








AdjustableRange:

0 = Not Used1 = Not Used2 = General Enable3 to 17 = Not Used18 = No External Alarm19 = No External Fault20 = Reset21 to 31 = Not Used

Factory Setting:

P0263 = 2P0264 = 0P0265 = 0P0266 = 0P0267 = 0P0268 = 0P0269 = 0P0270 = 0

Properties: cfg



25 Digital Inputs 25 Digital Inputs

Description:

Those parameters allow configuring the digital input function, according to the related adjustable range.

- No External Alarm: this function will indicate “External Alarm” (A090) on the keypad (HMI) display when the programmed digital input is open (0 V). If +24 V is applied in the input, the alarm message will automatically disappear from the keypad (HMI) display. The converter operation is not affected by the status of the programmed input in 18 = No External Alarm.

CFW-11 RB | 9-7


9

Figure 9.2 - (a) to (c) Details on the operation of the functions of the digital inputs

DIx Open

Time

Time24 V

Open

24 V

Time

Time

DIx

DC Link voltage DC Link voltage

b) NO EXTERNAL FAULT a) GENERAL ENABLE

With fault

P0151 P0151

1,35 x P00021,35 x P0002

Time24 V

Time

Time

24 V

No fault

Reset

DIx - Reset Open

Converter status (*)

(*) The condition that generated the persistent error

c) RESET

9.1.3 Digital / Relay Outputs [26]

As standard, the CFW-11 RB has 3 relay digital outputs on its control board, and other 2 other digital outputs

of the open collector type that can be added with the accessories IOA-01 or IOB-01. The next parameters

configure the functions related to those outputs.

P0013 – DO5 to DO1 Status

AdjustableRange:

Bit 0 = DO1Bit 1 = DO2Bit 2 = DO3Bit 3 = DO4Bit 4 = DO5

Factory Setting:

Properties: ro



26 Digital Outputs 26 Digital Outputs

Description:

By means of this parameter it is possible to visualize the status of the 3 control board digital outputs (DO1 to DO3) and of the 2 optional board digital outputs (DO4 and DO5).

The indication is done by means of the numbers "1" and "0", representing, respectively, the “Active” and “Inactive” status of the outputs. The status of each output is considered as one digit in the sequence, where DO1 represents the least significant digit.


9-8 | CFW-11 RB

9

Example: in case the sequence 00010010 in presented on the keypad (HMI), it will correspond to the following status of the DOs:

Table 9.6 - Status of the digital outputs

DO5 DO4 DO3 DO2 DO1

Active(+24 V)

Inactive(0 V)

Inactive(0 V)

Active(+24 V)

Inactive(0 V)

P0275 – DO1 Function (RL1)

AdjustableRange:

0 to 24 = Not Used25 = Preload26 to 35 = Not Used

Factory Setting:

P0275 = 25

Properties: ro



P0278 – DO4 Function

P0279 – DO5 Function

AdjustableRange:

0 to 10 = Not Used11 = Run12 = Ready13 = No Fault14 to 20 = Not Used21 = Rectifying (+)22 to 24 = Not Used25 = Preload OK26 to 34 = Not Used35 = No Alarm

Factory Setting:

P0276 = 11P0277 = 13P0278 = 0 P0279 = 0

Properties:



26 Digital Outputs 26 Digital Outputs

Description:They program the function of the digital outputs, according to the options presented previously.

When the condition declared by the function is true, the digital output will be activated.

Some additional notes regarding the Digital Outputs and Relay Outputs are presented next.

- Not used: it means that the digital outputs will always remain in a resting state, i.e., DOx = open transistor and/or relay with the coil not energized.

- Preload OK: it means that the DC Link Voltage is above the preload voltage level.

- Run: it corresponds to a enabled converter. In this moment the IGBTs are to commutating, and the motor may be at any speed, including zero.

- Ready: converter with no fault and no undervoltage.

CFW-11 RB | 9-9


9

- No fault: it means that the converter is not disabled by any type of fault.

- Rectifying (+): - ON = Rectifying and OFF = Regenerating.

Relay/Transistor

ON = rectifying

OFF = regeneratingOFF

Id (%)

+2,5

- 2,5

- No Alarm: it means that the converter is not in the alarm condition.


9-10 | CFW-11 RB

9

CFW-11 RB | 10-1

10

Faults and Alarms

10 FAULT AND ALARMS

The troubleshooting structure of the converter is based on the fault and alarm indication.

In a fault event, the IGBTs will be blocked and the DC Link Voltage will drop to the voltage level defined by:

1.35 x P0002 (V).

The alarm works as a warning to the user about critical operating conditions and that a fault may occur if the

situation does not change.

Refer to the chapter 6 of the CFW-11 RB user’s manual to obtain more information regarding Faults and Alarms.

10.1 PROTECTIONS [28]

The parameters regarding the motor and the converter protections are in this group.

P0030 – U Arm IGBT Temperature

P0031 – V Arm IGBT Temperature

P0032 – W Arm IGBT Temperature

P0034 – Internal Air Temperature

P0035 – Air Temperature Control Board

AdjustableRange:

-20.0 to 150.0 ° Factory Setting:

Properties: ro


01 PARAMETER GROUPS or 07 READ ONLY PARAMETERS

28 Protections

Description:

These parameters present, in Celsius degrees, the temperatures of the heatsink on the U, V and W arms (P0030, P0031 and P0032), internal air (P0034) and control board (P0035).

They are useful to monitor the temperature on the main converter sections in case of an occasional converter overheating.

P0340 – Auto-Reset Time

AdjustableRange:

0 to 255 s Factory Setting:

0 s

Properties:


01 PARAMETER GROUPS

28 Protections

Description:

Faults and Alarms

10-2 | CFW-11 RB

10

When a fault occurs, the converter may reset itself automatically after the time set in P0340 has elapsed.

NOTE!The faults F051, F054, F057, F301, F304, F307, F310, F313, F316, F319, F322, F325,

F328, F331, F334, F337, F340 and F343 allow a conditional Reset, i.e., the Reset will only

occur if the temperature returns to the normal operating range.

If after performing the auto-reset, the same fault is repeated for three times consecutively, the auto-reset function will be disabled. A fault is considered consecutive if it happens again within 30 seconds after the auto-reset is performed.

Therefore, if a fault occurs four times consecutively, the converter will remain disabled (general disable) and the fault will continue being indicated.

If P0340 ≤ 2, auto-reset will not occur.

P0343 – Ground Fault Configuration

AdjustableRange:

0 = Off1 = On

Factory Setting:

0

Properties: cfg


01 PARAMETER GROUPS

28 Protections

Description:

This parameter enables the Ground Fault Detection, which will be responsible for generating the fault F074 (Ground Fault).

P0352 – Fan Configuration

AdjustableRange:

0 = Heatsink fan and internal fan are OFF1 = Heatsink fan and internal fan are ON2 = Heatsink fan and internal fan are controlled via software3 = Heatsink fan is controlled via software and internal fan is OFF4 = Heatsink fan is controlled via software and internal fan is ON5 = Heatsink fan is ON and internal fan is OFF6 = Heatsink fan is ON and internal fan is controlled via software 7 = Heatsink fan is OFF and internal fan is ON8 = Heatsink fan is OFF and internal fan is controlled via software 9 = Heatsink fan and internal fan are controlled via software (*)

10 = Heatsink fan is controlled via software and internal fan is OFF (*)

11 = Heatsink fan is controlled via software and internal fan is ON (*)

12 = Heatsink fan is ON and internal fan is controlled via software (*)

13 = Heatsink fan is OFF and internal fan is controlled via software (*)

Factory Setting:

2

Properties: cfg


01 PARAMETER GROUPS

28 Protections

Description:

The CFW-11 RB is equipped with fans in the heatsink and in some models, with an internal fan, and their activation will be controlled by setting the parameter P0352.

The options available for the setting of this parameter are the following:

CFW-11 RB | 10-3

10

Faults and Alarms


P0352 Action0 = HS-OFF, INT-OFF Heatsink and internal fans are always OFF.1 = HS-ON, INT-ON Heatsink and internal fans are always ON.2 = HS-CT, INT-CT Heatsink and internal fans are controlled via software.3 = HS-CT, INT-OFF Heatsink fan is controlled via software and internal fan is always OFF.4 = HS-CT, INT-ON Heatsink fan is controlled via software and internal fan is always ON.

5 = HS-ON, INT-OFF Heatsink fan is always ON and internal fan is always OFF.

6 = HS-ON, INT-CT Heatsink fan is always ON and internal fan is controlled via software.

7 = HS-OFF, INT-ON Heatsink fan is always OFF and internal fan is always ON.

8 = HS-OFF, INT-CT Heatsink fan is always OFF and internal fan is controlled via software.

9 = HS-CT, int-CT * Heatsink and internal fans are controlled via software. (*)

10 = HS-CT, int-OFF * Heatsink fan is controlled via software and internal fan is always OFF. (*)

11 = HS-CT, int-ON * Heatsink fan is controlled via software and internal fan is always ON. (*)

12 = HS-ON, int-CT * Heatsink fan is always ON and internal fan is controlled via software. (*)

13 = HS-OFF, int-CT * Heatsink fan is always OFF and internal fan is controlled via software. (*)

(*) The fans will not turn on for one minute after the power-on or after a fault reset.

A delay of fifteen seconds was introduced to turn on (off) the fan after it has been turned off (on).

P0353 – Overtemperature Configuration in the IGBTs

AdjustableRange:

0 = IGBTs: fault and alarm1 = IGBTs: fault and alarm2 = IGBTs: fault, Internal air3 = IGBTs: fault, Internal air4 = IGBTs: fault and alarm (*)

5 = IGBTs: fault and alarm (*)

6 = IGBTs: fault, Internal air (*)

7 = IGBTs: fault, Internal air (*)

Factory Setting:

0

Properties: cfg


01 PARAMETER GROUPS

28 Protections

Description:

The overtemperature protection is carried out by means of the temperature measurement on the NTCs sensors of the IGBTs, being able to generate alarms and faults.

In order to configure the desired protection, set P0353 according to the Table 10.2 on page 10-3.


P0353 Action0 = HS-F/A, AIR-F/A Enables faults (F051, F054, F057 and F153) – IGBT Overtemperature and Internal air Overtemperature.

Enables alarms (A050, A053, A056 and A152) – IGBT high temperature and internal air high temperature.

1 = HS-F/A, AIR-F Enables faults (F051, F054, F057 and F153) - IGBT Overtemperature and Internal air Overtemperature.Enables alarm (A050, A053, A056) – IGBT high temperature.

2 = HS-F, AIR-F/A Enables faults (F051, F054, F057) - IGBT Overtemperature. Enables alarms (A050, A053, A056 and A152) - IGBT high temperature and internal air high temperature.

3 = HS-F, AIR-F Enables faults (F051, F054, F057 and F153) - IGBT Overtemperature and Internal air Overtemperature.4 = HS-F/A, AIR-F/A * Enables faults (F051, F054, F057 and F153) – IGBT Overtemperature and Internal air Overtemperature.

Enables alarms (A050, A053, A056 and A152) – IGBT high temperature and internal air high temperature. (*)

5 = HS-F/A, AIR-F * Enables faults (F051, F054, F057 and F153) - IGBT Overtemperature and Internal air Overtemperature.Enables alarm (A050, A053, A056) – IGBT high temperature. (*)

6 = HS-F, AIR-F/A * Enables faults (F051, F054, F057) - IGBT Overtemperature. Enables alarms (A050, A053, A056 and A152) - IGBT high temperature and internal air high temperature. (*)

7 = HS-F, AIR-F * Enables faults (F051, F054, F057 and F153) - IGBT Overtemperature and Internal air Overtemperature. (*)

(*) Disable alarm (A155) and fault (F156).

Faults and Alarms

10-4 | CFW-11 RB

10

P0354 – Heatsink Fan Protection Configuration

AdjustableRange:

0 = Alarm1 = Fault

Factory Setting:

1

Properties: cfg


01 PARAMETER GROUPS

28 Protections

Description:

This parameter allows setting whether a fault or an alarm should take place when the heatsink fan reaches ¼ of therated speed. If set to 1, the fault F179 will occur and the inverter will be disabled. If set to 0, the alarm A178 willoccur and the inverter won't be disabled.

P0356 – Dead Time Compensation

AdjustableRange:

0 = Off1 = On

Factory Setting:

1

Properties: cfg


01 PARAMETER GROUPS

28 Protections

Description:

This parameter must be always kept in 1 (On). Only in special maintenance cases the value 0 (Off) can be used.

P0357 – Line Phase Loss Time

AdjustableRange:

0.01 to 3.00 s Factory Setting:

2.00 s

Properties:


01 PARAMETER GROUPS

28 Protections

Description:

It configures the time for the phase loss indication (F006).

P0360– Temperature Imbalance Configuration

AdjustableRange:

0 = Fault/Alarm1 = Fault

Factory Setting:

0

Properties: Frame H and cfg


01 PARAMETER GROUPS

28 Protections

Description:

This parameter allows choosing whether showing or not the alarm of temperature imbalance of the power modules.

CFW-11 RB | 10-5

10

Faults and Alarms

If defined as 1, only fault F062 will occur.This fault is shown in three conditions:- The temperature difference between IGBT modules of the same phase (U, V and W) is above 15 °C (59 ° F).- The temperature difference between IGBT modules of different phases (U and V, U and W, V and W) is above20 °C (68 ° F).- The temperature difference between rectifier modules of different phases (R and S, R and T, S and T) is above20 °C (68 ° F).

If defined as 0, besides fault F062, alarm A417 will also be shown.The alarm will be shown in three conditions:- The temperature difference between IGBT modules of the same phase (U, V and W) is above 10 °C (50 ° F).- The temperature difference between IGBT modules of different phases (U and V, U and W, V and W) is above10 °C (50 ° F).- The temperature difference between rectifier modules of different phases (R and S, R and T, S and T) is above10 °C (50 ° F).

P0800 – Temperature U-B1/IGBT U1

P0801 – Temperature V-B1/IGBT V1

P0802 – Temperature W-B1/IGBT W1




AdjustableRange:

-20.0 to 150.0 °C Factory Setting:

Properties: CFW11 M, Frame H and ro



28 Protections

Description:

These reading parameters indicate, in Celsius degrees (ºC), the internal temperature of the IGBTs of each phase. In a modular drive, this information is shown for each Book, and for frame H it is shown for each IGBT module.The indication resolution is 0.1ºC (32.18 ºF).

P0806 – Temperature U -B3/IGBT U3






Faults and Alarms

10-6 | CFW-11 RB

10




AdjustableRange:

-20.0 to 150.0 °C Factory Setting:

Properties: CFW11 M and ro



28 Protections

Description:

These reading parameters indicate, in Celsius degrees (ºC), the internal temperature of the IGBTs of each phase. In a modular drive, this information is shown for each Book, and for frame H it is shown for each IGBT module.The indication resolution is 0.1ºC (32.18 ºF).

P0815 – Current U-B1/IGBT U1

P0816 – Current V-B1/IGBT V1

P0817 – Current W-B1/IGBT W1




AdjustableRange:

-1000.0 to 2000.0 A Factory Setting:

Properties: CFW11 M, Frame H and ro


01 PARAMETER GROUPS

28 Protections

Description:

This reading parameter indicates the current (A) of the IGBTs of each phase. In a modular drive, this information isshown for each Book, and for frame H it is shown for each IGBT module.







CFW-11 RB | 10-7

10

Faults and Alarms




AdjustableRange:

-1000.0 to 2000.0 A Factory Setting:



01 PARAMETER GROUPS

28 Protections

Description:

This reading parameter indicates the current (A) of the IGBTs of each phase. In a modular drive, this information isshown for each Book, and for frame H it is shown for each IGBT module.

P0832 – Digital Input DIM1 Function

P0833 – Digital Input DIM2 Function

AdjustableRange:

0 = Not Used1 = External Fault2 = Refrigeration Fault

Factory Setting:

0

Properties: CFW11 M


01 PARAMETER GROUPS or 01 PARAMETER GROUPS

28 Protections 25 Digital Inputs

Description:

These parameters allow configuring the digital inputs DIM1 and DIM2 with the type of fault to be detected. When the selected fault occurs, its code will be displayed on the HMI and the converter will be disabled.

P0834 – DIM1 and DIM2 Status

AdjustableRange:

Bit 0 = DIM1 Bit 1 = DIM2

Factory Setting:




25 Digital Inputs

Description:

Using this parameter, it is possible to view the 2 digital output status of the Modular Drive RB interface board .

The indication is done by means of the numbers 0 or 1, representing, respectively, the status “No Fault” and “With Fault” of the inputs.

The status of each input is considered as one digit in the sequence, where DIM1 represents the least significant digit.

For further information, refer to the CFW-11M RB user’s manual.

Faults and Alarms

10-8 | CFW-11 RB

10

CFW-11 RB | 11-1

11

Reading Parameters [07]

11 READING PARAMETERS [07]

In order to simplify the view of the main converter reading variables, you may directly access the

group[07] – “Reading Parameters”.

It is important to point out that all the parameters of this group can only be viewed on the HMI display, and

they do not allow changes by the user.

P0002 – Line Voltage

AdjustableRange:

0 to 2000 V Factory Setting:

Properties: ro


07 READ ONLY PARAMETERS

Description:

This parameter indicates the value of the line voltage of the power supply, read by the synchronism circuit on the sections (A, B, C), for further details, refer to Figure 3.1 on page 3-1.

P0003 – Input Current

AdjustableRange:

0.0 to 4500.0 A Factory Setting:

Properties: ro



Description:

It indicates the converter input current in Amp (A).

P0004 – DC Link Voltage

AdjustableRange:


Properties: ro



Description:

It indicates the DC Link direct current voltage in Volts (V).


11-2 | CFW-11 RB

11

P0006 – Converter Status

AdjustableRange:

0 = Ready1 = Run 2 = Undervoltage3 = Fault4 = Configuration

Factory Setting:

Properties: ro



Description:

It indicates one of the five possible converter status. The description of each status is presented in the Table 11.1 on page 11-2.

In order to facilitate the visualization, the converter status is also showed on the top left corner of the keypad (HMI) (Figure 5.3 on page 5-7 – Section 5.6 SETTING OF DISPLAY INDICATIONS IN THE MONITORING MODE on page 5-7). In the case of the status 2 and 4, the presentation is done in an abbreviated form, as follows:

Table 11.1 - Description of the converter status

StatusAbbreviated Form

Presented on the Keypad (HMI) Top Left Corner

Description

Ready Ready It indicates that the converter is ready to be enabled.Run Run It indicates that the converter is enabled.

Undervoltage Sub It indicates that the converter is with insufficient line voltage for operation (undervoltage), and does not accept enabling commands.

Fault Fxxx, where xxx is the number of the occurred fault

It indicates that the converter is in the fault status.

Configuration Config It indicates that the converter is in the Oriented Start-up routine.

P0007 – Input Voltage

AdjustableRange:


Properties: ro



Description:

It indicates the line voltage at the converter input, in Volts (V) after the input filter on the sections R, S and T. For further details, refer to Figure 3.1 on page 3-1.

P0010 – Input Power

AdjustableRange:

0.0 to 6553.5 kVA Factory Setting:

Properties: ro



CFW-11 RB | 11-3

11


Description:

It indicates the instantaneous input power of the converter in kilovoltampere (kVA).

NOTE!The value indicated in this parameter is calculated indirectly, and should not be used to measure

the energy consumption.

P0012 – DI8 to DI1 Status

Refer to the Item 9.1.2 Digital Inputs [25] on page 9-5.

P0013 – DO5 to DO1 Status

Refer to the Item 9.1.3 Digital / Relay Outputs [26] on page 9-7.

P0014 – AO1 Value

P0015 – AO2 Value

P0016 – AO3 Value

P0017 – AO4 Value

Refer to the Item 9.1.1 Analog Outputs [24] on page 9-1.

P0023 - Software Version

For further details, refer to the Section 6.1 DATA OF THE REGENERATIVE CONVERTER [27] on page 6-1.



P0029 – Power Hardware Configuration

Refer to the Section 6.1 DATA OF THE REGENERATIVE CONVERTER [27] on page 6-1.

P0030 – U Arm IGBT Temperature

P0031 – V Arm IGBT Temperature

P0032 – W Arm IGBT Temperature

P0034 – Internal Air Temperature

P0035 – Air Temperature Control Board

Refer to the Section 10.1 PROTECTIONS [28] on page 10-1.


11-4 | CFW-11 RB

11

P0036 – Fan Speed

P0042 – Time Powered

AdjustableRange:

0 to 65535 h Factory Setting:

Properties: ro



Description:

It indicates the total number of hours that the converter remained powered.

This value is kept even when the converter is disconnected.

P0043 – Time Enabled

AdjustableRange:

0.0 to 6553.5 h Factory Setting:

Properties: ro



Description:

It indicates the total number of hours that the converter remained enabled.

It indicates up to 6553.5 hours, and then it returns to zero.

By setting P0204 = 3, the value of the parameter P0043 is reset to zero.


P0044 – kVAh Counter

AdjustableRange:

0 to 65535 kVAh Factory Setting:

Properties: ro



Description:

It indicates the energy consumed by the converter.

It indicates up to 65535 kVAh hours, and then it returns to zero.



CFW-11 RB | 11-5

11


NOTE!The value indicated in this parameter is calculated indirectly, and should not be used to measure

the energy consumption.

P0045 – Fan Enabled Time

AdjustableRange:

0 to 65535 h Factory Setting:

Properties: ro



Description:

It indicates the total number of hours that the heatsink fan remained connected.

It indicates up to 65535 hours, and then it returns to zero.



P0048 – Present Alarm

P0049 – Present Fault

AdjustableRange:


Properties: ro



Description:

It indicates the alarm (P0048) or the fault (P0049) number that may occasionally be present on the converter.

In order to understand the meaning of the codes used for faults and alarms, refer to section 10 of this manual and the chapter 6 of the CFW11 RB or CFW-11M RB user’s manual.

11.1 FAULT HISTORY [06]

In this group are described the parameters that record the last fault occurred in the converter, together with

other relevant information for the fault interpretation, as date, time, etc.

NOTE!If the fault occurs simultaneously with the CFW-11 RB power up or Reset, the parameters regarding

this fault, as date, time, etc, may contain invalid information.


11-6 | CFW-11 RB

11

P0050 – Last Fault

P0054 – Second Fault

P0058 – Third Fault

P0062 – Fourth Fault

P0066 – Fifth Fault

P0070 – Sixth Fault

P0074 – Seventh Fault

P0078 – Eighth Fault

P0082 – Ninth Fault

P0086 – Tenth Fault

AdjustableRange:


Properties: ro


06 FAULT HISTORY

Description:

They indicate the occurrence codes from the last to the tenth fault.

The recording system is the following:

Fxxx → P0050 → P0054 → P0058 → P0062 → P0066 → P0070 → P0074 → P0078 → P0082 → P0086

CFW-11 RB | 11-7

11


P0051 – Last Fault Day/Month

P0055 – Second Fault Day/Month

P0059 – Third Fault Day/Month

P0063 – Fourth Fault Day/Month

P0067 – Fifth Fault Day/Month

P0071 – Sixth Fault Day/Month

P0075 – Seventh Fault Day/Month

P0079 – Eighth Fault Day/Month

P0083 – Ninth Fault Day/Month

P0087 – Tenth Fault Day/Month

AdjustableRange:

00/00 to 31/12 Factory Setting:

Properties: ro


06 FAULT HISTORY

Description:

They indicate the day and month from the last to the tenth fault occurrence.


11-8 | CFW-11 RB

11

P0052 – Last Fault Year

P0056 – Second Fault Year

P0060 – Third Fault Year

P0064 – Fourth Fault Year

P0068 – Fifth Fault Year

P0072 – Sixth Fault Year

P0076 – Seventh Fault Year

P0080 – Eighth Fault Year

P0084 - Ninth Fault Year

P0088 – Tenth Fault Year

AdjustableRange:


Properties: ro


06 FAULT HISTORY

Description:

They indicate the year from the last to the tenth fault occurrence.

P0053 – Last Fault Time

P0057 – Second Fault Time

P0061 – Third Fault Time

P0065 – Fourth Fault Time

P0069 – Fifth Fault Time

P0073 – Sixth Fault Time

P0077 – Seventh Fault Time

P0081 – Eighth Fault Time

CFW-11 RB | 11-9

11


P0085 – Ninth Fault Time

P0089 – Tenth Fault Time

AdjustableRange:

00:00 to 23:59 Factory Setting:

Properties: ro


06 FAULT HISTORY

Description:

They indicate the time from the last to the tenth fault occurrence.

P0090 – Current at the Moment of the Last Fault

AdjustableRange:


Properties: ro


06 FAULT HISTORY

Description:

It is the record of the current supplied by the converter (P0003) at the moment of the last fault occurrence.

P0091 – DC Link Voltage at the Moment of the Last Fault

AdjustableRange:


Properties: ro


06 FAULT HISTORY

Description:

It is the record of the converter DC Link Voltage (P0003) at the moment of the last fault occurrence.

P0092 – Line Voltage at the Moment of the Last Fault

AdjustableRange:


Properties: ro


06 FAULT HISTORY

Description:

It is the record of the line voltage (P0002) at the moment of the last fault occurrence.


11-10 | CFW-11 RB

11

P0093 – Reactive Current at the Moment of the Last Fault

AdjustableRange:


Properties: ro


06 FAULT HISTORY

Description:

It is the record of the reactive current at the moment of the last fault occurrence.

P0095 – Input Voltage at the Moment of the Last Fault

AdjustableRange:


Properties: ro


06 FAULT HISTORY

Description:

It is the record of the input voltage (P0007) at the moment of the last fault occurrence.

P0096 – DIx Status at the Moment of the Last Fault

AdjustableRange:


Properties: ro


06 FAULT HISTORY

Description:

It indicates the status of the digital inputs at the moment of the last fault occurrence.

The indication is done by means of an hexadecimal code, which when converted to binary will indicate the status “Active” and “Inactive” of the inputs through numbers.

Bit 0 = DI1 Bit 1 = DI2 Bit 2 = DI3 Bit 3 = DI4 Bit 4 = DI5 Bit 5 = DI6 Bit 6 = DI7 Bit 7 = DI8

Example: if the code presented for the parameter P0096 on the keypad (HMI) is 00A5, it will correspond to the sequence 10100101, indicating that the inputs 8, 6, 3 and 1 were active at the moment of the last fault occurrence.

CFW-11 RB | 11-11

11


Table 11.2 - Example of correspondence between the P0096 hexadecimal code and the Dix status

0 0 A 50 0 0 0 0 0 0 0 1 0 1 0 0 1 0 1

No relation with the DIx(always zero)

DI8Active

(+24 V)

DI7Inactive

(0 V)

DI6Active

(+24 V)

DI5Inactive

(0 V)

DI4Inactive

(0 V)

DI3Active

(+24 V)

DI2Inactive

(0 V)

DI1Active

(+24 V)

P0097 – DOx Status at the Moment of the Last Fault

AdjustableRange:


Properties: ro


06 FAULT HISTORY

Description:

It indicates the status of the digital outputs at the moment of the last fault occurrence.

The indication is done by means of an hexadecimal code, which when converted to binary will indicate the status “Active” and “Inactive” of the outputs through numbers.

Example: if the code presented for the parameter P0097 on the keypad (HMI) is 001C, it will correspond to the sequence 00011100, indicating that the outputs 5, 4 and 3 were active at the moment of the last fault occurrence.

Table 11.3 - Example of correspondence between the P0097 hexadecimal code and the DOx status

0 0 1 C0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0

No relation with the DOx(always zero)

No relation with the DOx(always zero)

DO5Active

(+24 V)

DO4Active

(+24 V)

DO3Active

(+24 V)

DO2Inactive

(0 V)

DO1Inactive

(0 V)







P0806 – Temperature U -B3/IGBT U3




11-12 | CFW-11 RB

11







P0834 – DIM1 and DIM2 Status

For further details, refer to Section 10.1 PROTECTIONS [28] on page 10-1.

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