Toshiba VF-AS1 Series manuel d'utilisation

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Table des matières du manuel d’utilisation

  • Page 1

    E6581315 ② T OSVER T VF-AS1 Series RS485 Communication Function Instruction Manual      * The contents of this manual ar e subject to change w ithout notice. © TOSHIB A SCHNEI DER INVE RTER CORPORA TION 2005 All right s reserved. Notice 1. Make sure that this instruction manual is deliv ered to the end user of the inverter. 2. Read this ma[...]

  • Page 2

    E6581315 1 Read first Safety precautions This manual and labels on the inverter prov ide very important information that you should bear in mind to use the inverter properly and safely , and also to avoid injury to y ourself and other people and damage to property. Read the safety precautions in the instruction m anual for your inverter before read[...]

  • Page 3

    E6581315 2 Contents 1. General outlines of t he communicati on function............................................................................... .......................... 3 2. Data transmission specific ations ............................................................................................. ................................... 4 3[...]

  • Page 4

    E6581315 3 1. General outlines of the communication function This manual ex plains the RS485 communication f unction provided for the TOSVERT VF-AS1 series of industrial inverters. (1) RS485 communication by the use of a tw o-wi re RS485 communication port (standard function) (2) RS485 communication by the use of a four-w ire RS485 communication po[...]

  • Page 5

    E6581315 4 2. Data transmission specifications Items Specifications Transmission scheme Half-duplex Synchronization scheme Start-stop synchronization Communication baud rate 9600/19200*/38400 bps (selectable using a parameter) *1 Communication protocol TOSHIBA Inv erter Protocol * / MO DBUS-RT U (selectable using a parameter) *1 Character transmiss[...]

  • Page 6

    E6581315 5 3. Communication protocol This communication protocol supports the T OSH IBA Inverter Protocol and part of M ODBUS-R TU protocol. Select the desired protocol from in the follo wing communication protocol selection parameters (  ,  ). “Parameter Name   and  , Communication Number. 0807 [...]

  • Page 7

    E6581315 6 4. T OSHIBA Inverter Protocol Select “TOSHIBA” (  ,  =  ) in the communication protocol selection parameters. “TOSHIBA” (  ,  =  ) is set for initial communication protocol selection of shipment setting. (See “3. Communication protocol.”)  Exchange of data between the c[...]

  • Page 8

    E6581315 7 4.1. Dat a transmission format  Note: The term “trip st atus” used in this manual in cludes retry waiting st atus and trip retention status. 4.1.1. Dat a transmission format used i n A SCII mode A communication number is used to specify a data it em, all data is written in hexadecimal, and JIS- X-0201 (ASCII (ANSI))-compliant tr a[...]

  • Page 9

    E6581315 8  Inverter → computer At time of broadcast communication, returning of data is not ex ecuted, ex cept for the inverters to be returned, when the inverter number is not matc hed, and the inverter number has only one character. This is because there w ill be a risk of that the returned data may be deformed.  Data returned when data [...]

  • Page 10

    E6581315 9 • Data returned w hen data is not processed normally (ASCII mode) In case an error occurs, communication error co mmand (4EH(N) or 6EH(n)) and the error type num- ber is returned to the computer in addition to t he checksum. At time of broadcast communication of the binary mode, returning of data is not ex ecuted ex cept for the invert[...]

  • Page 11

    E6581315 10 4.1.2. Data transmission format used in binary mode A communication number is used to specify a data it em, data is written in hexadecimal form, and data in transmission characters are r epresented by binary codes (HEX codes).  Computer → Inverter (binary mode) Omissible in one-to-one communication      No data for the 52H [...]

  • Page 12

    E6581315 11  Inverter → computer (binary mode) At time of broadcast communication of the binary m ode, returning of data is not executed ex cept for the inverter to be returned (inverter number 00H) and when the inverter number is not matched. This is because there will be a risk that the returned data may be deformed. • Data returned w hen [...]

  • Page 13

    E6581315 12 2) Error Processing (Binary mode) In case an error occurs, communication error co mmand (4EH(N) or 6EH(n)) and the error type num- ber is returned to the computer in addition to the checksum. At time of broadcast communication of the binary mode, returning of data is not ex ecuted except for the inv erter to be returned (inverter number[...]

  • Page 14

    E6581315 13 4.1.3. T ransmissi on format of Block Communi cation W hat is block communication? Data can be wr itten in and read from several data groups set in one communication by setting the type of data desired for communication in the block communication parameters (  ,  ,  to  ) in advance. Block[...]

  • Page 15

    E6581315 14  Block W rite 1, 2 Select data, which is desired to be written in block communication, in block write Data 1 and 2 Pa- rameters (  ,  ) . This parameter becomes effective when the system is reset, such as when pow er is turned off. W hen the setting is completed, turn off and then on the power. * W hen “Dese[...]

  • Page 16

    E6581315 15  Inverter → Computer At time of broadcast communication of the binary m ode, returning of data is not executed ex cept for the inverter to be returned (inverter number 00H) and when the inverter number is not matched. This is because there will be a risk that the returned data may be deformed. 1) Normal processing 1. 2FH “/” (1[...]

  • Page 17

    E6581315 16 2) Error Processing (Binary mode) In case an error occurs, communication error co mmand (4EH(N) or 6EH(n)) and the error type num- ber is returned to the computer in addition to the checksum. O m i s s i b l e         (3.5bytes Blank) “/” (2FH) INV-NO 1 byte Norn (4EH)(6EH) DATA 2 bytes SUM 1 byte (3.5bytes Blank)   [...]

  • Page 18

    E6581315 17 4.2. Commands Here are the communication commands available. Command Function R command Reads the data with the specified communication number. W command W rites the data with the specified communication number. (RAM and EEPRO M). P command W rites the data with the specified communication number. (RAM). G command Reads the data with th[...]

  • Page 19

    E6581315 18  P (50 H ) (RAM *1 wri te ) This command is used to rewrite data into the parameter specified using a communication number. It writes data into the RAM only . It cannot be used to w rite data into any read-only parameters. Each time an attempt to write data is made the inv erter checks whether the data falls w ithin the specified ran[...]

  • Page 20

    E6581315 19 W hen Command “s” (lowercase letter) is received, the slave side judges that the master side is tripped and operates in accordance with the inter-drive communication parameter (  ,  ). For detail, see "7. Communication parameters ". - Examples: 50% frequency command (2-wire RS 485 communication) (If[...]

  • Page 21

    E6581315 20 4.3. T ransmissi on errors  Table of error codes Error name Description Error code Impossible to exe- cute The command is impossible to ex ecute, though communication wa s established normally. 1 W riting data into a parameter whose setting cannot be changed during operation (e.g., maximum frequency ) *1 2 W riting data into a parame[...]

  • Page 22

    E6581315 21 4.4. Broadcast communication functi on Broadcast communication function can transmit the comm and (write the data) to multiple inverters by one communication. Only the write (W , P) command is valid and the read (R, G) command is in- valid. The inv erters subject to the broadcast communication are the same to the independent com- munica[...]

  • Page 23

    E6581315 22 In broadcast communication, only the representative inv erter in each block returns data to the host computer. However, y ou can make the representative inverter in each block report the occurrence of a problem in the block. To do so, follow these steps. Set the timer function so that, if a time-out occurs, the inverter w ill trip (Ex.:[...]

  • Page 24

    E6581315 23 4.5. Examples of the use of communi cation commands Here are some examples of the use of communica tion commands provided for the VF-AS1 series of inverters. Inverter numbers and checksum used in ASCII mode are omitted from these ex amples.  Examples of communication - To run the motor in forw ard direction with the frequency set to [...]

  • Page 25

    E6581315 24 4.6. Examples of Communi cation programs According to the hardw are configur ation of the computer used, select a serial output port. T o use an RS232C port on the computer, y ou will hav e to prepare an R S232C-RS485 conversion unit sepa- rately. An USB-RS485 conversion unit (USB0001Z) is av ailable as our standard offering. Ex. 1: BAS[...]

  • Page 26

    E6581315 25 Ex. 2: BASIC program for executing an input command w ith checksum (RS232C, ASCII mode) (Toshiba version of Advanced BASIC-86 Ver. 3.01.05J) ◊ Checking if the max imum frequency setting has been changed correctly 1) Examples of programs 10 OPEN "COM1:9600,E,8,1" AS #1 --- 9600 baud, ev en parity, 8-bit length, 1 stop bit 20 [...]

  • Page 27

    E6581315 26 Ex. 3 BASIC program for communi cation tests (RS232C, ASCII mode) (Toshiba version of Advanced BASIC-86 Ver. 3.01.05J) ◊ Accessing a parameter (with error code.) 1) Examples of programs 100 INPUT "Baud rate=9600/4800/2400/1200";SPEED$ ---- Selects a baud rate. 110 INPUT "Parity =even(E)/odd(O)";PARIT Y$ ---- Select[...]

  • Page 28

    E6581315 27 Ex. 4 A VisualBaisc program for the ASCII mode communication (VisualBaisc is the register ed trademark of the U.S. microsoft company.) ◊ Accessing a parameter 1) Sample program executiv e example (Monitor of the output frequency (FD00)) Transmission and reception of the optional data like in the following example can be done by do- in[...]

  • Page 29

    E6581315 28 3)The description of the code Private Sub Form_Load() Form1.Show '********************************************************************** ' Setting the labels (Initialization) '********************************************************************** Label1.Caption = "Data for transmission" Label2.Caption = "Re[...]

  • Page 30

    E6581315 29 5. MODBUS-R TU protocol The M OD BUS-RT U protocol of VF-AS1 supports only part of the M ODBUS-R TU protocol. Only two commands are supported, “03: Multiple dat a read (limited only to two bytes)” and “06: W ord writes.” All data will be binary codes.  Parameter Setting • Protocol selection (  ,  ) S[...]

  • Page 31

    E6581315 30 5.1. MODBUS-RTU transmission format MO DBUS-RT U sends and receives binary data wit hout a frame-synchroniz ing start code and de- fines the blank time to recogniz e the start of a fr ame. M ODBUS-R TU decides the data that is first received subsequently as the first byte of a frame after a blank time for 3.5 bytes at the on-going commu[...]

  • Page 32

    E6581315 31 5.1.2. Write command (06)  Computer → Inverter *The tex t size is 8 bytes fix ed. Inverter No. Command Commu- nication No. (high) Commu- nication No. (low) Wr i t e D a t a (high) Wr i t e D at a (low) CRC (low) CRC (high) (3.5bytes Blank) 06 (3.5bytes Blank) 1) Inverter No. (1 byte) : Specify an inverter number between 0 and 247 ([...]

  • Page 33

    E6581315 32 5.2. CRC Generation “CRC” is a system to chec k errors in com municati on frames during data transm ission. CRC is composed of two bytes and has hexadecimal-bit bi nary values. CRC values are generated by the transmission side that adds CRC to mes sages. The receiv ing side regenerates CRC of received messages and compares generatio[...]

  • Page 34

    E6581315 33 <Notes> Speed command can be transmitted but the run / stop signal is not issued. Slave station should have an indi- vidual stop signal or the function to stop the action by the frequency reference. (Setting is necessary for  : Operation start frequency,  : Operation start frequency hysteresis .) For contin[...]

  • Page 35

    E6581315 34 Q W iring (2-wire RS485 communication) Master RXD+/ TXD+ RXD- /TX D- SG C N1 Pin -4 Pin -5 Pin -8 (Pin -3) Str aight Straight Terminat ing resistance 120 Ω -1/2 W Str aight Sla ve RXD+/ TXD+ RXD-/TXD- SG Sla ve RXD+/ TXD+ RXD- /TX D- SG Sla ve RXD+/ TXD+ RXD- / TXD - SG * Never use pin-7 (P11). Q W iring (4-wire RS485 communication) ?[...]

  • Page 36

    E6581315 35  Setting of parameter ● Protocol selection (  ,  ) Shipment setting: 0 (TOSHIBA) Protocol setting with all inv erters (both master and slave inverters) engaged in inter-driv e commu- nication 0: Set the TOSHIBA. * Inter-drive communication are disabled w hen the MODBUS-R TU protocol is selected. * This param[...]

  • Page 37

    E6581315 36  Relating communication parameters Following parameters should be set or changed if necessary . • Baud rate (  ,  )... Shipment setting =  : 19200bps Baud rate of all inverters in the netwo rk (master and slave) should be same netw ork. • Parity (  ) ... Shipment setting =  : Even parity [...]

  • Page 38

    E6581315 37 6.1. Proportional control of speed Proportional control of frequency can be performed in two ways: control by selecting frequency points and control by adjusting the ratio to the maximum frequency. This section explains propor- tional control of inverters by means of a master inverter (inter-drive communication), although the AS1 series[...]

  • Page 39

    E6581315 38 • If the “Frequency point selection” function is disabled (  =  ) The operation frequency (frequency command value) of the inverters are calculated using the fol- lowing equations, w ith the received data in the following equation used as the data received from the master inverter when inverter s are operated under [...]

  • Page 40

    E6581315 39 6.2. T ransmission form at for inter-drive communication Data type is handled in hexadecimal notation and t he transmission characters are treated with the binary (HEX ) code. The transmission format is basically the same to the case of binary mode. S command is used and the slave inverters do not return the data.  Master inverter ?[...]

  • Page 41

    E6581315 40 7. Communication parameters The settings of communication-related paramet ers can be changed from the operation panel and the ex ternal controller (computer). Note that there are two types of param eters: parameters whose settings take effect immediately after the setting and parameters whose settings do not take effect until the invert[...]

  • Page 42

    E6581315 41 Com- munic a- tion Number . Title Function Adjus tment range Unit Default setting V alid Refere nce 0826  Inverter-t o-inverter com munic ation setting (4-wire RS485) 0:Slave (i ssues a 0Hz c omm and if som e- thing goes wrong with the m aster) 1:Slave (c ontinues operat ion if s omet hing goes wrong with the mas ter) 2:Slav[...]

  • Page 43

    E6581315 42 7.1. Baud rate(  ,  ) , Parity (  ) • Communication baud rate and parity bit should be uniform inside the same netw ork. • This parameter is v alidated by resetting the pow er supply. 7.2. Inverter number(  ) This parameter sets individual numbers w ith the inverters. Inverter numbers [...]

  • Page 44

    E6581315 43 7.3. Communication tim e-out time (  ), Comm unication time-out action ( f804 ) The timer function is mainly used to detect a break in a cable during communication, and if no data is sent to an inverter within the preset ti me, this function makes the inverter trip (  ) or issue an alarm (  ). W ith the commun[...]

  • Page 45

    E6581315 44 7.4. Send w aiting time (  ,  ) Use this function for the following case: W hen the data response from the inverter is too qui ck after the PC had sent the data to the inv erter, PC process cannot get ready to receive the data, or w hen the USB/RS485, RS485/R S232C con- verter is used, changeover of sending and r[...]

  • Page 46

    E6581315 45 8. Commands and monitoring from the computer Across the network, instructions (commands and frequency) can be sent to each inverter and the operating status of each inverter can be monitored. 8.1. Communication com mands (commands from the computer)  Communication command (Communication number: FA00, FA04) Commands can be executed on[...]

  • Page 47

    E6581315 46  Communication command2 (Com munic ation Number : F A20, FA22) This command is enabled only w hen the communication command is enabled. Set Bit 15 of Com- munication Command 1 (communication Number: FA00, FA04) to “1” (enable). W hen enabling the communication command by C ommunication Command 1, commands by communication can be [...]

  • Page 48

    E6581315 47  Frequency setting f rom the computer “Com munication Number: FA01, FA05” Setting range: 0 to maximum frequency ( fh ) This frequency command is enabled only w hen the frequency command by communication is en- abled. To make frequency commands from the co mputer valid, set the frequency setting mode se- lection parameter ( fmod )[...]

  • Page 49

    E6581315 48  T erminal board output data (F A50) The output terminal board on each inverter can be directly controlled with the computer. To use this function, select functions 92 to 105 in advance for the output terminal function selection parameters f130 to f138 , f168  and  f169 . If bit 0 through bit 6 of terminal board output data (FA[...]

  • Page 50

    E6581315 49 8.2. Monitoring from the com puter This section ex plains how to monitor the operati ng status of the inverter from the computer.  Monitoring of the out put frequency from the c omputer (FD00, FE00) Output frequency (current status): “Communi cation Number FD00” (minimum unit: 0.01H z) Output frequency (status immediately before [...]

  • Page 51

    E6581315 50  Input terminal board status (FD06, FE06) Input terminal board status (current status): “Communication Number FD06” Input terminal board status (status immediately before the occurrence of a trip): “Communication Number FE06” Using terminal function selection parameters, f unctions can be assigned individually to the termi- n[...]

  • Page 52

    E6581315 51  Output terminal board status (FD07, FE07) Output terminal board status (current status): “Communication Number FD07” Output terminal board status (status immediately before the occurrence of a trip): “Communication Number FE07” Using terminal function selection parameters, f unctions can be assigned individually to the termi[...]

  • Page 53

    E6581315 52  Inverter operating st atus 1 (FD01, FE01) Inverter status 1 (current st atus): Communication Number FD 01 Inverter status 1 (status immediately before the occurrence of a trip): Communication Number FE01 Bit Specifications 0 1 Remarks 0 Failure FL No output Output in progress 1 Failure N ot tripped Tripped T rip statuses include [...]

  • Page 54

    E6581315 53  Inverter operating st atus 2 (FD42, FE42) Inverter status 2 (current st atus): Communication Number FD 42 Inverter status 2 (status immediately before the occurrence of a trip): Communication Number FE42 Bit Function 0 1 Remarks 0 Control mode switching Speed control (Simple posi- tioning) Torque control 1 Electric Power Counting (F[...]

  • Page 55

    E6581315 54  Inverter operating command mode st atus (FD45, FE45) The monitor of the command mode t hat the present condition is enabled Command mode status (current stat us): “Communication Number FD45” Command mode status (status immediately before t he occurrence of a trip): “Communication Num- ber Data Enabled command 0 Terminal input [...]

  • Page 56

    E6581315 55  Alarm information monitor (FC91) Bit Specifications 0 1 Remarks (Code displayed on the panel) 0 Over-current alarm Normal Alarming  flickering 1 Inverter ov erload alarm Normal Alarming  flickering 2 M otor overload alarm Normal Alarming  flickering 3 Overheat alarm Normal Alarming  flickering 4 O[...]

  • Page 57

    E6581315 56  T rip code monitor ( current status: FC90: historic records: FE10 to FE13) Code Data (hexadeci- mal number) Data (decimal number) Description nerr 0 0 No error oc1 1 1 Over-current during acceleration oc2 2 2 Over-current during deceleration oc3 3 3 Over-current during constant speed operation ocl 4 4 Over-current in load at startup[...]

  • Page 58

    E6581315 57 e-24 38 56 Option 2 error e-25 39 57 Stop position retaining error e-26 3A 58 CPU2 fault etn1 54 84  tuning error etn2 55 85  tuning error etn3 56 86 Motor constant setting error  Inverter model (capacity) code (FB05) Model Data (hexadecimal number) Data (decimal number) VFAS1-2004P 2 2 VFAS1-2007P 4 4 VFAS1-2[...]

  • Page 59

    E6581315 58 8.3. Utilizing p anel (LEDs and key s) by communication The VF-AS1 can display data that is not related to the inverters through an external controller or other means. Input by key operations can also be ex ecuted. The use of inverter resources re- duces the cost for the entire system. 8.3.1. LED setting by communication Desired LED inf[...]

  • Page 60

    E6581315 59  Block Communication Function for LED Display To display LED data for ASCII display that is sync hronized to each digit, set data for each digit and validate this set data by display selection by communication (Communication Number FA65). Synchronization can also be achieved by batch wr iting LED data parameters after changing the fo[...]

  • Page 61

    E6581315 60 ■ ASCII LED display data code (00H-1FH are blank.) Hex Code Displ ay Char. Hex Code Displ ay Char. Hex Code Disp lay Char. Hex Code Di splay Char. 00H BLANK 20H BLA NK SP 40H BLANK @ 60H BLANK ` 01H BLANK 21H B LANK ! 41H A 61H a 02H BLANK 22H B LANK 42H B 62H b 03H BLANK 23H B LANK # 43H C 63H c 04H BLANK 24H B LANK $ 44H D 64H d 05H[...]

  • Page 62

    E6581315 61 8.3.2. Key utilization by communication The VF-AS1 can use the panel keys on the inv e rters through ex ternal communication.  Key Monitoring Procedure Set panel key selection (Communication Number: FA10) to “1” to set the ex ternal key mode. How- ever, if communication duration is less than 1sec to avoid an inverter operation sh[...]

  • Page 63

    E6581315 62 9. Parameter data Explanation of parameters for VF-AS1 series is described here. For communication purposes, see the parameter list on inverter' s instruction m anual regarding the communication number, adjustment range and so forth.  Referring to the parameter list   <Example of ex cerpts from the inverter’s instruction [...]

  • Page 64

    E6581315 63  Command parameters For those parameters that contain data only in t he RAM and not in the EEPROM, their data return to initial values w hen the power is turned off, in failure resetting, or when standard shipment settings are set. Note that parameters w i thout data stor age in the EEPROMs w ill be written in the RAM only even if th[...]

  • Page 65

    E6581315 64 * 1 : Enable the communication command or communication frequency setting before setting these parameters are set. Otherw ise, the parameter s will not function. See “8.1 Command by communication” for the method to enable them. * 2 : Note that the Communication Number for operation panel operation frequency is FA02 in the VF-S7 [...]

  • Page 66

    E6581315 65  Monitor parameters *These Pa rameters are read-only (monitor-only) parameters. Communication No. Current valu e Trip data held Function Unit Remarks FC00 − Monitor of key data (Effective data) − FC01 − Monitor of inv erter keypad data − Refer to Section 8.3. FC90 − Trip code − FC91 − Alarm code − FD00 FE00 Output fre[...]

  • Page 67

    E6581315 66 FD50 − Light-load high-speed torque 1 0.01% FD51 − Light-load high-speed torque 2 0.01% − FE60 MY monitor 1 − − FE61 MY monitor 2 − − FE62 MY monitor 3 − − FE63 MY monitor 4 − − FE70 Rated current 0.1a − FE71 Rated voltage 0.1V − FE73 CPU version 2 (motor) − − FE76 Integral input power 0.01kW h − FE77 Int[...]

  • Page 68

    E6581315 67 Appendix 1 T able of dat a codes • JIS (ASCII) codes Higher orde Lower order 0 1 234567 0 NUL TC 7 (DLE) (SP) 0@P、p 1T C 1 (SOH) DC 1 ! 1AQaq 2T C 2 (STX) DC 2 2BRbr 3T C 3 (ETX) DC 3 #3CScs 4T C 4 (EOT) DC 4 $4DTdt 5T C 5 (ENQ) TC 8 (NAK) %5EUeu 6T C 6 (ACK) TC 9 (S[...]

  • Page 69

    E6581315 68 Appendix 2 Response time The communication response time can be calcul ated from data communication time and inverter processing time. W hen wishing to know the communication response time, calculate using the following as a reference  Data transmission time bits of number d transmitte bytes of number rate baud 1 time on transmissi D[...]

  • Page 70

    E6581315 69 Appendix 3 Comp atibility with the communication function of the VF-A7 To provide consistency in communication proc edures, the communication function of the VF-AS1 series of inverters has been designed based on the protocols used for the T oshiba VF-A7 series of inverters. W ith regard to compatibility, however , VF-A7 users should che[...]

  • Page 71

    E6581315 70 Appendix 4 T roubleshooting If a problem arises, diagnose it in accordance with the following table before making a service call. If the problem cannot be solved by any remedy described in the table or if no remedy to the problem is specified in the table, contact your Toshiba dealer. Problem Remedies Reference Communication will not ta[...]

  • Page 72

    E6581315 71 Appendix 5 Connecting for RS485 communication  Connector diagram for 2-wire RS485 communication                               Connecting diagram for 2-wire RS485 communication * Never use pin-7 (P11). Master RXD+/ TXD+ RXD- /TX D- SG C N1 Pin -4 Pin -5 Pin -8 (Pin -3) Str aight[...]

  • Page 73

    E6581315 72  Connector diagram for 4-wire RS485 communication                               Connecting diagram for 4-wire RS485 communication * W hen using 2-wire type, short RX B to TXB and RXA to T XA. * Never use pin-1 (Open) and pin-7 (P11). Terminat ing resistance 120 Ω -1/2 W Sla ve[...]