Mitsubishi Electronics 700 Series Bedienungsanleitung
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Inhaltsverzeichnis der Gebrauchsanleitungen
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Seite 1
INVERTER FR - A 700 HEAD OFFICE:MITSUBISHI DENKI BLDG MARUNOUCHI TOKYO 100-8310 FR-A 700 INVERTER PLC FUNCTION PROGRAMM ING MANUAL A PLC FUNCTION Chapter 1 CC-Link COMMUNICA TION Chapter 2 SEQUENC E PROGRAM M ING Chapter 3 ERROR CODE LIST Chapter 4 PLC FUNCTION PROGRAMMING MANUAL IB(NA)-0600262EG-A(0509)MEE Printed in Japan Specifications subject t[...]
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I CONTENTS CONTENTS 1. PLC FUNCTION 1 1.1 Func tion Bloc k Dia gram ...... .... ..... .... ..... .... .... ..... .... ....... .... ..... .. 2 1.2 PLC Function Specifi cations ...... ....... ....... ....... .......... ....... ....... .3 1.3 Syste m Con figur at ion ........ .... .... ..... .... ....... .... ..... .... ..... .... .... ..... 4 1.4 Wir[...]
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II 2. CC-Link COMMUNICATION 45 2.1 Syst em Co nfi gurati on ...... .... ..... .... ..... .... ....... .... ..... .... .... ..... .... 46 2.1.1 System con figuration exampl e ................... ................. ....................... ......... 46 2.1.2 Function block d i agram ............. ....................... ........... ................. ..[...]
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III CONTENTS 3.9.5 100ms, 10ms and 100ms re tentive timers .................. ...................... .......... 80 3.9.6 Timer pro c essing me thod and accura cy ......... ................. ....................... .... 81 3.10 Count ers C ...... .... ..... .... ....... .... .... ..... .... ..... ...... ..... .... ..... .... .... ... 83 3.10.1 Count[...]
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IV 3.25.6 Output I nstructio ns : Device set, res et ... SET, RST .............. ................. .. 1 26 3.25.7 Output I nstructions : Le ading edge, t railing ed ge differentia l outputs ... PLS, PLF ............... ....................... ................. ...................... ................. ............. 129 3.25.8 Shift Inst ructions : B[...]
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1 Cha pt e r 1 Cha pt e r 2 Cha pt e r 3 Cha pt e r 4 1. PLC FUNCTION This manua l desc ribes the func tions a nd device s neces sary for programm ing. 1.1 Function Block Diagram ........... ......... ......... ......... 2 1.2 PLC Function Specif ications ......... ....... .......... ..... 3 1.3 Syste m Con fig urat ion . .... ..... .... ....... ..[...]
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2 Function Block Diagram 1.1 Function Block Diagram How I/O dat a are transferred to/from the inverter by the built-in PLC function is explained using function bloc ks. (1) I/O data read, write, etc. can be performed by ac cessing the inverter in the predetermined method using special relay s, special registers, etc. (2) Operation, parameter read/w[...]
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3 PLC Funct ion Speci fications 1 PLC FUN CTIO N 1.2 PLC Function Speci fications The follow ing tab le indicates the progr am capacity and device s of the PLC function. *1 These signals use the same terminals as used by the input and output signals given in t he common specifications of the inverter . One point is always necessary for a sequence s[...]
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4 Syst em Configura tion 1.3 System Configuration The following shows the system configuration for use of the PLC function. <System configura tion example> Communication specifi cations Set the following setting in c ommunication param eters of the inverter . Inverter Parame ter GX Develope r Setting Inverter initial setting Pr .1 18 PU co mm[...]
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5 Wiri ng of the I nverter and P ersonal Compu ter Usin g GX Developer f or RS-485 Communic ation 1 PLC FUN CTIO N 1.4 W iring of the Inverter and Personal C omputer U sing GX D evelop er for R S-485 C omm unica tion z Personal computer - inverter connection cable Make connection after c onversion between RS-232C and RS-485. Examples of commerciall[...]
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6 Prior to Sequence Program Creation 1.5 Pri or to Sequence Program Creation 1.5.1 Precautions for sequenc e program creation If any of the instructions (r efer to page 103) and devices (r efer to page 3) that cannot be used with the built-in PLC function ex ists in a sequence program, an instruction code error occurs at the execution of that instr[...]
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7 Prior to Sequence Program Creation 1 PLC FUN CTIO N 1.5.3 Sequence program ex ecution key The sequence program execution key (ST OP/RUN) of the PLC is switched by turning off/on the SQ s ignal. Open (STOP) the S Q signal-SD terminals when writing a sequence program, for example. When executing the sequence program, shor t (RUN) the SQ signal-SD t[...]
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8 Prior to Sequence Program Creation 1.5.4 Sequence program write When rewriting the PLC function parameters and sequence program using GX Developer , check the following: 1) Check that the sequence program execution k ey is in the STOP position (SQ si gnal is off) (r efer to page 7) . 2) Check that the inverter is at a stop. 3) Check that the comm[...]
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9 Function Block Diagram 1 PLC FUN CTIO N 1.5.5 Setting list of buil t-in PLC function parameter The built-in PLC function p arameters are designed to specify the ranges of using the PLC function, e.g. program cap acity , dev ice assignment and various functions. Item GX Devel oper Default Setting Rang e <Usable d evice range> Sequ ence prog [...]
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10 Device Map 1.6 Dev ice Map 1.6.1 I/O device map Device No. Name Remarks Device No. Name Remarks External I/O X00 STF terminal External terminal Y00 R UN terminal External term ina l X01 STR termi nal Y01 SU t ermin al X02 RH terminal Y02 O L terminal X03 RM terminal Y03 IPF terminal X04 RL t erminal Y04 F U terminal X05 JOG terminal Y05 A BC1 te[...]
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11 Device Map 1 PLC FUN CTIO N Device Ma p System I/O X20 Op eratio n mode sett ing read com pletion D9140 Y20 Oper ation m ode setting read com mand D9140 X21 Set frequency read completion ( R AM) D9141 Y21 Set freq uency read com mand (R AM) D9141 X22 Set frequency read completi on (E 2 PROM) D 9142 Y22 Set freq uency rea d com mand (E 2 PR OM) D[...]
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12 Device Map 1.6.2 Internal relay (M) device m ap 1.6. 3 D ata registe r (D) device map 1.6.4 Spec ial rela ys The special relays are i nternal relays wi th special applications and therefore should not be switched on-of f in the program. Device No . Descrip tion M0 to M63 Use f reel y on user side . Data Register (D) Inverte r Pr . Number Paramet[...]
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13 Device Map 1 PLC FUN CTIO N Device Ma p M921 1 Inve rter op eration status cont rol f lag (R E S) Control the R ES terminal of the inverter from PLC func ti on M9216 Inverter st atus (RUN) Inverter ru nning M9217 Inverter status (FWD ) For ward runn ing M9218 Inverter status (REV) Reverse runn ing M9219 Inverter status (SU) Up to freq uency M922[...]
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14 Device Map 1.6.5 Special regist ers The special registers are dat a r egisters with special appl ications and therefore dat a should not be written to the special regi sters in the program. Number Name Description Page S p ecial re gisters D9008 Self -diagnost ic error S to res the sel f-diagnos ed error num ber in BIN . ( Refer to page 2 2 for [...]
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15 Device Map 1 PLC FUN CTIO N Device Ma p S pec ial regis ters for co ntrol D9133 Output frequency monitor S t ores the c urrent out put freque ncy . 0.01Hz un its 20 D9134 Output current monitor S t ores the c urrent out put curren t. 0.01A un its D9135 Output volt age monitor S t ores the c urrent out put voltage. 0.1V u nits D9136 Error histo r[...]
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16 Device Map S p ecial re gisters f or control D9148 Inve rter op eration status con trol Turn on/off the correspond ing bits to con trol the inverter operat ion status. The initial val ue: All "0". W hen M925 5 is off, this device does not fu nction. 31 D9149 Inverter operat ion status con trol enable/di sable setting Enable/di sable th[...]
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17 Device Map 1 PLC FUN CTIO N Device Ma p S p ecial re gisters f or control D9159 Conver ter output voltage peak value 0.1V units — D9160 Input power 0.0 1kW /0.1kW unit s — D9161 Output po wer 0.0 1kW /0.1kW unit s — D9162 Inpu t termin al status Input t erminal status details — D9163 Output terminal status Output term inal status details[...]
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18 Device Map S pe cial re gister s for co ntrol D9205 Option input ter minal st atus 1 The inpu t status of the FR-A 7AX is sto red. All of f (0) when a n option i s not fitte d. — D9206 Option input ter minal st atus 2 — D9207 Opt ion output ter minal st atus The outp ut status of t he FR-A 7A Y , FR- A7AR is stored . All of f (0) when a n op[...]
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19 Device Map 1 PLC FUN CTIO N Device Ma p Number Name Descripti on Page S p ecia l registers for control D9234 Sec ond para met er changi ng (RAM) Whe n setti ng the calib ration( bias/gai n) parameter s. H00: F reque ncy(to ruque) H01: P arameter -set ana log value H02: A nalog value input from term inal 34, 36 D9235 Second para met er changi ng [...]
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20 Inverter Status Monitoring, Sp ecial Registers for Control 1.7 Inverter St atus Monitoring, S pecial Registers for Control Y ou c an assign the data for grasping and changing the inverter's operation status to D9133 - D9147 and r ead/write them from the user sequence. ( Refer to page 14 for the list.) 1.7.1 Data that can be read at all ti m[...]
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21 Inverter Status Monitoring, S pecial Registers for Control 1 PLC FUN CTIO N (2) Error history (error codes and err or definitions) The inverter stores the error codes of the errors that occurred. The error codes of up to ei ght error s are stored in the order as s hown below and are always read-enabled (write-disabled). <Error code storing me[...]
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22 Inverter Status Monitoring, Sp ecial Registers for Control <Alarm definition read prog ram example> The following program reads the latest al arm definition of the inv erter to D0. <Regarding the err or No. and det ails of the self-diagnosti c errors> During execution of a sequence program, any of the following error No. is stored in[...]
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23 Inverter Status Monitoring, S pecial Registers for Control 1 PLC FUN CTIO N 1.7.2 Data that are read by c ontrolling (OFF to ON) the read command Y ou c an read the operation mode and set frequency of the inverter . Data are stored into the above data devices as soon as the read completion turns from off to on af ter the r ead command has turned[...]
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24 Inverter Status Monitoring, Sp ecial Registers for Control (2) S et frequ ency (RAM) (D9141) The frequency set to the RAM is read to D9141. The unit is 0.01Hz. (For example, 6000 indicates 60.00Hz.) When the speed is set, the speed is either 1r/min or 0.1r/min. <Set frequency (RAM) read prog ram example> The following program reads the set[...]
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25 Inverter Status Monitoring, S pecial Registers for Control 1 PLC FUN CTIO N 1 . 7 . 3 How to write data by controll ing (OFF to ON) the wri t e command Y ou c an write the operation mode and set frequency to the inverter , batch-clear the alarm definitions, and clear all p arameters . The above data are written as soon as the write completion tu[...]
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26 Inverter Status Monitoring, Sp ecial Registers for Control (1) O perati on mode se tting write (D9143) Data are as follows: The operation mode switching method is as shown below when the Pr .79 Oper atio n mode sele ctio n value is "0". When Pr . 79 = 2, switching is performed as shown below . There are no restrictions on operation mod[...]
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27 Inverter Status Monitoring, S pecial Registers for Control 1 PLC FUN CTIO N (2) S et freque ncy (RAM ) (D9144 ) The D9144 data is written to the RAM as a set frequency . The unit is 0.01Hz. (For example, 6000 indicates 60.00Hz.) When the speed is set, the speed is either 1r/min or 0.1r/min. The range where the frequency can be set is 0 to 12000 [...]
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28 Inverter Status Monitoring, Sp ecial Registers for Control (3) Set frequ ency ( EEPROM ) (D9145 ) The D9145 data is written to the E EPROM as a set frequency . The unit is 0.01Hz. (For example, 6000 indicates 60.00Hz.) When the speed is set, the speed is either 1r/min or 0.1r/min. The range where the frequency can be set is 0 to 12000 (0 to 120.[...]
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29 Inverter Status Monitoring, S pecial Registers for Control 1 PLC FUN CTIO N (4) Alarm definition batch clear (D9 146) Writing H9696 to D9146 batc h-clears the alarm definitions. At completion of clear , the write completion signal (X26) turns on, and at the same time, 0 is set to D9150. If any value outside the setting range is written or write [...]
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30 Inverter Status Monitoring, Sp ecial Registers for Control (5) Param eter clear (D91 47) Writing H9696 or H9966 to D9147 clears all parameters. Writing H5A5A or H55AA to D9147 clears the parameters other than the communication parameters (Refer to the In verter i nstruct ion ma nual (applied ) ). At completion of clear , the write completion sig[...]
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31 Inverter Status Monitoring, S pecial Registers for Control 1 PLC FUN CTIO N 1.7. 4 Inverter opera tion st atus co ntr ol (1) Inverter ope ration st atus cont rol (D9148) Device for inverter operation status control. The operation of the inverter c an be controlled by turning on/off (1, 0) bit s b0 to b1 1 of D9148. All bit s are factory-set to &[...]
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32 Inverter Status Monitoring, Sp ecial Registers for Control (2) Inverter operation st atus control enable/disable setting (D9149) Y ou can enable or disable D9148 "inv erter operation status control". The c ontrols of the corresponding bits of D9148 are enabled by turning on/of f (1, 0) bits b0 to b1 1 of D9149. All bits are factory-set[...]
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33 Inverter Status Monitoring, S pecial Registers for Control 1 PLC FUN CTIO N 1.7.5 Inverter parameter acc e ss error (D9150) If any value outside the setting range is written during parameter write, set frequency write, parameter clear , etc. from the sequenc e progr am of the inverter , or if write is performed when write is disabled, a write al[...]
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34 Inverter Parameter Read/ Write Method 1.8 Inverter Parameter R ead/Write Method 1.8.1 Reading the inverter para meters When reading the parameter , the parameter description is stored to D9242(D9244) by storing the parameter number to D9241(D9243) and turning Y28 (Y2A) on. When reading is completed, X28 (X2A) turns ON to notify the completion. ([...]
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35 Inverter Parameter Read/Write Method 1 PLC FUN CTIO N Inverter p arameter dat a read timing chart Y28(Y2A) Parameter r ead command X28(X2A) Parameter re ad completion D9242(D9243) Parameter read data User sequence processing Inverter parameter 1) Read command is turned on in user sequen ce. 3) In user sequenc e, ON of read completion is confirme[...]
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36 Inverter Parameter Read/ Write Method 1.8.2 Writing the inverter parameters Parameter writing is performed when the p arameter number is stored to D9241 (D9243) and parameter writing value to D9242 (D9244), and turns ON the Y29 (Y2B). When writing is completed, X29 (X2B) turn s ON to notify the compl etion. (The device number within parentheses [...]
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37 Inverter Parameter Read/Write Method 1 PLC FUN CTIO N Inverter p arameter dat a write timing chart Y29(Y2B) X29(X2B) Parameter write completion Inverter parameter D9242(D9244) Parameter write data User sequence data Parameter write command 1) In user sequenc e, user data are stored into parameter wr ite data area (D9242(D9244)). 2) Write command[...]
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38 User Area Read/Write Metho d 1.9 User Area Read/W rite Method Inverter parameters Pr.506 to P r.515 can be used as user parameters. Since this parameter area and the devices used with the PLC function, D1 10 to D1 19, are accessible to each other , the values set in Pr .506 to Pr .515 c an be used in a sequence program. The result of operation p[...]
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39 Analog I/O functio n 1 PLC FUN CTIO N 1.10 Analog I/O function 1.10.1 Analog input Analog input value of t ermianl 1, 2, 4 can be read from D9245 to D9247. Actual read processing is performed at the END processing of the sequence. 1.10.2 Analog output Analog output from each terminal can be performed by setting value on D9251 to D9254. Output fr[...]
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40 Paluse t rain input functio n 1.1 1 Paluse train input function Pulse train (the number of sampli ng pulses) from terminal JOG is stored to D9236. When the sampling p uls es overflow , make adjustment with the setting of Pr . 416 and Pr . 41 7 . The number of sampling pulses = the number of input pulses per count cycle x Pre-sc ale setting value[...]
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41 PID cont rol 1 PLC FUN CTIO N 1.12 PID control With PLC function, PID set point/PID deviation value, PID process value can be set by setting Pr . 128. Performing the PID operation using the v alue of D9248 and D9249 as PID set point/ PID deviation value, PID process value, mani pulated variable is stored to D9250. When performing PID control wit[...]
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42 PID cont rol Device No. Name Setting Range Descr iption D924 8 PID set point / PID deviati on -10 0 to 100 % Set the PID s et point or PID devi ation (0 .01% un it s) D924 9 PID measure men t value 0 to 100% Set the P ID me asure ment value (0.0 1% units) D925 0 PID mani pulated va riable -100 to 100% Stores the PID manipul ated variabl e (0.01%[...]
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43 Inverter Operation Lock Mode Setting 1 PLC FUN CTIO N 1.13 Inverter Operation Lock Mode Setting Y ou c an disable a sequence program from being executed until the sequence program execution key is set to RUN (SQ signal is turned on). POINT When you want to perform only inverter operation without using the PLC function, set "0" (inverte[...]
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44 MEMO[...]
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45 Cha pt e r 1 Cha pt e r 2 Cha pt e r 3 Cha pt e r 4 2. CC-Link COMMUNICA TION 2.1 Syste m Con fig urat ion . .... ..... .... ....... .... ..... .... ..... ... 46 2.2 CC-Li nk P ara meter s .... .... ..... .... ..... ...... ..... .... ..... ... 49 2.3 CC-Li nk I /O Specific atio ns ... .... ..... .... ....... .... ..... ... 50 2.4 Buff er Memo ry[...]
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46 Syst em Configura tion 2.1 System Configuration 2.1.1 System configuration example (1) PLC side Mount the "Control & Communication Link system master/local module" on the main base unit or extension base unit of t he PLC CPU that will ac t as the master station. (2) Connect the PLC CC-Link module master station and inverters by CC-[...]
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47 Syst em Configura tion 2 CC-Link COMMUNICATION 2.1.2 Function block diagram How I/O data are transferred to/from the inverter in CC-Link will be described us ing function blocks. (1) Between the master station and inverter in the CC-Link system, link refresh is always made at 3.5 to 18ms (512 points ). (2) I/O refresh and master st ation's [...]
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48 Syst em Configura tion POINT The difference bet ween CC-Link co mmunication ( Pr . 544 = 100, 1 12, 1 14, 1 18) with PLC fu nction and n ormal CC-Link communication ( Pr . 544 =1, 2, 12, 14, 18) is indicated below. I/O (RX, RY) I/O (RX, RY) RWw RWr RWw RWr PLC CPU CC-Link mas ter module Inverter Pr.544=0,1,12,14,18 Inverter CPU Parameter read/wr[...]
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49 CC-Link Parameters 2 CC-Link COMMUNICATION 2.2 CC-Link Parameters 2.2.1 CC-Link Extended Setting (Pr . 544) Remote register function can be extended. *1 The program use d for conv ention al series inv erter ( FR-A5NC) can be us ed. *2 When usin g doubl e, quad ruple and o ctuple setting s of t he CC- Link Ver . 2, statio n data of the maste r st[...]
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50 CC-Li nk I/O Spec ificat ions 2.3 CC-Link I/O Specificati ons 2.3.1 I/O signal when CC-Link Ve r.1 one station is occupied (Pr. 544 = 100) The device point s usable in CC-Link comm unication are 32 input (RX) points (16 points are avail able for PLC function), 32 out put (RY) point s (16 points are available for PLC function), 4 remote register [...]
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51 CC-Link I /O Specifica tions 2 CC-Link COMMUNICATION ("n" indica tes a val ue determi ned ac cordin g to the station nu mber se tting. ) *1 Signal names a re initial values. Using Pr . 180 to Pr . 186, Pr . 188, and Pr . 189 , you can change in put sign al function s. Signals o f the RYn0, RYn1, and RYn9 can not be cha nged. E ven wh e[...]
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52 CC-Li nk I/O Spec ificat ions 2.3.2 I/O signal when CC-Link Ve r.2 double setting is selected (Pr. 544 = 112) The device point s usable in CC-Link comm unication are 32 input (RX) points (12 points are avail able for PLC function), 32 out put (RY) point s (12 points are available for PLC function), 4 remote register (RW r) points and 4 remote re[...]
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53 CC-Link I /O Specifica tions 2 CC-Link COMMUNICATION ("n" indica tes a val ue determi ned ac cordin g to the station nu mber se tting. ) *1 Signal names a re initial values. Using Pr . 180 to Pr . 186, Pr . 188, and Pr . 189 , you can change in put sign al function s. Signals o f the RYn0, RYn1, and RYn9 can not be cha nged. E ven wh e[...]
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54 CC-Li nk I/O Spec ificat ions 2. 3 .3 I/O signal when CC-Link Ver.2 qu adruple setting is selected (Pr. 544 = 114) The device point s usable in CC-Link comm unication are 32 input (RX) points (12 points are avail able for PLC function), 32 out put (RY) point s (12 points are available for PLC function), 8 remote register (RW r) points and 8 remo[...]
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55 CC-Link I /O Specifica tions 2 CC-Link COMMUNICATION 2.3.4 I/O signal whe n CC-Link Ver.2 octuple se tting is selected (Pr. 54 4 = 118 ) The device point s usable in CC-Link commu nication are 32 input (RX) point s (12 points are availa ble for PLC function), 32 out put (RY) points (12 point s are available for PLC function), 16 remote register [...]
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56 CC-Li nk I/O Spec ificat ions ("n" indica tes a va lue determ ined ac cordin g to the station nu mber set ting. ) D906 2 RWw n+10 Regist ers desi gned to read d ata rece ived from the master station D9078 R Wrn+ 10 Regist ers desi gned to write dat a to be sent to th e maste r st ati on. D9063 RWwn+ 1 1 D9 079 RWrn+1 1 D906 4 RWwn+12 D[...]
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57 Buffer Memory 2 CC-Link COMMUNICATION 2.4 Buffer Me mory 2.4.1 Remote output signals (Master module to inverter(FR-A7NC)) • Input states to the remote device st ation are stored. • T wo words are used for each station. (Do not use address 16n (n = 2(X - 1) + 1, X = station No.)) Correspondences between Master S tation Buf fer Memory Addresse[...]
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58 Buffer Memory 2.4.2 Remote input signals Pr .544 =100 (Inverte r(FR-A7NC) to master m odule) • Input states from the remote devic e station are stored. • T wo words are used for each station. (Do not use address En (n = 2(X - 1) + 1, X = station No.)) Correspondences between Master S tation Buf fer Memory Addresses and S tation Numbers St at[...]
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Seite 64
59 Buffer Memory 2 CC-Link COMMUNICATION 2.4.3 Remote registers Pr .544= 100 (Master module to inverter(FR-A7NC)) • Data to be sent to the remote registers (RWW) of the remote device station are stored. • Four words are used for each station. Correspondences between Master S tation Buf fer Memory Addresses and S tation Numbers Sta t i on No. Bu[...]
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60 Buffer Memory 2.4.4 Rem ote r egi ster s P r . 544 =100 (Inverter(FR-A7NC) to master module) • Data sent from the remote registers (R WR) of the remote device station are stored. • Four words are used for each station. Correspondences between Master S tation Buf fer Memory Addresses and S tation Numbers Sta t i on No. Buffer Memory Addr ess [...]
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Seite 66
61 Cha pt e r 1 Cha pt e r 2 Cha pt e r 3 Cha pt e r 4 3. SEQUENCE PROGRAMMING 3.1 Overv iew .. ..... .... .... ..... ...... ..... .... ..... .... ..... ...... ..... ... 62 3.2 RUN and STOP Opera tion Processings ........... .. 64 3.3 Program Makeup ............ ......... ......... ........... ......... 64 3.4 Programming Languages ........... ....[...]
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Seite 67
62 Overview 3.1 Over view 3.1.1 Outline of Operation Process ings This section outlines processings perform ed from when the inverter is powered on until a sequence program is executed. The built-in PLC function processings are roughly classified into the following three types. (1) Initial processing Pre-processing for executing sequence operation.[...]
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Seite 68
63 Overview 3 SEQUENCE PROGRAMMING Fig 3.1 Operation Processings of Built-in PLC functi on Sequenc e program op eration p r oces sing Step 0 to Until execution of END instruction Power on I/O ref resh processin g Init ial proc essing I/O in itialization Data me mory initializ ation Self-diagnostic checks END pr oc essi ng Self-diagnostic checks Upd[...]
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Seite 69
64 RUN and STOP Operation Processings 3.2 RUN and STOP Operation Processings The built-in PL C function has two di fferent operation s tatuses: RUN st atus and STOP status. This section explains the operation processings of the built-in PLC function in each operating status . (1) Operation processing in RUN status A RUN status indicates that a sequ[...]
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Seite 70
65 Progr amming Lang uages 3 SEQUENCE PROGRAMMING 3.4 Programming Lan guages The built-in PLC function has two different programming methods: one that uses ladders and the other that uses dedicated instructions . • Programming that uses ladders is performed in the relay symbolic language. *1 • Programming that uses dedicated instructions is per[...]
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Seite 71
66 Progr amming Langu ages (2) Sequence program operation method Sequence program operation repeat s execution from a ladder bl oc k at step 0 to an END instruction. In a single ladder block, operation i s performed from the left hand side vertic al bus to the right, and from the top to the bottom. Fig 3.3 Operation Processing Sequence Beginni ng o[...]
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Seite 72
67 Progr amming Lang uages 3 SEQUENCE PROGRAMMING 3.4.2 Logic symbolic language (List mode) The logic symbolic l anguage uses dedicated instructions for programming contact s, coils, etc. instead of their sy mbols used by the relay symbolic language. (1) Program operation method Sequence program operation is executed from an instruction at s tep 0 [...]
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68 Operation Processing Me thod of P LC Functi on 3 . 5 Operation Proc essing Me thod of PLC Functi on The operation processing method is the repeated operation of a stored program. (1) S tored program system 1) In a stored program s ystem, a sequence program to be operated is stored in the internal memory beforehand. 2) When sequence program opera[...]
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Seite 74
69 I/O Processing M ethod 3 SEQUENCE PROGRAMMING 3.6 I/O Processing Method The control system is a refresh system. 3.6.1 What is ref resh syst em? In the refresh system, control input termi nal changes are batch-imported into the input data memory of the CPU before execution of each scan, and the data of this input data memory are used as the input[...]
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Seite 75
70 I/O Processing Met hod 3.6.2 Response delay in refres h system This section describes a delay of an output change in response to an input change. An output change in response to an input change has a del ay of up to two scans as shown in Fig. 2.6. Fig 3.7 Output Y Change in Response to Input X Change Ladder exa mple When Y1E turns on earliest Th[...]
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Seite 76
71 Scan Time 3 SEQUENCE PROGRAMMING 3.7 Scan Ti me (1) Scan time A scan time is a time from when s equence program operation is executed from step 0 until step 0 is executed again. The scan time of each s can is not equal, and changes depending on whether the used instructions are executed or not. Fig 3.8 Scan T ime (2) Scan time confirmation (a)Th[...]
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Seite 77
72 Numerica l Values Usable in Sequence Pro gram 3.8 Numerical V alues Usable i n Sequence Pr ogram The built-in PLC function represents numer ical values, alphabet s and other data in two statuses: 0 (OFF) and 1 (ON). The data represented by these 0s and 1s are called BIN (binary code). The built-in PLC function c an also use HEX (hexadecimal c od[...]
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Seite 78
73 Numeric al Values Usabl e in Sequen ce Program 3 SEQUENCE PROGRAMMING 3.8.1 BIN (Bin ary Co de) (1) Binary code BIN is a numerical value represented by 0s (OFF) and 1s (ON). In the decimal code, a number is incremente d from 0 to 9, and at this point, a carry occurs and the number is incremented to 10. In BIN, 0, 1 are followed by a carry , and [...]
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Seite 79
74 Numerica l Values Usable in Sequence Pro gram the range -32768 to 32767. Therefore, each register of the built -in PLC function can store any value between -32768 and 32767. 3.8.2 HEX (HEX De cimal ) (1) HEX HEX represents four bit s of BIN data as one digit. Using four bits in BIN, y ou can represent 16 values from 0 to 15. Since HEX represents[...]
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Seite 80
75 Description of devices 3 SEQUENCE PROGRAMMING 3.9 Description of devices 3.9.1 Device List The following table i ndicates the device nam es usable with the built-in PLC function and their ranges of use. T able 3.3 Device List Input (X) 6 4 (X0 to X3F) <12 points installe d> Output (Y) 64 (Y0 to Y3F) < 7 points in stalle d> Interna l [...]
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Seite 81
76 Description of devices 3.9.2 Inputs, Outputs X, Y Inputs and outputs are devices designed to transfer data between the inverter and external devices. Inputs provide ON/OFF data gi v en to the corresponding control input terminals from outside the inverter . In a program, they ar e used as c ontact s (normally open, normally closed contact s ) an[...]
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Seite 82
77 Description of devices 3 SEQUENCE PROGRAMMING (1) Input s X (a) Inputs are designed to give commands and data from external dev ices, such as pushbuttons, selec t switches, limit switch es and digital switches, to the inverter (built-in PLC function). (b) On the assumption that the PLC function cont ains a virtual relay Xn for one input point, t[...]
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Seite 83
78 Description of devices (2) O ut puts Y (a) Outputs are designed to output the control results of a program to outside the inverter (signal lamps , digital in dicators, magnetic switches (contactors), solen oids, et c.). (b) An output c an be exported to outside the inverter as equivalent to one N/O contact. (c) There are no restrictions on the n[...]
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Seite 84
79 Description of devices 3 SEQUENCE PROGRAMMING 3.9.3 Internal Relays M Internal relays are auxiliary relays that are used in the PLC function and cannot latch data (backup for power failure). All internal relays are turned of f when: • Power is switched from off to on; or • Res et is performed. There are no res trictions on the number of cont[...]
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Seite 85
80 Description of devices 3.9. 4 T imers T The timers of the PLC function are count up timers. The count up timer starts timin g the present value when its coil turns on, and the contact of that timer turns on when the present value reaches the set ting (time-out). 3.9.5 100 ms, 10 ms an d 100m s re tenti ve ti mers (1) 100ms and 10ms timers The ti[...]
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Seite 86
81 Description of devices 3 SEQUENCE PROGRAMMING (2) 100ms retentive timers 1) A 100ms retentive timer is designed to time the ON period of the timer coil . When its coil turns on, the timer start s timing the present value and maintains the present value and contact ON/OFF state i f the c oil turns off. When the coil turns on again, the time r res[...]
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Seite 87
82 Description of devices (2) Present value update timing and accuracy in refresh system 1) The timer accuracy is +2 scan times independently of the used timer and scan time. 2) The follow ing shows the present value update timing and accuracy when the 10ms timer is used in a program where the scan time is 10ms or more. Fig 3.17 T imer Timing Metho[...]
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Seite 88
83 Counte rs C 3 SEQUENCE PROGRAMMING 3.10 Counters C The counters of the built-in PLC function are up counters. An up counter stop s counting and it s contact turns on when the count value reaches the setting. (1) Count processing 1) The coil of the counter is turned on/off at execution of the OUT C instruction, and its present value is updated an[...]
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Seite 89
84 Counters C 3.10.1 Count processing in refre sh system The counter counts on the leading edge of the input condition of the counter imported at an input refresh. Fig 3.19 Counter Counting Method Ladder exampl e Counting meth od REMARKS Refer to pa ge 85 f or the maxi mum co unting speed of the co unte r . When OFF t o ON of X5 is counte d twice, [...]
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85 Counte rs C 3 SEQUENCE PROGRAMMING 3.10.2 Maximum counting spee d of counter The maximum counting speed of the counter is determined by the scan time, and the counter can count only when the ON/OFF period of the input conditi on is longer than the scan time. REMARKS The du ty n is a percent (%) r atio of ON/OF F peri od to (ON + OF F period ) of[...]
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Seite 91
86 Data Registers D 3.1 1 Dat a Registers D (1) Data registers are memories that can store numerical dat a (-32768 to 32767 or H0000 to HFFFF) in the built-in PLC function. One point of data register c onsists of 16 bits and allows data to be read/wri tten in units of 16 bit s . Fig 3.20 Data Register S tructure (2) The data stored once by the sequ[...]
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Seite 92
87 Special Relays, Special Registers 3 SEQUENCE PROGRAMMING 3.12 S p ecial Relays , Special Regist ers S pecial relays and s pecial registers are internal relays and data registers, respectively , whose applications are predetermined by the built-in PLC functions. They have the following main applications. (1) Sequence operation check The special r[...]
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Seite 93
88 Special Relays, Sp ecial Registers T able3.4 S pecial Relay Application List Item S pecial Relay Application /Description Initia l process ing fla g (1 s can ON) M9038 (1) T his re lay tur ns on fo r one sc an when t he built -in PLC f unct ion switches from STOP to RUN. (2) U sing M 9038 , you ca n crea te a seq uence p rogra m to be execu ted [...]
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Seite 94
89 Func tion Lis t 3 SEQUENCE PROGRAMMING 3.13 Function L ist Function De scription Remote RUN/STOP • This func tion per forms re mote RUN/STOP from outsid e the inver ter wh en SQ -SD are shor ted ( PLC fun ction in RUN status (P .RUN lit)). W atc hdog tim er va riab le (10 to 200 0ms ) • The wa tchd og timer i s an inte rnal timer of the sequ[...]
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Seite 95
90 How to RUN/S TOP the Bui lt-in PLC Func tion from Outside (Remote RUN/STOP) 3.14 How to RUN/STOP the Built-in PLC Function from Out sid e (Remote RUN/STOP) The built-in PLC function is RUN/STOPped by shorting/opening SQ-SD. Remote RUN/ST OP is to RUN/ST O P the built-in PLC function from outside the inverter with SQ-SD shorted ( RUN status). (1)[...]
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Seite 96
91 How to RUN / STOP the Built-in PLC Function from Outsi de (Remo te RUN/STOP) 3 SEQUENCE PROGRAMMING 2) Method using GX Developer RUN/ST OP can be perfo rmed by remot e RUN/ST OP operation from GX Devel oper . For example, this meth od can be used to ST OP the function for sequence program write in a place where the inverter is out of reach. Fig [...]
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Seite 97
92 Watchdo g Time r ( Oper at ion cl og up moni tor t imer ) 3.1 5 W atchdog T imer (Operation clog up monitor timer) (1) W atchdog timer A watchdog timer is the internal timer of the built-in PLC function designed to detect hardware or sequence program faults. Its default value is set to 200ms. (2) W atchdog timer resetting The built-in PLC functi[...]
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Seite 98
93 Self- diagno stic F unction 3 SEQUENCE PROGRAMMING 3.16 Self-d iagnostic Fun ction The self-diagnostic function diagnoses faults by the built-in PLC function its el f. (1) Self-diagnostic timing The self-diagnostic function is performed at po w er-on, at reset, at execution of any instruction, or at execution of the END instruction. 1) At power-[...]
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Seite 99
94 Self- diagnost ic Fu nction 3.16.1 Error-time operation mode The built-in PLC function allows you to set whether the sequence program operation will be stopped or continued at occurrence of an operation error . Use the built-in PLC function parameter to set whether operation will be stopped or continued. z Default value of error-time operation m[...]
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Seite 100
95 Keyword Re gistrat ion 3 SEQUENCE PROGRAMMING 3.17 Keyword Registrati on The keyword is designed to inhibit the read and rewrite of the program and comment s in the built-in PLC function using GX Developer . (1) Read/write from built-in PLC function where keyword has been registered When the keyword has been registered, the built-in PLC function[...]
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Seite 101
96 Setting of O utput (Y) S tatus at Switching from STOP Statu s t o RUN Stat us 3.18 Settin g of Outp ut (Y) St atus at Swi tching from STOP St atu s to R UN St atu s When the RUN status is switched to the STOP status, the outputs (Y) in the RUN status are stored into the built-in PLC function. Using the built-in PLC function parameter , you can s[...]
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Seite 102
97 Instruct ion Forma t 3 SEQUENCE PROGRAMMING 3.19 Instruction For mat (1) Many of the instructions can be divided into an instruction p art and a device, and their applications are as described below . (2) The instruction format can be roughly classified as follows according to the instruction part and device combinations. 1) .....This instructio[...]
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Seite 103
98 Instruction Format (3) Source (S) The source contains the data to be us ed for operation. The data changes depending on the specified device. (4) Destination (D) The destination stores the data resulting from operation. Note that if the format consists of + + , the data to be used for operation must have been stored into the destination before o[...]
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Seite 104
99 Bit Device Processing M ethod 3 SEQUENCE PROGRAMMING 3.20 Bit Device Processing Method As the processing met hod when the bit device (X, Y , M) is specified, 1-bit proc essing and 16-bit processing using digit designation processing are available. 3.20.1 1-bit processing When a PLC instruction is us ed, the device used as the target of operati o[...]
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Seite 105
100 Bit Device Processing M ethod Fig 3.26 Ladder Example and Processing (b) When there is digit designation on the destination (D) side, the number of points specified by digit designation is the t arget on the destination side. Fig 3.27 Ladder Examples and Processingse Ladder Exampl e Processing For 16 -bit in str ucti on Ladder Ex ample Processi[...]
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Seite 106
101 Handlin g of Numerical Val ue 3 SEQUENCE PROGRAMMING 3.21 Handling of Numerical V alue The built-in PLC function has instructions that handle numerical values indicated in 16 bits. The most significant bit of the 16 bits is used to judge whether the value is positive or negative. Therefore, the numerical v alues that can be handled as 16 bits a[...]
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Seite 107
102 Operation Error 3.22 Operat ion Error When a basic instruction is used, an operation error will occur in the following case. (a) If any error described in the description of the corresponding instruction occurs. (1) Error proces sing If an operation error occurred at execution of a basic instruction, the error flag turns on and the error step n[...]
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Seite 108
103 Instructions List 3 SEQUENCE PROGRAMMING 3.23 Instructions List 3.23.1 How to use th e instruction lis t 1)....... Classifies the instruction by application. 2)....... Indicates the instruction symbol used for programming. The instructions are based on 16-bit data instructions. Example MOV ↓ 16-bit transfer instruction • Add P to the end of[...]
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Seite 109
104 Instructions List 4) ....... Indicates the operation. 5) ....... Indicates the condition of executi on for each instruction as described below: 6) ....... Indicates the number of program steps required for each instruction. The number of steps that changes depending on conditi ons is two. Symbol Execution Co ndition No entr y The inst ruc tion [...]
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105 Instructions List 3 SEQUENCE PROGRAMMING 3.23. 2 Sequ enc e ins tru ctio n Classi ficat ion Instruction Symbol Symbol Proc essing Executi on Conditi on Number of Steps Reference p age Cont acts Logic al opera tio n start (Ope ration start at N/O contact) 1 111 Logical NOT operation start (Operation start at N/C contact) 1 Logic al produ ct (N/O[...]
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Seite 111
106 Instructions List Master contr ol Master control start 5 133 Master control rese t 3 Program end — Mus t be writte n at the end of sequence progr am to r eturn t o step 0. 11 3 7 No operat ion — No operat ion For program d elet ion or sp ace 11 3 8 — No operat ion Line feed in stru cti on for pr inte r output 1- Classi ficat ion Instr uct[...]
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Seite 112
107 Instructions List 3 SEQUENCE PROGRAMMING 3.23.3 Basic i nstructions Clas sific atio n Instruct ion Sym bol Sym bol Processing Executi on Conditi on Number of Steps Reference p age 16-bit dat a compar ison Continuity when (S1) = (S2) Non-continuity when (S1) ≠ (S2) 5 140 7 5 7 5 7 Continuity when (S1) ¼ (S2) Non-conti nuity when (S1 ) = (S2) [...]
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Seite 113
108 Instructions List BIN 16-bit addi tion/ subtr action (S) + ( D) → (D) 5 145 5 (S1) + ( S2) → (D) 7 7 (S) - (D) → (D) 5 5 (S1) - (S2 ) → (D ) 7 7 BIN 16 bit mul tipli cat ion /di vis io n (S1) x ( S2) → (D+1 , D) 7 149 7 (S1) / (S 2) → Quo tient (D) ,Remai nder (D+1) 7 7 Clas sific ation I nstruction Sym bol Symb ol Processing Execut[...]
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Seite 114
109 Instructions List 3 SEQUENCE PROGRAMMING 3.23.4 Application instructions Clas sific atio n Instruction Sym bol Sym bol Process ing Executi on Conditi on Number of Steps Reference p age Logica l prod uct (D) A ND (S) → (D ) 5 156 5 (S1) AN D (S2) → (D) 7 7 Logica l sum (D) OR (S ) → (D ) 5 159 5 (S1) OR (S2) → (D) 7 7 Exclusi ve logica l[...]
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Seite 115
11 0 Description of the Instructions 3.24 Description of the Instructions In Chapter 6, the instructions are described in the following format. Descriptio n 1) Indicates the section number , instruction outlines and instruction symbols. 2) The devices usable with the instructions are marked. 3) The digit designation that can be set is indi cated fo[...]
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Seite 116
111 Sequence Instructions 3 SEQUENCE PROGRAMMING 3.25 Sequence Instructions Sequence instructions are used for relay control circuits, etc. 3.25. 1 Contac t Inst ruct ions : Operation start, se ries connection, paral lel connection ... LD, LDI, AND, ANI, OR, ORI Usable Devices Digit Desig natio n Error Flag Bit devices Word (16-bit) devices Constan[...]
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Seite 117
11 2 Sequence I nstructions Functions (1) LD is an N/O contact operation start instruction, and LDI is an N/C contact operation start instruction. Each of them imp or ts the ON/OFF dat a of the specified device and uses it as an operation result. (1) AND is an N/O contact series connection instruction, and ANI is an N/C cont ac t series connection [...]
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Seite 118
11 3 Sequence Instructions 3 SEQUENCE PROGRAMMING Program Examples , , , , , 3.25.2 Contact Instructions : Ladder block serie s connection, parallel connection .. . ANB , ORB Usable Devices Digit Desig natio n Error Flag Bit devices Word (16-bit) devices Constants L evel X YMT CDKHN ( M 9010,M901 1) LD LDI AND ANI OR ORI ORB ANB Coding ・ Coding ?[...]
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Seite 119
11 4 Sequence I nstructions Block A Block B Use OR or O RI to connect contacts in parall el. Block A Block B[...]
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Seite 120
11 5 Sequence Instructions 3 SEQUENCE PROGRAMMING Functions (1) ANDs blocks A and B and uses the resultant value as an operation result. (2) The symbol of ANB is not a contac t s ymbol but a connection symbol. (3) ANB can be written up to seven instructions (eight blocks) consecutively . If ANB is written consecutively more than the above, the PLC [...]
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Seite 121
11 6 Sequence I nstructions Program Examples Though there are the following two dif ferent program c oding methods for connecting ladder blocks in series consecutively , use the coding example 1. Though there are the following two dif ferent program c oding methods for connecting ladder blocks in parall el c onsecutively , use the coding example 1.[...]
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Seite 122
11 7 Sequence Instructions 3 SEQUENCE PROGRAMMING 3.25.3 Connection Instructions : Ladder block se ries connecti on, paral lel connection ... ANB, ORB Usable Devices Digit Desig natio n Error Flag Bit devices Word (16-bit) devices Constants L evel X YMT CDKHN ( M 9010,M901 1) Block A Block B Use OR or O RI to connect contacts in para llel. Block A [...]
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Seite 123
11 8 Sequence I nstructions Functions (1) ANDs blocks A and B and uses the resultant value as an operatio n result. (2) The symbol of ANB is not a cont act symbol but a connection symbol. (3) ANB can be written up to seven instructions (eight blocks) consecutively . If ANB is written consecutively more than the above, the PLC c annot per form norma[...]
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Seite 124
11 9 Sequence Instructions 3 SEQUENCE PROGRAMMING Program Examples Though there are the following two dif ferent program coding methods for connecting ladder blocks in series consecutively , use the coding example 1. Though there are the following two dif ferent program coding methods for connecting ladder blocks in parallel c onsecutively , use th[...]
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Seite 125
120 Sequence I nstructions 3.25.4 Connection Instructions : Operation result, push, re ad, pop ... MPS, MRD, MPP Functions (1) S tores the operation result (ON/OFF) immediately before itself. (2) The MPS instruction can be used consecutively up to 12 times. In the ladder mode, however , it can be used up to 1 1 times. When the MPP instruction is us[...]
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Seite 126
121 Sequence Instructions 3 SEQUENCE PROGRAMMING POINT (1) L adders d iffer as shown below b etwee n when MPS, MR D and M PP are used and wh en th ey are not us ed. (2) Use the sa me numb er of MP S and MP P instru ctio ns. If t hey di ffer in the numb er of used instr uctio ns, ope rati on wil l be perf orme d as de scribe d belo w . 1) If t he MP[...]
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Seite 127
122 Sequence I nstructions Program Example , , 1) Program using MPS, MRD and MPP MPS MRD MPP 1) 2) 3) 4) 5) 6) 7) 8) 9) 10) 1) 2) 3) 4) 5) 6) 7) 8) 9) 10) Coding ・[...]
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Seite 128
123 Sequence Instructions 3 SEQUENCE PROGRAMMING 3.25.5 Output Instructions : B it device, timer , counter ... OUT Functions (1) Outputs the operation result up to OUT instruction to the specified device. Usable Devices Digit Designation Error Flag Bit devi ces Word (16 -b i t) devices Const an t s Level X YMT CD KH N (M 9010, M901 1) Bit devic e {[...]
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Seite 129
124 Sequence I nstructions (1) When the operation result up to the OUT instruction is ON, the coil of the timer turns on and the timer times up to the setting, and when the timer times out (timing value ≥ setting), the contac t operates as indicated below . (2) When the operation result up to the OUT instruction turns from ON to OFF , the timer o[...]
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Seite 130
125 Sequence Instructions 3 SEQUENCE PROGRAMMING Program Examples 1) Program that outputs to the output module. 2) Program that turns on Y10 and Y14 10s after X0 has turned on. 3) Program that turns on Y0 when X0 turns on 10 times and turns off Y0 when X1 turns on. 4) Program that changes the C0 s etting to 10 when X0 turns on and to 20 when X1 tur[...]
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Seite 131
126 Sequence I nstructions 3.25.6 Output Inst ructions : Devi ce set, reset ... SET , RST Functions (1) T ur ns on the specified device when the SET input turns on. (2) The device turned on is held on if the SET input turns of f. It can be turned off by the RST instruction. (3) When the SET input is off, the device st atus does not change. (1) When[...]
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Seite 132
127 Sequence Instructions 3 SEQUENCE PROGRAMMING (3) The function of RST (D) is the same as that of the following ladder . Execution Condi tions The SET and RST instructions are executed every scan. Program Examples , 1) Program that sets (turns on) Y8 when X8 turns on and resets (turns of f) Y8 when X9 turns on. Operations of SET and RST instructi[...]
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Seite 133
128 Sequence I nstructions 2) Program that resets the data regis ter contents to 0. 3) Program that resets the 100ms retentive timer and counter . Stores X10 to 1F conten ts into D8 when X0 turn s on . Resets D8 contents to 0 w hen X5 tu rns on. Coding When T5 is set as rete ntive timer, T5 turns on when ON period o f X4 reaches 30 min utes. Counts[...]
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Seite 134
129 Sequence Instructions 3 SEQUENCE PROGRAMMING 3.25.7 Output Instructions : Leading edge, trailing edge diffe rential outputs ... PLS, PLF Functions (1) Turns the specified device on when the PLS command turns from OFF to ON, and turns it off except when the PLS command turns from OFF to ON. When there is one PLS instruction for the device specif[...]
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Seite 135
130 Sequence I nstructions (1) T ur ns the specified dev ice on one scan when the PLF command turns from ON to OFF , and turns it off except when the PLF command turns from ON to OFF . When there is one PLF instruction for the device specified at during one scan, the specified device turns on for one scan. Do not execute the PLF instruction for the[...]
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Seite 136
131 Sequence Instructions 3 SEQUENCE PROGRAMMING 3.25.8 Shift Instructi ons : Bit device shift ... SFT , SFTP Functions (1) Shift s the ON/OFF status of the device preceding the one specified at to the specified device, and turns off the preceding devi ce. (2) Use the SET instruction to turn on the first device from which data wil l be shifted. (3)[...]
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Seite 137
132 Sequence I nstructions Program Example 1) Program that shifts the Y7 - B dat a when X8 turns on. SFT Execu tes shi ft s when X8 tur ns on. Program in orde r of larger to smaller device numbers. Turns on Y 7 when X7 tur ns on. X 8 X 7 Y 7 Y 8 Y 9 Y A Y B Coding[...]
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Seite 138
133 Sequence Instructions 3 SEQUENCE PROGRAMMING 3.25.9 Maste r Control Instr uctions : Ma ster cont rol set, rese t ... MC, MC R Functions (1) The master control instructions are designed to create an ef ficient ladder switching sequence program by switching on/of f the common bus of the ladder . The ladder that uses master control is as shown bel[...]
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Seite 139
134 Sequence I nstructions (1) When the MC ON/OFF command is on at the start of master control, the operation results between MC and MCR are as performed by the instruc tions (ladder). (2) If the MC instruction is off, the scan between the MC and MCR instructions is executed, and therefore, the scan time does not become short. When the MC instructi[...]
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Seite 140
135 Sequence Instructions 3 SEQUENCE PROGRAMMING (1) This instr uction is designe d to r eset t he mast er contr ol and indicate s the e nd of the master control r ange. (2) Do not provide a contact ins truction in front of the MCR instruction. The master control instructions can be nested. Their master control ranges are differentiated by the nest[...]
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Seite 141
136 Sequence I nstructions Note the following when nesting the instructions . (1) The instructions can be nested to a level of eight (N0 to 7). When nes ting them, use MC from lower to higher nesting (N) numbers and MCR from higher to lower numbers. In the opposite order , the PLC function cannot perform normal operation since the instructions cann[...]
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Seite 142
137 Sequence Instructions 3 SEQUENCE PROGRAMMING 3.25.10 End Instruction : Sequence program end ... END Functions (1) Indicates the end of a program. Execution terminates scanning at this step and returns to step 0. (2) The END instruction cannot be used halfway through the sequence program. Usable Devices Digit Designation Error Flag Bit devices W[...]
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138 Sequence I nstructions 3.25.1 1 O ther Instructions : No operation ... NOP Functions (1) No-operation instruction that has no influence on the preceding operation. (2) Use NOP to: 1) Provide space for debugging of a seq uence program. 2) Delete an instruction wi thout changing the number of step s. (Change the instruction for NOP) 3) Delete an [...]
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139 Sequence Instructions 3 SEQUENCE PROGRAMMING Program Examples 1) Contact short-circuit (AND, ANI) 2) Contact short-circuit (LD, LDI) .......Note that if LD or LDI is replaced by NOP , the ladder will be completely changed. NOP Before change Replaced by NOP. Afte r change Coding Coding Replaced b y LD T3. Before chang e Replaced by NOP. After ch[...]
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140 Basic Instructions 3.26 Basic Instructi ons The basic instructions can handle numerical dat a represented in 16 bits . 3.26.1 Comparison Operation Instructions (1) The comparis on operation instruction is handled as a cont act, comp ares the magnitudes of two pieces of data (e.g. =, >, <), and turns on when the condition holds. (2) Use th[...]
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141 Basic Instructions 3 SEQUENCE PROGRAMMING CAUTION The c omparison inst ruction regards the s pecifi ed data as BIN valu es. Hence , if the value whos e most signi ficant bit (b 15) is 1 (8 to F) is sp ecified for com parison of hex adecimal data, it is regarded as a negative BIN value. Comparison of 4-digit HEX values Theref ore, the res ult is[...]
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142 Basic Instructions 3.26.2 Comparison Operation Instructions : 16-bit data comparis on ... =, <>, >, <=, <, >= Functions (1) Handled as an N/O contact and performs 16-bit comparison operation. (2) The comparison operation results are as indicated below . Execution Condi tions The execution conditions of LD , AND and OR are as i[...]
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143 Basic Instructions 3 SEQUENCE PROGRAMMING Program Examples 1) Program that compares the X0-F data an d D 3 data. 2) Program that compares the BCD value 100 and D3 dat a. 3) Program that compares the BIN value 100 and D3 dat a. 4) Program that compares the D0 and D3 dat a. REMARKS Seven st eps are use d when: • The di git desig nati on o f a b[...]
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144 Basic Instructions 3.26.3 Arithmetic Oper ation Instructions The arithm etic op erati on inst ructions ar e instru ction s whi ch perform the additio n, subtr action, mul tiplic atio n, an d divi sion of two BIN d ata. (1) Arithmetic operation with BIN (Bi nary) • If the operation r esult of an addition instruction ex ceeds 32767 , the result[...]
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145 Basic Instructions 3 SEQUENCE PROGRAMMING 3.26.4 Arithmetic Opera tion Instructions : BIN 16-bit addition, subtraction .. . +, +P , -, -P Usable Devices Digit Designation Error Flag Bit devices W ord (16-b it) devices Const an t s Level X YMT CD KH N (M9010, M901 1) {{{{{{ {{ K1 to K4 { {{{{{ {{{{{{ {{ {{{{{{ {{ {{{{{ S D S1 S2 D1 Addition/subt[...]
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146 Basic Instructions Functions (1) Performs the addition of BIN data specifies at and the BIN data specified at , and stores the addition result into the device specified at . (2) Performs the addition of BIN data specified at and the BIN data specified at , and stores the addition result into the device specified at . (3) At , , and , -32768 to [...]
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147 Basic Instructions 3 SEQUENCE PROGRAMMING Functions (1) Performs the subtraction of BIN data specifies at and the BIN dat a specified at , and stores the subtracti on result into the device specified at . (2) Performs the subtraction of BIN data specified at and the BIN data specified at , and stores the subtraction result into the device speci[...]
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148 Basic Instructions Execution Condi tions Addition/subtraction command. Program Examples Program which adds the content of A0 to the content of D3 and outputs the result to Y38 to 3F when X5 turns on. Program which outputs the difference between the set value and present value timer T3 to Y40 to 53 in BCD. A ddition/subtraction command Executed [...]
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Seite 154
149 Basic Instructions 3 SEQUENCE PROGRAMMING 3.26.5 Arithmetic Opera tion Instructions : BIN 16-bit multiplication, div ision ... *, *P , /, /P Usable Devices Digit Desi gnat ion Error Flag Bit devices Word (16-bit) devi ces Con st ants Level X YMT CDKH N (M9010, M901 1) {{{{{{{ { K1 to K4 { {{{{{{{ { {{{{{ S1 S2 D Multiplication/division commands[...]
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150 Basic Instructions Functions (1) Performs the multiplication of BIN dat a specified at and the BIN data s pecified at , and stores the multiplication result into the device specified at . (2) When is a bit device, specify the bits, beginning with the lower bits. Example K1: Lower 4 bits (b0 to 3) K4: Lower 16 bits (b0 to 15) (3) At and , -32768[...]
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151 Basic Instructions 3 SEQUENCE PROGRAMMING (1) Performs the division of BIN data specified at and the BIN data specified at , and stores the result into the device specified at . (2) In regards to the operation result, the quotient and remainder are stored by us e of 32 bits i n the case of word devic e, and only the quotient is stored by use of[...]
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152 Basic Instructions Operation Er rors In the following case, operation error occurs and the error flag tur ns on. • A1 or V has been specified at . • The divisor is 0. Program Examples 1) Program which stores the multiplication result of 5678 and 1234 in BIN to D3 and 4 when X5 turns on. 2) Program which outputs the multiplication result of [...]
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153 Basic Instructions 3 SEQUENCE PROGRAMMING 3.26.6 Data T ransfer Instruct ions The data transfer instructions are designed to transfer data. The da ta mov ed by the d ata tra nsfer in struct ion is m ainta ined unti l new dat a is tran sferr ed. 3.26.7 Data T ransfer Inst ructions : 16-bit da ta transf er ... MOV , MOVP Functions T ransf ers the[...]
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154 Basic Instructions Program Examples 1) Program that stores the input X0-B data into D8. 2) Program that stores 155 into D8 in binary when X8 turns on. MOV MOV P Transf e r command Execute d every scan. Executed every scan . Execute d only once. Executed o nly once. MOV Coding Coding[...]
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155 Application instructions 3 SEQUENCE PROGRAMMING 3.27 Application instructi ons Application instructions are used when special processing is requi red. 3.27.1 Logical Operation Inst ructions (1) The logical operation instructions are inst ructions which perform the logical operations such as logical add and logical product. (2) The logical opera[...]
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156 Application instructions 3.27.2 Logical Operation I nstructions : 16-bit Logical Product ... W AND, W ANDP Functions (1) ANDs the 16-bit data of the device specified at and the 16-bit data of the device specified at on a bit-by-bit basi s, and stores the result into the device specified at . Usable Devices Digit Designation Error Flag Bit devic[...]
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157 Application instructions 3 SEQUENCE PROGRAMMING (2) ANDs the 16-bit data of the device specified at and the 16-bit data of the device specified at on a bit-by- bit basis, and stores the result into the device specified at . (3) More than the digit designation of a bit device is regarded as 0 for operati on. Execution Condi tions The execution c[...]
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158 Application instructions 2) Program that ANDs the X10-1B and D33 data and outputs the result to Y0-B when XA turns on. 3) Program that ANDs the X10-1B and D33 data and outputs the result to Y0-B when XA turns on. ANDs X10 -1B data and D33 data and stor es result t o D33. Output s D33 data to Y 0-F. Coding X1B to 10 D33 X1B X1 A X 19 X 18 X 17 X[...]
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159 Application instructions 3 SEQUENCE PROGRAMMING 3.27.3 Logical Operation Inst ructions : 16-bit Logical Add ... WOR, WORP Functions (1) ORs the 16-bit data of the device spec ified at and the 16-bit data of the device specified at on a bit-by-bit basis, and stores the result into the device specified at . Usable Devices Digit Designat ion Error[...]
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160 Application instructions (2) ORs the 16-bit data of the device specified at and the 16-bit data of the dev ice specified at on a bit-by-bit basis, and stores the result into the device specified at . (3) More than the digit designation of a bit device is regarded as 0 for operati on. Execution Condi tions The execution conditions of the logical[...]
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161 Application instructions 3 SEQUENCE PROGRAMMING 2) Program that ORs the X10-1B and D33 data and outputs the result to Y0-F when XA turns on. 3) Program that OR s the D10 and D20 data and stores the result into D33 when XA turns on. 4) Program that ORs the X10-1B and D33 data and outputs the result to Y0-B when XA turns on. ORs X10- 1B and D33 a[...]
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Seite 167
162 Application instructions 3.27.4 Logical Operation I nstructions : 16-bit Exclusi ve Lo gical Add ... WXOR, WXORP Usable Devices Digit Designation Error Flag Bit devices Word (16-bit) device s Const ants Level X YMTCDKH N (M9010, M901 1) WXOR {{{{{{ {{ K1 to K4 { {{{{{ {{{{{{ {{ {{{{{{ {{ {{{{{ S D S1 S2 D1 WXORP Operation commands Operation com[...]
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163 Application instructions 3 SEQUENCE PROGRAMMING Functions (1) Performs the exclusi ve OR of the 16-bit data of device spec ified at and the 16-bit data of device specified at per bit, and stores the result into the device specified at . (2) Performs the exclusive OR of the 16-bit data of devic e specified at and the 16-bit data of device s peci[...]
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164 Application instructions Program Examples 1) Program which performs exc lusive OR of the data of D10 and that of D20, and stores the result to D10 when XA turns on. 2) Program which performs the exclusive OR of the data of X10 to 1B and data of D33, and sends the result to the Y30 to 3B when XA turns on. 3) Program which performs exc lusive OR [...]
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165 Application instructions 3 SEQUENCE PROGRAMMING 3.27.5 Logical Operation Inst ructions : 16-bit NOT Exclusi v e Logical Add ... WXNR, WXNRP Usable Devices Digit Designat ion Error Flag Bit devices Word (16-bit) devices Const ants Level X YMTCDKH N (M9010, M901 1) WXNR {{{{{{ {{ K1 to K4 { {{{{{ {{{{{{ {{ {{{{{{ {{ {{{{{ S D S1 S2 D1 WXNRP Opera[...]
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166 Application instructions Functions (1) Performs the exclusive NOR of the 16-bit data of device specifi ed at and the 16-bit data of device specified at per bit, and s tores the result into the device specified at . (2) Performs the exclusive NOR of the 16-bit dat a of device specified at and the 16-bit data of device specified at per bit, and s[...]
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Seite 172
167 Application instructions 3 SEQUENCE PROGRAMMING Program Examples 1) Program which compares the bit p attern of the 16-bit data of X 30 to 3F and tha t of the 16-bit data of D99 and stores the number of the same bit patterns and the number of different bit patterns to D7 and 8, res pectively , when XC turns on. 2) Program which compares the bit [...]
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Seite 173
168 Application instructions 3.27.6 Logical Operation I nstructions : BIN 16-bit 2’s complement ... NEG , NEGP Functions (1) Reverses the sign of the 16-bit data of device specified at and stores the result in device specified at . (2) Used to reverse the positive sign to the negative sign and vice versa. Usable Devices Digit Designation Error Fl[...]
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169 Application instructions 3 SEQUENCE PROGRAMMING Execution Condi tions Program Examples 1) Program which c alculates "D10 - D20" when XA turns on, and obtains the absolute value when the result is negative. NEG NEG NEGP 2's complement execution command Executed every scan. Executed only once. Executed only once. Executed every sca[...]
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170 MEMO[...]
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171 Cha pt e r 1 Cha pt e r 2 Cha pt e r 3 Cha pt e r 4 4. ERROR CODE LIST 4.1 How t o Re ad the E rr or C ode ..... ..... .... ..... ...... ..... 172[...]
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Seite 177
172 How to Read the Error Code When the built-in PLC function is in the RUN status or if an alarm occu rs during RUN, the self-diagnostic function displays the error and stores the error code and error step into the special registers. This chapter describes the error definitions and c orrective actions. 4.1 How to Read the Error Code When an error [...]
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173 How to Read the Error C ode 4 ERROR CODE LIST “OPERA TI ON ERROR” [Che cked at instru cti on executi on] 50 Run (S top) Divide d by zero Read the er ror step by use of periph eral dev ice, and chec k and correct th e program at that step. Error Name Error Code (D9008 ) St atus Definition and Cause Correc tive Action[...]
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174 MEMO[...]
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175 APPENDIX Appendix1Instr uction Processi ng Ti me ............ ........ 176[...]
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176 Instruction Processing Time Appendix1 Instruction Processing Time Instru ctio n Condi tion (Devic e) Numbe r of Ste p s Proc ess ing Time ( µ s) LD 1 2.6 LDI 1 2.7 AND 1 2.8 ANI 1 2.8 OR 1 2.7 ORI 1 2.8 ORB 1 2.0 ANB 1 2.0 MPS 1 1.9 MRD 1 1.9 MPP 1 2.0 MC 5 3.7 MCR 3 2.4 NOP 1 2.1 NOPLF 1 2.1 END 1 1.3 PLS 3 3.6 PLF 3 3.5 SFT 3 3.6 SFTP 3 4.1 [...]
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177 Instruction Processing Time OR<> 7 8.2 OR> 5 7.5 OR> 7 8.2 OR<= 5 7.5 OR<= 7 8.2 OR< 5 7.5 OR< 7 8.2 OR>= 5 7.6 OR>= 7 8.2 +5 1 0 . 3 +P 5 10.7 +7 1 0 . 3 +P 7 10.7 -5 1 0 . 3 -P 5 10.7 -7 1 0 . 4 -P 7 10.8 *7 1 0 . 8 *P 7 1 1.3 /7 1 1 . 3 /P 7 1 1.8 Instr ucti on Condi tion (Devic e) Numbe r of Ste p s Processin g[...]
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REVISIONS *The manual number is given on the bottom left of the back cover Print Date *Manual Number Revision Sep., 20 05 I B(NA)- 060026 2ENG-A First editi on[...]