Specifications

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V Series

Summary of content (332 pages)

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V Series
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Record of Revisions Reference numbers are shown at the bottom left corner on the back cover of each manual. Printing Date Reference No.
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Preface Thank you for selecting the MONITOUCH V7 series. For correct set-up of the V7 series, you are requested to read through this manual to understand more about the product. For more information about the V7 series, refer to the following related manuals. Manual Name Contents Reference No. Reference Manual (Operation) The V-SFT operating procedure is described. 1043NE Reference Manual (Function) The functions and instructions of the V7/V6 series are explained.
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Notes on Safe Use of MONITOUCH In this manual, you will find various notes categorized under the following levels with the signal words “DANGER,” and “CAUTION.” DANGER Indicates an imminently hazardous situation which, if not avoided, will result in death or serious injury. CAUTION Indicates a potentially hazardous situation which, if not avoided, may result in minor or moderate injury and could cause property damage.
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CAUTION • Check the appearance of the unit when it is unpacked. Do not use the unit if any damage or deformation is found. Failure to do so may lead to fire, damage or malfunction. • For use in a facility or for a system related to nuclear energy, aerospace, medical, traffic equipment, or mobile installations, please consult your local distributor. • Operate (or store) MONITOUCH under the conditions indicated in this manual and related manuals.
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[General Notes] • Never bundle control cables and input/output cables with high-voltage and large-current carrying cables such as power supply cables. Keep these cables at least 200 mm away from the high-voltage and large-current carrying cables. Otherwise, malfunction may occur due to noise. • Plug connectors or sockets of MONITOUCH in the correct orientation. Otherwise, it may cause a malfunction. • Do not use thinners for cleaning because they may discolor the MONITOUCH surface.
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Contents Preface Notes on Safe Use of MONITOUCH 1. Before Connecting to PLC Types of Connection............................................................................................................................ 1-1 Interface............................................................................................................................................... 1-5 Wiring (1 : 1 Connection) ........................................................................................................
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10. Hitachi PLC Available PLCs .................................................................................................................................. Communication Setting ..................................................................................................................... HIDIC-H: Switch Setting .................................................................................................................... Available Memory ...................................................
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20. SAIA PLC Available PLCs .................................................................................................................................. 20-1 Communication Setting ..................................................................................................................... 20-1 S-BUS Configuration ......................................................................................................................... 20-1 Available Memory ......................................
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31. Yamatake PLC Available PLCs .................................................................................................................................. Communication Setting ..................................................................................................................... Available Memory .............................................................................................................................. Wiring .........................................................
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Appendix 7 V-Link V-Link ........................................................................................................................................... App7-1 Wiring ........................................................................................................................................... App7-2 V-SFT Setting ............................................................................................................................... App7-4 Protocol ...........................
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1. Before Connecting to PLC 1. 1-1 Before Connecting to PLC Types of Connection There are four types of connection between MONITOUCH(es) and PLC(s). 1 : 1 Connection Outline One set of the V7 series is connected to one PLC (1 : 1 connection). The wiring diagrams and the description of settings for connection to PLCs in 1 : 1 connections can be found from Chapter 2 onward.
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1-2 1. Before Connecting to PLC 1 : n Connection (Multi-drop) Outline One V7 series is connected to multiple PLCs. (Maximum connectable PLCs: 31) V7 series CN1 Maximum length (V7 series to the terminating PLC) = 500 m RS-422/RS-485 connection PLC1 PLC2 PLC3 Notes on Connection For more information, refer to “Appendix 4, 1 : n Connection (Multi-drop).
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1-3 1. Before Connecting to PLC n : 1 Connection (Multi-link 2) Outline • One PLC is connected to a maximum of four V7 series. • An original network is created where the V7 series (Local Port 1) that is directly connected to the PLC is the master station, and other three V7 series are slave stations. Only the master station makes communications directly with the PLC, and the slave stations make communications with the PLC via the master station.
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1-4 1. Before Connecting to PLC n : 1 Connection (Multi-link) Outline • One PLC is connected to multiple V7 series. (Maximum connectable V series: 31) V7 series No. 1 V7 series No. 2 V7 series No. 3 CN1 CN1 CN1 V7 series No. “n” (n = 1 to 31) CN1 Maximum length (PLC to the terminating V7 series) = 500 m RS-422/RS-485 connection PLC • The PLC must be of the type of signal level RS-422/RS-485 with port numbers.
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1-5 1. Before Connecting to PLC Interface CN1 (D-sub 25-pin) (V7 series and V706 + DU-01) CN1 (D-sub 25-pin, female) Pin No.
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1-6 1. Before Connecting to PLC MJ2 (V706 only) MJ2 Pin No. 1 *1 2 *1 12345678 3 4 5 6 7 *1 8 *1 *1 *2 Signal Name Contents Not used Not used +SD RS-422 + send data Not used Not used −SD RS-422 − send data +5 V Externally supplied +5 V Max. 150 mA *2 SG Signal ground RD RS-232C receive data +RD RS-422 + receive data SD RS-232C send data -RD RS-422 − receive data Switch between RS-232C and RS-422 for pin Nos. 1, 2, 7, and 8 with the slide switch on the MONITOUCH.
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1-7 1. Before Connecting to PLC Connection between MJ2 and PLC There are two connection methods. • With MJ2-PLC One method uses an adaptor MJ2-PLC for connection between MJ2 and the D-sub 25-pin connector plus a PLC communication cable. For connection of a PLC communication cable, refer to the CN1 pin arrangement.
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1-8 1. Before Connecting to PLC Wiring (1 : 1 Connection) Electric shock hazard Shut the power off before connecting cables. DANGER Prepare the communication cable with the PLC on your side. Refer to the following information for the cable. For more information on the connection to respective PLCs, refer to “Chapter 2” and later. RS-232C Connection • Connect the shielded cable either to the V7 series or PLC side.
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1. Before Connecting to PLC 1-9 RS-422/485 Connection • Connect twisted pairs between +SD/−SD and +RD/−RD. • If the PLC has the terminal for signal ground (SG), be sure to connect a wire. • Connect the shielded cable either to the V7 series or PLC side. This connection diagram shows the case where the shielded cable is connected on the V7 series side. When connecting the shielded cable to the V7 series side, connect it to pin 1 of the connector or the connector case cover.
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1-10 1. Before Connecting to PLC V-SFT Setting (1 : 1 Connection) For serial communications, the following settings on the V-SFT editor are required. The settings in the [Select PLC Type] and [Comm. Parameter] dialogs are shown on the Main Menu screen of the V7 series. (For more information, refer to “Chapter 6, MONITOUCH Operations” in V7 Hardware Specifications.) PLC Selection Select the PLC that is connected.
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1-11 1. Before Connecting to PLC Choose the action to be taken against communication errors. [Comm. Err. Handling] Set error handling routine in the case that a communication error between the V7 series and the PLC occurs. [Stop] If any communication error has arisen, the communications are stopped. When restoring, use the Retry switch (found on the error screen of the V7 series). [Continuous] If any communication error has arisen, it is indicated at the top left corner on the V7 screen.
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1-12 1. Before Connecting to PLC System Memory [Read Area] and [Write Area] must be secured for communications between the V7 series and the PLC. • Setting Procedure [System Setting] → [Comm. Parameter] → [Comm. Parameter] dialog • Setting Items [Read Area] (3 words or more)* - This is the area where commands from the PLC are received for screen display changes. Consecutive three words from the specified memory address are used as “read area.
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1. Before Connecting to PLC 1-13 • SCRN_No. (n + 2) Screen number command 15 14 13 12 11 0 0 10 09 08 07 06 05 04 03 02 01 00 0 Screen number System reserved (setting [0]) Use example: To specify a screen number from the PLC: When “D0” is set for [Read Area], the screen number is written in “D2” of the PLC. Problem example: The screen display does not change when a screen number is specified from the PLC.
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1-14 1. Before Connecting to PLC [Write Area] (3 words)* This is an area where the screen status is written. Consecutive three words from the specified memory address are used as “write area.” * When you have converted GD-80 data to the V7 series data, the number of required memory addresses vary. Refer to the GD-80 User’s Manual.
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2. Allen-Bradley PLC 2.
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2-2 2. Allen-Bradley PLC SLC500 Series Item Baud rate Port Parity Setting on PLC V7 Comm. Parameter Setting 19200 bps 19200 bps 0 0 Even Even − − Channel 0 not supported − Transmission mode RS-232C Transmission code Data length 8 8 Stop bit 1 1 Full duplex (fixed) − BCC (fixed) − NO (fixed) − Setting on PLC V7 Comm.
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2. Allen-Bradley PLC SLC500 Series, Micro Logix 1000 Memory TYPE N (integer) 0 B (bit) 1 T.ACC (timer/current value) 2 T.PRE (timer/set value) 3 C.ACC (counter/current value) 4 C.PRE (counter/set value) 5 I (input) 6 O (output) 7 S (status) 8 T (timer/control) 9 C (counter/control) 10 R (control) 11 R.LEN (control/data length) 12 R.
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2-4 2. Allen-Bradley PLC SW3 (Network link communication speed) Adjust to the settings of the network you are using. No Setting Contents 1 ON 2 ON 3 ON 4 ON 5 ON 6 ON Local/remote selection No Setting Contents 1 OFF 2 OFF 3 OFF 4 OFF Data highway (57.6 kbps) Link communication speed (19.
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2. Allen-Bradley PLC SW7 (Network link selection) Switch Setting 1 2 ON OFF Contents Peer transmission link SW8 (RS-232C/RS-422 selection) Switch Setting 1 Contents 2 OFF ON RS-232C ON OFF RS-422 SLC500 Series, Micro Logix 100: Transmission Parameter Setting CPU Port Channel 0 Set up the parameters for CPU port channel 0 using the software specifically designed for this purpose.
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2-6 2. Allen-Bradley PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name D-sub 25-pin (male) PLC D-sub 15-pin (male) Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 TXD 2 RD 7 3 RXD 3 RS 4 RTS 4 CS 5 CTS 5 7 DSR 6 SG 7 DCD 8 DTR 11 SG 13 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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2. Allen-Bradley PLC Wiring Diagram 3 V706 V Series MJ2 CN1 PLC RJ-45 8-pin D-sub 25-pin (male) D-sub 9-pin (female) Signal Name Pin No. Pin No. Signal Name Pin No. *1 SHELL 1 DCD 1 SD 8 2 RXD 2 RD 7 3 TXD 3 RS 4 DTR 4 CS 5 COM 5 7 DSR 6 RTS 7 CTS 8 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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2-8 2. Allen-Bradley PLC Wiring Diagram 5 V706 V Series MJ2 CN1 RJ-45 8-pin PLC D-sub 9-pin (male) D-sub 25-pin (male) Signal Name Pin No. Pin No. Signal Name Pin No. *1 SHELL 1 CD 1 SD 8 2 RD 2 RD 7 3 SD 3 RS 4 RS 4 CS 5 GND 5 7 DR 6 RS 7 CS 8 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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2. Allen-Bradley PLC Wiring Diagram 7 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SG 5 7 TXD- 1 +SD 1 12 RXD- 2 -SD 2 13 COM 5 +RD 7 24 RXD+ 6 -RD 8 25 TXD+ 9 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 9-pin (male) * Use shielded twist-pair cables.
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2-10 2. Allen-Bradley PLC Please use this page freely.
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3. Automationdirect PLC 3.
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3-2 3. Automationdirect PLC Available Memory The available memory setting range varies depending on the PLC model. Be sure to set within the range available with the PLC to be used. Use [TYPE] when assigning the indirect memory for macro programs.
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3. Automationdirect PLC Wiring Diagram 2 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 SG 1 RD 7 3 RxD 3 RS 4 TxD 4 CS 5 SG 5 Modular connector 6-pin 654321 7 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables. Wiring Diagram 3 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No.
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3-4 3. Automationdirect PLC Wiring Diagram 4 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name D-sub 25-pin (male) PLC Pin No. Pin No. D-sub 15-pin (male) *1 SHELL 1 Signal Name Pin No. SD 8 2 TXD 2 RD 7 3 RXD 3 RS 4 0V 13 CS 5 SG 7 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables. RS-422 Wiring Diagram 5 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No.
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3-5 3. Automationdirect PLC Wiring Diagram 6 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SG 5 7 SG 7 +SD 1 12 TXD3+ 12 -SD 2 13 TXD3− 13 +RD 7 24 RXD3+ 24 -RD 8 25 RXD3− 25 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 25-pin (male) * Use shielded twist-pair cables. In case SU-6M, it is possible to use terminal blocks.
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3-6 3. Automationdirect PLC Please use this page freely.
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4. Baldor PLC 4. 4-1 Baldor PLC Available PLCs Select PLC Type Unit/Port Connection NextMove (Comms Data Array) Mint Optimum (Comms Data Array) RS-232C [Wiring Diagram 1] Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: Item Baud rate Port Parity Transmission code Setting on PLC V7 Comm.
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4-2 4. Baldor PLC Wiring Wiring diagram with the PLC is shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name D-sub 25-pin (male) PLC Pin No. Pin No. D-sub 9-pin (female) *1 SHELL 1 Signal Name Pin No. SD 8 2 RXD 2 RD 7 3 TXD 3 SG 5 7 DTR 4 SG 5 DSR 6 RTS 7 CTS 8 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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5. DELTA PLC 5. 5-1 DELTA PLC Available PLCs Select PLC Type PLC DVP series DVP series Unit/Port RS-485 Communication port Connection RS-485 [Wiring Diagram 1] Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: Item Baud rate Port Parity Transmission code Setting on PLC V7 Comm.
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5-2 5. DELTA PLC Wiring Wiring diagram with the PLC is shown below. RS-485 Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name D-sub 25-pin (male) Pin No. Pin No. *1 SHELL 1 SG 5 7 PLC +SD 1 12 + -SD 2 13 - +RD 7 24 -RD 8 25 * Use shielded twist-pair cables. *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG.
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6. FANUC PLC 6. 6-1 FANUC PLC Available PLCs Select PLC Type PLC Power Mate-Model H/D Power Mate Unit/Port Connection Port on the CPU unit (JD14) RS-422 [Wiring Diagram 2] JD42 RS-232C [Wiring Diagram 1] JD40 RS-422 [Wiring Diagram 3] Power Mate i Model H/D Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: Item Baud rate Port V7 Comm.
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6-2 6. FANUC PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 RDB 9 RD 7 3 SDB 17 RS 4 0V 18 CS 5 SG 5 JD42 Half-pitch 20-pin 7 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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6. FANUC PLC Wiring Diagram 3 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC JD40 Half-pitch 20-pin Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SG 5 7 RXD 1 +SD 1 12 *RXD 2 -SD 2 13 TXD 3 +RD 7 24 *TXD 4 -RD 8 25 RTS 5 *RTS 6 CTS 7 *CTS 8 0V 12 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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6-4 6. FANUC PLC Please use this page freely.
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7. FATEK AUTOMATION PLC 7. 7-1 FATEK AUTOMATION PLC Available PLCs Select PLC Type PLC Unit/Port Connection RS-232 FACON FB series FACON FB series FB-DTBR RS-422 [Wiring Diagram 1] [Wiring Diagram 2] [Wiring Diagram 3] Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: Item Setting on PLC V7 Comm.
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7-2 7. FATEK AUTOMATION PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 RXD1 1 RD 7 3 TXD1 2 RS 4 RTS1 3 CS 5 CTS1 4 7 SG 6 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 15-pin (male) * Use shielded twist-pair cables.
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7. FATEK AUTOMATION PLC RS-422 Wiring Diagram 3 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name Pin No. D-sub 25-pin (male) Pin No. PLC *1 SHELL 1 Signal Name SG 5 7 D+ +SD 1 12 D- -SD 2 13 SG +RD 7 24 -RD 8 25 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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7-4 7. FATEK AUTOMATION PLC Please use this page freely.
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8-1 8. Fuji Electric PLC 8.
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8-2 8. Fuji Electric PLC FLEX-PC COM (T) (NJ Computer Link) Toyota Version Item Setting on PLC V7 Comm.
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8. Fuji Electric PLC 8-3 Available Memory The available memory setting range varies depending on the PLC model. Be sure to set within the range available with the PLC to be used. Use [TYPE] when assigning the indirect memory for macro programs.
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8-4 8.
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8. Fuji Electric PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 SD 2 RD 7 3 RD 3 RS 4 RS 4 CS 5 CS 5 7 DR 6 SG 7 CD 8 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 25-pin (male) * Use shielded twist-pair cables.
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8-6 8. Fuji Electric PLC RS-485 Wiring Diagram 3 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name Pin No. D-sub 25-pin (male) Pin No. PLC *1 SHELL 1 Signal Name SG 5 7 SDA +SD 1 12 SDB -SD 2 13 RDA +RD 7 24 RDB -RD 8 25 SG *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables. RS-422 Wiring Diagram 4 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name Pin No. D-sub 25-pin (male) Pin No.
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9. GE Fanuc PLC 9. 9-1 GE Fanuc PLC Available PLCs Select PLC Type PLC Unit/Port Connection 90 series Series 90-30 Programmable coprocessor (PCM) RS-232C RS-485 90 series (SNP-X) Series 90 micro Series 90-30 CPU port RS-485 [Wiring Diagram 1] [Wiring Diagram 2] [Wiring Diagram 3] Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: 90 Series Item Baud rate Port Parity Setting on PLC V7 Comm.
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9-2 9. GE Fanuc PLC Available Memory The available memory setting range varies depending on the PLC model. Be sure to set within the range available with the PLC to be used. Use [TYPE] when assigning the indirect memory for macro programs.
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9. GE Fanuc PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 SD 2 RD 7 3 RD 3 RS 4 RS 4 CS 5 CS 5 7 GND 7 5 SG *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 25-pin (male) * Use shielded twist-pair cables.
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9-4 9. GE Fanuc PLC Wiring Diagram 3 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SG 5 7 RTS(A) 6 +SD 1 12 0V 7 -SD 2 13 CTS(B’) 8 +RD 7 24 RT 9 -RD 8 25 RD(A’) 10 RD(B’) 11 SD(A) 12 SD(B) 13 RTS(B) 14 CTS(A’) 15 D-sub 15-pin (male) *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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10. Hitachi PLC 10.
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10-2 10. Hitachi PLC CPU Module The peripheral port setting should be “transmission control protocol 1 without port.” No other setting is available. HIDIC-S10α Item Setting on PLC V7 Comm. Parameter Setting 7 19200 bps Baud rate HIDIC-H: Switch Setting Baud rate: MODE switch: ST No switch: DIP switch 19200 bps To connect to both RS-232C and RS-422, set MODE switch to 9.
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10.
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10-4 10. Hitachi PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V Series CN1 D-sub 25-pin (male) PLC Signal Name Pin No. FG 1 Signal Name Pin No. SD 2 SD 2 RD 3 RD 3 CS 5 RS 4 SG 7 CS 5 DR 7 PHL 8 SG 9 PV12 14 D-sub 15-pin (male) * Use shielded twist-pair cables. Wiring Diagram 2 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No.
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10. Hitachi PLC Wiring Diagram 3 V706 V Series MJ2 CN1 RJ-45 8-pin PLC D-sub 25-pin (male) D-sub 9-pin (female) Signal Name Pin No. Pin No. Signal Name Pin No. *1 SHELL 1 CD 1 SD 8 2 RD 2 RD 7 3 SD 3 RS 4 ER 4 CS 5 SG 5 7 DR 6 RS 7 CS 8 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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10-6 10. Hitachi PLC Wiring Diagram 5 When connecting to the S10xα series, add a resistor of 50 Ω (1/2 W) as shown below. V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) Signal Name Pin No. Pin No. PLC *1 SHELL 1 Signal Name +SD 1 12 UTX H -SD 2 13 UTX L +RD 7 24 50 URX H -RD 8 25 50 URX L *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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11. IDEC PLC 11. 11-1 IDEC PLC Available PLCs Select PLC Type PLC Unit/Port Connection MICRO3 MICRO3 Loader port RS-232C IDEC cable “FC2A-KC1” or IDEC cable “FC2A-KC1” * + [Wiring Diagram 1] MICRO Smart MICRO Smart Loader port RS-232C IDEC cable “FC2A-KC4C” + [Wiring Diagram 1] * When using RS-232C cable “FC2A-KC2” made by IDEC, connect the cable shown in [Wiring Diagram 3] to the D-sub 9-pin side of the FC2A-KC2 cable for communications with the V7 series.
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11-2 11. IDEC PLC Wiring Wiring diagram with the PLC is shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin PLC D-sub 25-pin (male) D-sub 9-pin (male) Signal Name Pin No. Pin No. Signal Name Pin No. *1 SHELL 1 CD 1 SD 8 2 SD 2 RD 7 3 RD 3 RS 4 ER 4 CS 5 GND 5 7 DR 6 RS 7 CS 8 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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12. KEYENCE PLC 12.
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12-2 12. KEYENCE PLC Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: KZ Series Link Item Port Baud rate Parity Data length Transmission code Stop bit Terminating resistance Operation mode Setting on PLC V7 Comm.
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12. KEYENCE PLC 12-3 KV-700 CPU Item Setting on PLC V7 Comm. Parameter Setting 0 0 9600 bps 9600 bps Even − Data length 8 − Stop bit 1 − Port *1 Baud rate Parity Transmission code *1 Maximum baud rate available is 57600 bps. Select the appropriate baud rate depending on the used PLC and environment. KZ24/300 CPU Item Port 0 38400 bps 38400 bps*1 Even − Data length 8 − Stop bit 1 − Parity *1 V7 Comm.
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12-4 12. KEYENCE PLC Available Memory The available memory setting range varies depending on the PLC model. Be sure to set within the range available with the PLC to be used. Use [TYPE] when assigning the indirect memory for macro programs.
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12. KEYENCE PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 SD 2 RD 7 3 RD 3 RS 4 RS 4 CS 5 CS 5 7 SG 7 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 25-pin (male) * Use shielded twist-pair cables.
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12-6 12. KEYENCE PLC Wiring Diagram 3 V706 V Series MJ2 CN1 RJ-45 8-pin PLC D-sub 25-pin (male) Modular Connector 6-pin Signal Name Pin No. Pin No. Signal Name Pin No. *1 SHELL 1 CS 1 SD 8 2 SD 3 RD 7 3 SG 4 RS 4 RD 5 CS 5 RS 6 SG 5 7 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. 123456 * Use shielded twist-pair cables.
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12. KEYENCE PLC Wiring Diagram 5 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 RD 3 RD 7 3 SG 4 RS 4 SD 5 CS 5 5 SG Modular jack, 6-pin 123456 7 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables. RS-422 Wiring Diagram 6 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name Pin No. D-sub 25-pin (male) Pin No.
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12-8 12. KEYENCE PLC Please use this page freely.
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13. KOYO ELECTRONICS PLC 13.
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13-2 13. KOYO ELECTRONICS PLC Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: Item Baud rate Port Parity Transmission code Data length Stop bit Functions Setting on PLC V7 Comm.
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13.
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13-4 13. KOYO ELECTRONICS PLC G-01DM On-line/Off-line switch: On-line Short plug 1: open Short plug 2: RS-232C . . . . . ENABLE RS-422 . . . . . . DISENABLE SW1 DIP switch: No Setting 1 ON Contents 2 OFF 3 OFF 4 OFF 5 OFF 6 OFF 7 OFF 8 OFF 1:N 9 OFF Slave Unit No.
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13. KOYO ELECTRONICS PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 SD 2 RD 7 3 RD 3 RS 4 RS 4 CS 5 CS 5 7 SG 7 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 25-pin (male) * Use shielded twist-pair cables.
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13-6 13. KOYO ELECTRONICS PLC RS-422 Wiring Diagram 3 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SG 5 7 0V 7 +SD 1 12 +RTS 10 -SD 2 13 −RTS 11 +RD 7 24 +CTS 12 -RD 8 25 −CTS 13 +OUT 14 −OUT 15 −IN 16 +IN 17 −IN 24 +IN 25 D-sub 25-pin (male) *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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13. KOYO ELECTRONICS PLC Wiring Diagram 5 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name Pin No. D-sub 25-pin (male) Pin No. PLC *1 SHELL 1 Signal Name SG 5 7 FG +SD 1 12 T1 -SD 2 13 T2 +RD 7 24 T3 -RD 8 25 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables. Wiring Diagram 6 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No.
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13-8 13. KOYO ELECTRONICS PLC Wiring Diagram 7 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SG 5 7 SG 7 +SD 1 12 RXD+ 9 -SD 2 13 RXD- 10 +RD 7 24 CTS1+ 11 -RD 8 25 TXD1+ 14 TXD1- 16 RTS1+ 18 RTS1- 19 CTS1+ 23 D-sub 25-pin (male) *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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14. LG PLC 14.
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14-2 14. LG PLC MASTER-KxxxS CNET / GLOFA CNET / GM Series CPU Item Setting on PLC Baud rate Parity Transmission code V7 Comm. Parameter Setting 38400 bps 38400 bps Not provided Not provided Data length 8 8 Stop bit 1 1 Available Memory The available memory setting range varies depending on the PLC model. Be sure to set within the range available with the PLC to be used. Use [TYPE] when assigning the indirect memory for macro programs.
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14.
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14-4 14. LG PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 RXD 2 RD 7 3 TXD 3 SG 5 7 GND 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 9-pin (male) * Use shielded twist-pair cables.
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14. LG PLC Wiring Diagram 3 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 RXD 2 RD 7 3 TXD 3 RS 4 GND 5 CS 5 RTS 7 7 CTS 8 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 25-pin (male) * Use shielded twist-pair cables. Wiring Diagram 4 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name PLC D-sub 25-pin (male) Pin No. Pin No.
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14-6 14. LG PLC Wiring Diagram 5 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 RXD 4 RD 7 3 SG 5 SG 5 7 TXD 7 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 9-pin (male) * Use shielded twist-pair cables. RS-422 Wiring Diagram 6 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No.
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14. LG PLC Wiring Diagram 7 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name Pin No. D-sub 25-pin (male) Pin No. PLC *1 SHELL 1 Signal Name SG 5 7 SG +SD 1 12 RDA -SD 2 13 RDB +RD 7 24 SDA -RD 8 25 SDB *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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14-8 14. LG PLC Please use this page freely.
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15. Matsushita Electric Works PLC 15.
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15-2 15. Matsushita Electric Works PLC MEWNET: Link Unit Switch Setting Switch Setting Contents 1 ON 2 OFF 3 OFF 4 OFF Data length: 7 bits 5 ON With parity 6 ON Even 7 OFF Stop bit 1 8 OFF CS, CD invalid Same as that set on V7 (normally 19200 bps) Available Memory The available memory setting range varies depending on the PLC model. Be sure to set within the range available with the PLC to be used. Use [TYPE] when assigning the indirect memory for macro programs.
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15. Matsushita Electric Works PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 SD 2 RD 7 3 RD 3 RS 4 RS 4 CS 5 CS 5 7 SG 7 CD 8 ER 9 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 9-pin (male) * Use shielded twist-pair cables.
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15-4 15. Matsushita Electric Works PLC Wiring Diagram 3 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name Pin No. D-sub 25-pin (male) Pin No. PLC *1 SHELL 1 Signal Name SD 8 2 SD RD 7 3 RD RS 4 SG CS 5 SG 5 7 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables. RS-422 Wiring Diagram 4 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) Signal Name Pin No. Pin No.
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16. MITSUBISHI ELECTRIC PLC 16.
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16-2 16.
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16. MITSUBISHI ELECTRIC PLC 16-3 Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: A Series Link Item Baud rate Port Setting on PLC V7 Comm. Parameter Setting 19200 bps 19200 bps 0 for both stations ×10, ×1 0 Even Even Parity Transmission mode*1 RS-232C MODE1 Trans. Mode 1 RS-422 MODE5 Trans.
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16-4 16. MITSUBISHI ELECTRIC PLC Be sure to check these boxes. Set the V7 communication parameters as shown in this box. A Series CPU, QnA Series CPU Communication parameters for the V7 series are automatically set. QnH (A) Series CPU, QnH (Q) Series CPU, Q00J/00/01 CPU Communication parameters for the V7 series except the baud rate are automatically set. * The maximum baud rate available with the V7 series is 115200 bps. Select the appropriate baud rate depending on the used PLC and environment.
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16-5 16. MITSUBISHI ELECTRIC PLC A Series Link, QnA Series Link: Switch Setting The following is an example that shows the settings for both rotary DIP switches and DIP switches on the PLC.
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16-6 16. MITSUBISHI ELECTRIC PLC A1SJ71UC24-R4, A1SJ71C24-R4 Example 4 Signal level: RS-422, baud rate: 19200 bps, transmission mode 1 STATION No ´10 STATION No ´1 MODE B C D E B C D E B C D E A 9 8 7 6 5 4 3 A 9 F 0 1 2 8 7 6 5 4 3 F 0 1 2 A 9 8 7 6 5 4 3 ON SW01 F 0 1 2 SW02 SW03 SW04 SW05 ON SW06 OFF SW07 SW08 SW09 SW10 SW11 SW12 Available Memory The available memory setting range varies depending on the PLC model.
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16. MITSUBISHI ELECTRIC PLC 16-7 FX Series, FX1S Series Memory TYPE D (data register) 0 TN (timer/current value) 1 CN (counter/current value) 2 32CN (counter 32 bits) 3 M (internal relay) 4 S (state) 5 X (input relay) 6 Y (output relay) 7 TS (timer/contact) 8 CS (counter/contact) 9 (file register) 10 DX *1 *2 Remarks *1 Read only *2 For numerical data format where double-words can be used (Num. Data Display, Graph, Sampling), data is processed as double-words.
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16-8 16. MITSUBISHI ELECTRIC PLC FX Series (A Protocol) Memory TYPE Remarks D (data register) 0 TN (timer/current value) 1 CN (counter/current value) 2 *1 32CN (counter 32 bits) 3 *2 M (internal relay) 4 S (state) 5 X (input relay) 6 Y (output relay) 7 TS (timer/contact) 8 CS (counter/contact) 9 *1 *2 Read only CN200 to CN255 equals 32CN (32-bit counter). For numerical data format where double-words can be used (Num.
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16. MITSUBISHI ELECTRIC PLC Wiring Diagram 2 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 SD 2 RD 7 3 RD 3 RS 4 RS 4 CS 5 CS 5 7 DR 6 SG 7 CD 8 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 25-pin (male) * Use shielded twist-pair cables.
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16-10 16. MITSUBISHI ELECTRIC PLC Wiring Diagram 4 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 SD 2 RD 7 3 RD 3 RS 4 SG 7 CS 5 SG 5 D-sub 25-pin (male) 7 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables. RS-422 Wiring Diagram 5 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) Signal Name Pin No. Pin No.
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16. MITSUBISHI ELECTRIC PLC Wiring Diagram 6 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name D-sub 25-pin (male) Pin No. Pin No. PLC D-sub 25-pin (male) *1 SHELL 1 Signal Name Pin No. SG 5 7 RDA 2 +SD 1 12 SDA 3 -SD 2 13 DSRA 4 +RD 7 24 DTRA 5 -RD 8 25 SG 7 RDB 15 SDB 16 DSRB 17 DTRB 18 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. 20 * Use shielded twist-pair cables.
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16-12 16. MITSUBISHI ELECTRIC PLC According to our noise tests, the attachment of a ferrite core improves noise voltage by 650 to 900 V and aids in preventing communication errors. • When connecting to the A/QnA series CPU directly, attach a ferrite core to the communication cable between the V7 series and A/QnA series CPU to avoid noise problems. Ferrite core A/QnA series CPU V7 series • Ferrite cores are optionally available. When ordering the ferrite core, state “GD-FC (ID: 8 mm, OD: 20 mm).
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16. MITSUBISHI ELECTRIC PLC 16-13 A Link + Net10 • When the V7 series is connected to the standard type link unit on the CPU that is connected to the data link system or network system, the V7 series can have access to CPUs on NET II (/B) and NET/10. In this case, select “A Link + Net10” for [PLC Type] on the VSFT editor. • When the V7 series has access to the CPU on NET II (/B) or NET/10: - With NET II (/B), the V7 series can only have access to CPUs in the network (No.
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16-14 16. MITSUBISHI ELECTRIC PLC • Network specifying macro............... [OUT_ENQ] of system call [SYS] F1 memory n+0 Always 0 n+1 Network selection: 2 n+2 System code n+3 Network number “n + 0” and “n + 1” are fixed to “0” and “2”, respectively. “n + 2” (system code) should be: 1: NET/10 2: NET II (/B) For “n + 3” (network number), set “0” when NET II (/B) is selected for “n + 2” (system code) or the network number to be accessed when NET/10 is selected.
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16. MITSUBISHI ELECTRIC PLC 16-15 V-MDD (Dual Port Interface) V-MDD is the add-on connector with two ports, specifically designed for the connector on MITSUBISHI’s A series, QnA series or FX series CPU programming port. MITSUBISHI A/QnA/FX series CPU A6GPP, A7PHP, computer, etc. G P P When connecting to the CPU of the MITSUBISHI A/QnA series: Insert the connector on the backside into the CPU port directly or use the MDD-CPU (optional) cable for connection.
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16-16 16. MITSUBISHI ELECTRIC PLC Connection • When connecting the V7 series (CN1) to the PLC (CPU port), use a 1 : 1 communication cable as previously described. • Use Hakko Electronics’ V6-CP cable when connecting the computer (PLC programming software) and the V7 series (MJ1/2).
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16. MITSUBISHI ELECTRIC PLC 16-17 Settings and Communications 1. PLC type setting Select [PLC Type] from the [System Setting] menu. Select a type adapted to the ladder transfer function in the [Select PLC Type] dialog. 2. PLC programming software port setting Select [Modular Jack] from the [System Setting] menu. Select [Ladder Tool] for [Modular Jack 1] or [Modular Jack 2] in the [Modular Jack] dialog.
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16-18 16. MITSUBISHI ELECTRIC PLC - Enabling V-SFT communications manually Main Menu V710iTD System Information SYSTEM PROG. VER. 1.000 Screen Data Information Size : 5783552 2002-4 -1 FONT VER.1.300 / 1.000 / 1.000 ENGLISH PLC Type : MITSUBISHIQnH(Q) series CPU Comment : Connection : 1:1 Signal Level : RS232C PLC Stat. No. : 0 Error : Stop Time-Out : 1.00 sec Retry : 3 Baud Rate :19200 Data Length : 8 Stop Bit : 1 Parity : Odd Send Delay : 0msec SRAM/Clock Editor:MJ1 07:23:30 I/F DRV VER.1.
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16. MITSUBISHI ELECTRIC PLC 16-19 Notes on Ladder Transfer Function 1. When [Ladder Tool] is selected for a modular jack, monitor registration on the PLC is prohibited so that the screen display speed becomes slower than usual during communications between the V7 series and the PLC even if the PLC programming software is not started. 2.
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16-20 16. MITSUBISHI ELECTRIC PLC Please use this page freely.
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17. MODICON PLC 17. 17-1 MODICON PLC Available PLCs Select PLC Type PLC Modbus RTU Modbus RTU Unit/Port Modbus Connection RS-232C [Wiring Diagram 1] Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: Item Baud rate Port Parity Transmission code Setting on PLC V7 Comm.
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17-2 17. MODICON PLC Wiring Wiring diagram with the PLC is shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 RX 2 RD 7 3 TX 3 RS 4 DTR 4 CS 5 GND 5 7 DSR 6 RTS 7 CTS 8 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 9-pin (male) * Use shielded twist-pair cables.
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18. MOELLER PLC 18. 18-1 MOELLER PLC Available PLCs Select PLC Type PLC Connection RS-232C PS4 [Wiring Diagram 1] + ZB4-303-KB1 Cable made by MOELLER PS4-201-MM1 (PRG port) Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: Item Baud rate Port Parity Transmission code Setting on PLC V7 Comm.
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18-2 18. MOELLER PLC Wiring Wiring diagram with the PLC is shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 TX 2 RD 7 3 RX 3 SG 5 7 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 9-pin (male) * Use shielded twist-pair cables.
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19. OMRON PLC 19.
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19-2 19. OMRON PLC Select PLC Type PLC Unit/Port Connection PLC2Way CPU unit (RS-232C port) CS1W-SCU21 CS1 RS-232C [Wiring Diagram 2] Mounted on the CPU slot (CS1W-SCB41) RS-422 [Wiring Diagram 7] CPU unit with built-in port (host link port) RS-232C [Wiring Diagram 2] RS-232C [Wiring Diagram 2] RS-422 [Wiring Diagram 7] Mounted on the CPU slot (CS1W-SCB21) SYSMAC CS1/CJ1 SYSMAC CS1/CJ1 DNA*3 CJ1H, CJ1M CJ1W-SCU41 *1 *2 *3 Replace the shell on the D-sub 25-pin side before use.
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19. OMRON PLC 19-3 Example: PLC Memory Indication on V7 0000 to 9999 0 to 9999 F001 to F999 −1 to −999 A000 to A999 −1000 to −1999 00000000 to 99999999 0 to 99999999 F0000001 to F9999999 −1 to −9999999 A0000000 to A9999999 −10000000 to −19999999 • Setting procedure: Num. Data Display [Input Type] BCD [Display Type] DEC (w/ −sign, w/ +−signs) Available Memory The available memory setting range varies depending on the PLC model.
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19-4 19. OMRON PLC SYSMAC CS1/CJ1, SYSMAC CS1/CJ1 DNA Memory TYPE DM (data memory) 0 CH (input/output relay) 1 H (holding relay) 2 A (alarm relay) 4 T (timer/current value) 5 C (counter/current value) 6 EMn (extended data memory) 7 W (internal relay) 8 Remarks *1 TU (timer/contact) 9 Read only CU (counter/contact) 10 Read only *1 When using EMn (extended data memory), specify the bank number (CS1: 0 to C).
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19. OMRON PLC Wiring Diagram 2 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 SD 2 RD 7 3 RD 3 RS 4 RS 4 CS 5 CS 5 7 SG 9 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 9-pin (male) * Use shielded twist-pair cables. Wiring Diagram 3 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No.
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19-6 19. OMRON PLC RS-422 Wiring Diagram 4 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name D-sub 25-pin (male) PLC D-sub 9-pin (male) Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SG 5 7 RDB 1 +SD 1 12 SG 3 -SD 2 13 SDB 5 +RD 7 24 RDA 6 -RD 8 25 SDA 9 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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19. OMRON PLC Wiring Diagram 6 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SG 5 7 SG 9 +SD 1 12 RDB 8 -SD 2 13 RDA 6 +RD 7 24 SDB 2 -RD 8 25 SDA 1 RS 4 CS 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 9-pin (male) * Use shielded twist-pair cables.
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19-8 19. OMRON PLC SYSMAC CS1/CJ1 DNA When connecting the V7 series to CS1/CJ1 on a network (Controller Link), the V7 series can also access another CS1 on the network. CS1 (2-2) CS1 (1-2) Network No. 1 CS1 (1-1) CS1 (1-3) (2-1) Network No. 2 CS1 (2-3) CS1 (2-4) SYSTEM F1 F2 F3 F4 F5 F6 F7 POWER V7 series V-SFT Setting • Select [System Setting] → [Comm. Parameter] → [Detail] tab, and select [1 : n] for [Connection]. • Select [System Setting] → [Network Table Setting] → [PLC].
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20. SAIA PLC 20. 20-1 SAIA PLC Available PLCs Select PLC Type PLC PCD PCD1 Unit/Port Connection PGU port RS-232C [Wiring Diagram 1] PCD7.F120 RS-232C [Wiring Diagram 2] PCD4.F110 RS-485 [Wiring Diagram 3] Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: Item Baud rate Port Transmission code Setting on PLC V7 Comm.
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20-2 20. SAIA PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 SD 8 2 RX 2 RD 7 3 TX 3 SG 5 7 GND 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. PGU port Signal Pin No. Name * Use shielded twist-pair cables.
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20. SAIA PLC RS-485 Wiring Diagram 3 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SG 5 7 GND 10 +SD 1 12 T/R+ 12 -SD 2 13 T/R− 11 +RD 7 24 -RD 8 25 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. PCD7.F110 * Use shielded twist-pair cables.
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20-4 20. SAIA PLC Please use this page freely.
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21. SAMSUNG PLC 21. 21-1 SAMSUNG PLC Available PLCs Select PLC Type PLC SPC series Connection RS-232C RS-422/485 SPC series [Wiring Diagram 1] [Wiring Diagram 2] Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: Item Setting on PLC Baud rate Parity Stop bit Terminating resistance V7 Comm.
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21-2 21. SAMSUNG PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 TXD 2 RD 7 3 RXD 3 RS 4 GND 5 CS 5 SG 5 D-sub 9-pin (male) 7 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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22. SHARP PLC 22.
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22-2 22. SHARP PLC JW100/70H COM Port, JW20 COM Port: System Memory Setting The settings for communications with the V7 series should be made at the system memory as shown below.
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22. SHARP PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name D-sub 25-pin (male) PLC D-sub 15-pin (male) Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 SXD 2 RD 7 3 RXD 3 RS 4 RTS 4 CS 5 CTS 5 7 SG 7 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. 12 14 * Use shielded twist-pair cables.
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22-4 22. SHARP PLC RS-422 Wiring Diagram 3 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. +SD 1 12 +TXD 10 -SD 2 13 −TXD 11 +RD 7 24 +RXD 12 -RD 8 25 −RXD 13 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 15-pin (male) * Use shielded twist-pair cables. Wiring Diagram 4 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) Signal Name Pin No.
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23. SHINKO ELECTRIC PLC 23. 23-1 SHINKO ELECTRIC PLC Available PLCs Select PLC Type PLC SELMART SELMART-100 and later Unit/Port Version 01M2-UCI-6 Connection RS-232C [Wiring Diagram 1] Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: Item Baud rate Parity Transmission code Data length Stop bit Sumcheck Setting on PLC V7 Comm.
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23-2 23. SHINKO ELECTRIC PLC Wiring Wiring diagram with the PLC is shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 SD 2 RD 7 3 RD 3 RS 4 RS 4 CS 5 CS 5 7 SG 7 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 25-pin (male) * Use shielded twist-pair cables.
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24. Siemens PLC 24.
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24-2 24. Siemens PLC S5, S5 V4 (S5-115U, S5-135U, S5-155U), S7 (S7-300, S7-400) Item Setting on PLC Baud rate 9600 bps − Even (fixed) Data length − 8 (fixed) Stop bit − 1 (fixed) Parity Transmission code V7 Comm. Parameter Setting 9600 bps S5 PG Port Communication parameters are automatically set. S7-200PPI Item Setting on PLC V7 Comm. Parameter Setting 9600 bps 9600 bps Baud rate Port Parity 2 2 Even (fixed) − Setting on PLC V7 Comm.
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24. Siemens PLC 24-3 S7-300MPI (HMI ADP, PC ADP, Helmholz SSW7 ADP) V7 Comm. Parameter Setting Item Baud rate 38400 bps HMI ADP PC ADP Helmholz SSW7 ADP 38400 bps (fixed) 38400 bps − Odd (fixed) Data length − 8 (fixed) Stop bit − 1 (fixed) 2 2 Parity Transmission code Setting on PLC Local No. (PLC port number) • Set [MPI SETTING] in the [Comm. Parameter] dialog of the V-SFT editor. Item Highest MPI Address Source No.
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24-4 24. Siemens PLC Available Memory The available memory setting range varies depending on the PLC model. Be sure to set within the range available with the PLC to be used. Use [TYPE] when assigning the indirect memory for macro programs. S5, S5 V4, S7 Memory TYPE Remarks (data register) 0 Use memory address DB1 and later for S7, or DB3 or later for S5.
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24-5 24. Siemens PLC S5 PG Port Memory TYPE Remarks DB (data register) 0 Use memory address DB3 and later. I (input relay) 1 IW as word device Q (output relay) 2 QW as word device F (flag/internal relay) 3 FW as word device T (timer/current value) 4 C (counter/current value) 5 AS (absolute address) 6 The assigned memory is indicated when editing the screen as shown on the right.
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24-6 24.
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24. Siemens PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 TXD 2 RD 7 3 RXD 3 RS 4 GND 7 CS 5 SG 5 D-sub 25-pin (male) 7 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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24-8 24. Siemens PLC Wiring Diagram 3 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 TXD 2 RD 7 3 RXD 3 D-sub 25-pin (male) RS 4 4 CS 5 5 SG 7 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. GND 6ES5 734-1BD20 S5-95U 7 * Use shielded twist-pair cables.
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24. Siemens PLC Wiring Diagram 5 V Series CN1 HMI Adaptor PC Adaptor Helmholz Adaptor D-sub 9-pin (female) D-sub 25-pin (male) Signal Name Pin No. FG 1 Signal Name Pin No. SD 2 RD 2 RD 3 SD 3 RS 4 SG 5 CS 5 RTS 7 SG 7 CTS 8 * Use shielded twist-pair cables. RS-422 Wiring Diagram 6 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name D-sub 25-pin (male) Pin No. Pin No. PLC D-sub 15-pin (male) *1 SHELL 1 Signal Name Pin No.
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24-10 24. Siemens PLC Wiring Diagram 7 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SG 5 7 SG 5 +SD 1 12 +TxD/RxD 3 -SD 2 13 −TxD/RxD 8 +RD 7 24 -RD 8 25 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 9-pin (male) * Use shielded twist-pair cables. • Terminating Resistance Setting Set the DIP switch 7 of the V series (for V706: No.
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24. Siemens PLC Wiring Diagram 8 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SG 5 7 GND 6 +SD 1 12 DI+ 5 -SD 2 13 DI- 8 +RD 7 24 DO+ 1 -RD 8 25 DO- 7 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 9-pin (male) * Use shielded twist-pair cables.
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24-12 24. Siemens PLC Please use this page freely.
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25. TAIAN PLC 25. 25-1 TAIAN PLC Available PLCs Select PLC Type PLC TP02 TP02 Unit/Port Connection Communication Port (T/R+, T/R−) RS-422 [Wiring Diagram 1] MMI Port (9-pin) (4-5 Short Computer Link Mode) RS-422 [Wiring Diagram 2] Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: Item Baud rate Port Parity Transmission code Setting on PLC V7 Comm.
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25-2 25. TAIAN PLC Wiring Wiring diagrams with the PLC are shown below. RS-422 Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) Signal Name Pin No. Pin No. *1 SHELL 1 PLC SG 5 7 Signal Name +SD 1 12 T/R+ -SD 2 13 T/R- +RD 7 24 SHLD -RD 8 25 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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26. Telemecanique PLC 26. 26-1 Telemecanique PLC Available PLCs Select PLC Type PLC TSX Micro Connection TSX Micro RS-485 [Wiring Diagram 1] Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: Item Setting on PLC Baud rate Connection Parity Transmission code Data length Stop bit V7 Comm.
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26-2 26. Telemecanique PLC Wiring Wiring diagram with the PLC is shown below. RS-485 Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) Signal Name Pin No. Pin No. *1 SHELL 1 SG 5 7 Signal Name Pin No. +SD 1 12 D+ 1 -SD 2 13 D− 2 +RD 7 24 0V 7 -RD 8 25 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. PLC MiniDIN 9-pin (male) * Use shielded twist-pair cables.
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27. TOSHIBA PLC 27. 27-1 TOSHIBA PLC Available PLCs Select PLC Type PLC Unit/Port Connection T series T series Computer link port on CPU RS-422 [Wiring Diagram 1] EX series EX100, 250, 500 Computer link port on CPU RS-422 [Wiring Diagram 2] Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: T Series Item Setting on PLC V7 Comm.
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27-2 27. TOSHIBA PLC Available Memory The available memory setting range varies depending on the PLC model. Be sure to set within the range available with the PLC to be used. Use [TYPE] when assigning the indirect memory for macro programs.
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27. TOSHIBA PLC Wiring Wiring diagrams with the PLC are shown below. RS-422 Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 SG 5 7 2 RXA +SD 1 12 3 TXA -SD 2 13 4 CTSA 5 RTSA 7 SG 10 RXB 11 TXB 12 CTSB 13 RTSB +RD 7 24 -RD 8 25 D-sub 15-pin (male) Signal Pin No. Name * R *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG.
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27-4 27. TOSHIBA PLC Please use this page freely.
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28. TOSHIBA MACHINE PLC 28. 28-1 TOSHIBA MACHINE PLC Available PLCs Select PLC Type PLC Unit/Port Connection Port on the CPU unit TC200 TC200 TCCMW TCCMO RS-232C [Wiring Diagram 1] − TCmini Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: Item Baud rate Port V7 Comm.
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28-2 28. TOSHIBA MACHINE PLC Wiring Wiring diagram with the PLC is shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 TXD 2 RD 7 3 RXD 3 RS 4 DTR 4 CS 5 GND 5 7 DSR 6 CTS 7 RTS 8 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 9-pin (female) * Use shielded twist-pair cables.
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29. Toyoda Machine Works PLC 29. 29-1 Toyoda Machine Works PLC Available PLCs Select PLC Type PLC L2/PC2 series PC3J TOYOPUC Unit/Port Connection CMP-LINK RS-422 [Wiring Diagram 1] Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: Item Setting on PLC V7 Comm. Parameter Setting 19200 bps 19200 bps 0 0 Even Even Baud rate Port Parity Transmission code Data length 7 (ASCII) 7 2 2 Stop bit Set [Trans.
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29-2 29. Toyoda Machine Works PLC Available Memory The available memory setting range varies depending on the PLC model. Be sure to set within the range available with the PLC to be used. Use [TYPE] when assigning the indirect memory for macro programs.
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29. Toyoda Machine Works PLC Wiring Wiring diagram with the PLC is shown below. RS-422 Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) Signal Name Pin No. Pin No. PLC *1 SHELL 1 Signal Name SG 5 7 + +SD 1 12 - -SD 2 13 0V +RD 7 24 -RD 8 25 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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29-4 29. Toyoda Machine Works PLC Please use this page freely.
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30. VIGOR PLC 30. 30-1 VIGOR PLC Available PLCs Select PLC Type PLC M series M1-CPU1 Unit/Port Connection RS-232C RS-485 COM PORT [Wiring Diagram 1] [Wiring Diagram 2] Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: Item Baud rate Port Parity Transmission code Setting on PLC V7 Comm.
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30-2 30. VIGOR PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name D-sub 25-pin (male) PLC Pin No. Pin No. D-sub 9-pin (male) *1 SHELL 1 Signal Name Pin No. SD 8 2 RXD 2 RD 7 3 TXD 3 SG 5 7 SG 5 RTS 7 CTS 8 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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31. Yamatake PLC 31. 31-1 Yamatake PLC Available PLCs Select PLC Type PLC MX series MX200/MX50 Unit/Port ASCII connector Connection RS-232C [Wiring Diagram 1] Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: Item Baud rate Port Parity Transmission code Setting on PLC V7 Comm.
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31-2 31. Yamatake PLC Wiring Wiring diagram with the PLC is shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 SD 2 RD 7 3 RD 3 RS 4 RS 4 CS 5 CS 5 7 SG 7 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 25-pin (male) * Use shielded twist-pair cables.
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32. Yaskawa Electric PLC 32.
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32-2 32. Yaskawa Electric PLC CP9200SH/MP900 Item Baud rate Port Parity Transmission code Setting on PLC V7 Comm. Parameter Setting 19200 bps 19200 bps 1 1 Even Even Data length 8 8 Stop bit 1 1 CRC (fixed) − 0 (fixed) − Error check Port delay timer Available Memory The available memory setting range varies depending on the PLC model. Be sure to set within the range available with the PLC to be used. Use [TYPE] when assigning the indirect memory for macro programs.
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32. Yaskawa Electric PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name D-sub 25-pin (male) PLC D-sub 9-pin (male) Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 TXD 2 RD 7 3 RXD 3 RS 4 RTS 4 CS 5 CTS 5 7 DSR 6 SGND 7 DTR 9 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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32-4 32. Yaskawa Electric PLC Wiring Diagram 3 V706 V Series MJ2 CN1 D-sub 25-pin (male) CP217IF(CN1) 217IF(CN1/2) Pin No. Pin No. D-sub 9-pin (male) *1 SHELL 1 Signal Name Pin No. SD 8 2 SD 2 RD 7 3 RD 3 RS 4 RS 4 CS 5 CS 5 7 DR 6 SG 7 CD 9 RJ-45 8-pin Signal Name SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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32. Yaskawa Electric PLC RS-422 Wiring Diagram 5 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name D-sub 25-pin (male) PLC D-sub 9-pin (male) Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SG 5 7 TXD+ 2 +SD 1 12 RXD+ 3 -SD 2 13 RXD- 6 +RD 7 24 SG 7 -RD 8 25 TXD- 9 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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32-6 32. Yaskawa Electric PLC Wiring Diagram 7 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) CP217IF (CN3) Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. +SD 1 12 RX- 1 -SD 2 13 RX+ 2 +RD 7 24 TX- 6 -RD 8 25 TX+ 7 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. MR-8 (male) * Use shielded twist-pair cables.
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33. Yokogawa Electric PLC 33.
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33-2 33. Yokogawa Electric PLC Communication Setting The recommended communication parameter settings of the PLC and the V7 series are as follows: FA500 Item Baud rate Port Parity Transmission code Data length Stop bit Setting on PLC V7 Comm. Parameter Setting 19200 bps 19200 bps 1 1 Even Even 7 7 1 1 Provided (fixed) − Terminal character None (fixed) − Protection function None (fixed) − Setting on PLC V7 Comm.
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33. Yokogawa Electric PLC 33-3 Available Memory The available memory setting range varies depending on the PLC model. Be sure to set within the range available with the PLC to be used. Use [TYPE] when assigning the indirect memory for macro programs.
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33-4 33. Yokogawa Electric PLC Wiring Wiring diagrams with the PLC are shown below. RS-232C Wiring Diagram 1 V706 V Series MJ2 CN1 RJ-45 8-pin D-sub 25-pin (male) PLC Signal Name Pin No. Pin No. *1 SHELL 1 Signal Name Pin No. SD 8 2 SD 2 RD 7 3 RD 3 RS 4 RS 4 CS 5 CS 5 7 DR 6 SG 7 ER 20 SG 5 *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. D-sub 25-pin (male) * Use shielded twist-pair cables.
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33. Yokogawa Electric PLC RS-422 Wiring Diagram 3 V706 V Series MJ2 CN1 RJ-45 8-pin Signal Name Pin No. D-sub 25-pin (male) Pin No. PLC *1 SHELL 1 Signal Name SG 5 7 RDB +SD 1 12 RDA -SD 2 13 SDB +RD 7 24 SDA -RD 8 25 SG *1 Pin No. 1 of CN1 is used as FG. The metal shell of the modular jack 2 on the V706 is used as SG. * Use shielded twist-pair cables.
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33-6 33. Yokogawa Electric PLC Please use this page freely.
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Appendix 1 PLC2Way App1-1 Appendix 1 PLC2Way PLC2Way • The “PLC2Way” function is an original network function where one V7 series can be connected to two PLCs. Even if the manufacturers of these PLCs are not the same, they can be connected to one V7 series. • When the V7 series or a V706 equipped with DU-01 is used, connect the first PLC to the CN1 connector. When a V706 is used, connect the first PLC to MJ2. Connect the second PLC to the MJ port (to MJ1 when a V706 is used).
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App1-2 Appendix 1 PLC2Way • With the PLC2Way function, it is possible to communicate with PLCs without special program in the same way as 1 : 1 connection. Two PLCs that are connected to the V7 series are controlled at the same time, and memory read/write operations are available with these two PLCs. • When the PLC2Way function is used, connection at the MJ port is possible via RS-232C or RS-485 (2-wire connection).
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Appendix 1 PLC2Way App1-3 PLCs Compatible with PLC2Way Connection at MJ Port • When connecting the V7 series to the PLC at the MJ port using PLC2Way function, use the RS-232C or RS-485 (RS-422) 2-wire connection. The PLC that allows RS-485 (RS-422) (4-wire) connection only cannot be connected directly. • PLCs compatible with PLC2Way connection at MJ port as of February, 2004 are shown below.
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App1-4 Appendix 1 PLC2Way Wiring Two kinds of cables are available for PLC2Way connection at the MJ port. Cable connections are explained. Connecting Method 1 (Using MJ-D25) • To connect the PLC and the V7 series at the MJ port, use Hakko Electronics’ MJ to D-sub conversion cable “MJ-D25” (0.3 m, metric thread) and the cable for 1 : 1 connection at CN1. For more information on the cable for 1 : 1 connection at CN1, refer to “Wiring” in “Chapter 2” to “Chapter 33.
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Appendix 1 PLC2Way App1-5 • Connection example with MITSUBISHI A1SJ71UC24-R4 (1 set) Modular jack, 8-pin Signal Name PLC Pin No. Signal Name *1 (Black) 1 SDA -SD/RD (Green) 2 SDB (Red) 5 RDA +SD/RD SG *1 RDB V6-TMP is connected to FG when the V7 series is used and to SG when the V706 is used. SG * Use shielded cables. • Connection example with MITSUBISHI A1SJ71UC24-R4 (3 set) Modular jack, 8-pin Signal Name Pin No.
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App1-6 Appendix 1 PLC2Way For V706: • The terminating resistance should be set on the DIP switch in the side of the unit. • Set DIPSW1 to the ON position.
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Appendix 1 PLC2Way App1-7 3. Select the MJ port. Click the [Refer to Modular] button. The [Modular Jack] dialog is displayed. Select [Temp./PLC2Way] for modular jack 1 or 2 that is used for PLC2Way communication. 4. Select the PLC model to be connected at the MJ port. Click the [Setting] button. The [Type Setting] dialog is displayed. Select [PLC2Way]. The PLC manufacturer names who support PLC2Way communication are displayed. Click [+].
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App1-8 Appendix 1 PLC2Way 5. Set the parameters for the PLC to be connected at the MJ port. [Baud Rate] (4800, 9600, 19200, 38400, 57600, 115k, bps) Select the communication speed with the PLC connected at the MJ port. [Parity] (None/Odd/Even) Select the parity setting for communications with the PLC connected at the MJ port. [Data Length] (7-bit/8-bit) Select the data length for communications with the PLC connected at the MJ port.
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App1-9 Appendix 1 PLC2Way Code and Text Processing For the PLC connected at the MJ port, code and text processing cannot be set in the [Temp. Control/PLC2Way Comm. Setting] dialog. • Code (numerical data input format) The code is fixed as shown below. For numerical data, such as those for data displays or data sampling in the sampling mode, BCD or DEC should be chosen for [Input Type].
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App1-10 Appendix 1 PLC2Way V-SFT Setting When the Temperature Control Network/PLC2Way Table is Used: The following operations are available when the temperature control network/PLC2Way table is used. 1. Constant read from the PLC memory When the temperature control network/PLC2Way table is set, the data read from the PLC2 memory can be stored in the PLC memory or the V7 internal memory at regular intervals. 2.
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Appendix 1 PLC2Way App1-11 2. Closing Click [Close] in the drop-down menu, or click the [Close] button at the top right corner. 3. Comment setting There are 32 temperature control network/PLC2Way tables and a comment can be set for each table. Click [Edit] → [Comment]. The [Comment Setting] dialog is displayed. Enter the desired comment and click [OK]. The entered comment is displayed at the top right corner. 4. Setting data in the table Click on a line in the table. The selected line turns blue.
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App1-12 Appendix 1 PLC2Way When (2) is clicked, a data type for the PLC2 memory can be set. [Word] This is the data length setting for the memory address to be used. Numerical data of one word is handled. Data is transferred to the target memory address in the numerical data code of the PLC2 memory. [Double Word] This is the data length setting for the memory address to be used. Numerical data of two words is handled.
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Appendix 1 PLC2Way App1-13 When (3) is double-clicked, the [Temp. CTRL/PLC2Way Table Setting] dialog is displayed. Set the memory addresses of the target PLC memory and target internal memory at one time in the [Temp. CTRL/PLC2Way Table Setting] dialog. [Use Periodical Reading] Check this option when the following operation is required. • Constant read from the PLC memory • Data sampling in the PLC2 memory [Read Cycle] (sec) Set the cycle of reading data in the PLC2 memory.
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App1-14 Appendix 1 PLC2Way Data Sampling in the PLC2 Memory To perform data sampling in the PLC2 memory, the following settings are required. • Temperature control network/PLC2Way table editing (Refer to page App1-10.) • Buffering area setting • Memory card setting (when [SRAM] or [CF Card] is selected for [Store Target] in the [Buffering Area Setting] dialog) • Trend sampling or data sampling setting (setting for displaying data stored in the specified buffer) 1.
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Appendix 1 PLC2Way App1-15 2. Memory card setting When [SRAM] or [CF Card] is selected for [Store Target] in the [Buffering Area Setting] dialog, the memory card setting is required. * The used memory capacity of SRAM and CF card can be calculated in the same way as the buffering area. 1) Click [System Setting] → [Memory Card Setting]. The [Memory Card] dialog is opened. 2) Select [Buffering File] for [Type]. 3) Match the file number (tab) in the [Memory Card] dialog with [Output File No.
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App1-16 Appendix 1 PLC2Way Data Transfer from the PLC2 Memory Data in the PLC2 memory can be transferred to the PLC memory, V7 internal memory or a memory card at one time. Conversely, it is also possible to transfer data in the PLC memory, V7 internal memory or a memory card to the PLC2 memory at one time. To perform batch data transfer from the PLC2 memory, the following settings are required.
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App1-17 Appendix 1 PLC2Way Indirect Memory Designation It is possible to have access to the PLC2 memory using the indirect memory designation as a macro command. In this section, the indirect designation of the PLC2 memory is explained. The internal user memory ($u) is used for the indirect memory designation.
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App1-18 Appendix 1 PLC2Way Processing Cycle The processing cycle on the V7 series with the PLC2Way function is explained. 1. When the temperature control network/PLC2Way table is not used: PLC data 1 PLC data 2 PLC data 1 connected at the MJ port PLC data 3 PLC data “n” connected at the MJ port PLC data “n” 1 cycle Fig. 1 2.
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Appendix 1 PLC2Way App1-19 Notes on Screen Data Transfer Temperature Control/PLC2 Program When using the temperature control network/PLC2Way communications, it is necessary to transfer the temperature control/PLC2 program to the V7 series. When the temperature control network/PLC2Way setting has been made, the program is automatically transferred to the V7 series together with screen data. When [ Temp.
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App1-20 Appendix 1 PLC2Way System Memory The status of the PLC connected at the MJ port for PLC2Way communications is output to the system memory ($s) of the V7 series. The memory addresses ($s729 to 763) of the PLC connected at the MJ port are explained. List Address Contents • • • • • • $s729 TEMP_READ/TEMP_WRITE/TEMP_CTL macro execution result 730 Temperature controller/PLC2Way Station No. 00 status 731 Temperature controller/PLC2Way Station No.
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Appendix 1 PLC2Way App1-21 Details • $s729 An execution result of macro command TEMP_READ, TEMP_WRITE, or TEMP_CTL is stored at this address. - [0]: A command has been executed successfully. - [Other than “0”]: A command execution has resulted in an error. • $s730-761 The following status code for the PLC connected at the MJ port is stored.
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App1-22 Appendix 1 PLC2Way • $s762 Periodical reading that is set in the [Temp. CTRL/PLC2Way Table Setting] dialog can be suspended. - [0]: Periodical reading is performed. - [Other than “0”]: Periodical reading is suspended. If periodical reading of the temperature control network/PLC2Way table is performed while the PLC2 memory is being accessed using a macro command, the macro execution will be delayed (Fig. a). To avoid this, periodical reading can be suspended using memory address $s762 (Fig. b).
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App2-1 Appendix 2 n : 1 Connection (Multi-link 2) Appendix 2 n : 1 Connection (Multi-link 2) Multi-link 2 • One PLC is connected to a maximum of four V7 series. • An original network is created where the V7 series (Local Port 1) that is directly connected to the PLC is the master station, and other three V7 series are slave stations. Only the master station makes communications directly with the PLC, and the slave stations make communications with the PLC via the master station.
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App2-2 Appendix 2 n : 1 Connection (Multi-link 2) • This multi-link connection is available with almost all the PLC models that support 1 : 1 connection (refer to the “Appendix”). (The connection between the master station and the PLC is the same as the one for 1 : 1 connection.) • Use the RS-485 2-wire connection between stations of the V7 series. Please use Hakko Electronics’ multi-link 2 master cable (V6-MLT) for connection between the master station (local port 1) and the slave station (local port 2).
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App2-3 Appendix 2 n : 1 Connection (Multi-link 2) * When the terminal converter “TC485” is not used, install jumpers between +RD/+SD and −RD/−SD.
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App2-4 Appendix 2 n : 1 Connection (Multi-link 2) (d)(e) Connection between terminal blocks Use the RS-485 2-wire connection. V706 master station MJ1 (b) (c) V706 slave station MJ2 * Signal Name Signal Name + Terminating resistance (ON) - SG Pin No. SHELL +SD +SD 1 -SD -SD 2 +RD +RD 7 -RD -RD 8 SG SG 5 Terminal block to be installed by the user (d) V706 slave station MJ2 * Signal Name Signal Name Pin No.
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App2-5 Appendix 2 n : 1 Connection (Multi-link 2) Terminating Resistance Setting For V7 Series: • The terminating resistance of the V7 series should be set on the DIP switch.
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App2-6 Appendix 2 n : 1 Connection (Multi-link 2) For V706: • The terminating resistance of the V706 should be set on the DIP switch. MJ1 (modular jack 1) terminating resistance for RS-485 MJ2 (modular jack 2) SD terminating resistance for RS-422 MJ2 (modular jack 2) RD terminating resistance for RS-422 CF auto load (for USB or DU-01) 1 2 3 4 ON • When the PLC and the master station are connected via RS-422/485, set the terminating resistance at the PLC and the master station (MJ2).
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Appendix 2 n : 1 Connection (Multi-link 2) App2-7 Communication Parameter Setting • Setting Procedure [System Setting] → [Comm. Parameter] → [Comm. Parameter] dialog • Setting Items [Connection] Select [Multi-Link 2]. Click [Setting]. The [Multi-Link 2] dialog is displayed. Make the necessary settings. For the V7 series master station, set the following items. For the V7 series slave station, set the items marked with ♦. [Local Port]♦ (1 to 4) Set the port number of the V7 series.
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App2-8 Appendix 2 n : 1 Connection (Multi-link 2) Please use this page freely.
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Appendix 3 n : 1 Connection (Multi-link) App3-1 Appendix 3 n : 1 Connection (Multi-link) Multi-link • One PLC is connected to multiple V7 series. (Maximum connectable V series: 31) V7 series No. 1 V7 series No. 2 V7 series No. 3 CN1 CN1 CN1 V7 series No. “n” (n = 1 to 31) CN1 Maximum length (PLC to the terminating V7 series) = 500 m RS-422/RS-485 connection PLC V706 No. 1 *1 MJ2 RUN STOP ... ... ... ... ... ... ... ... PLC ... ... ... ... ... ... ... ... V706 No. 2 MJ2 *1 V706 No.
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App3-2 Appendix 3 n : 1 Connection (Multi-link) Wiring Connection with Link Unit For V7 Series: Use the RS-485 2-wire connection. (It is recommended that Hakko Electronics’ optional terminal converter “TC485” be used.) • When TC485 is used: Set “2-wire connection” at the DIP switch (SW1) on TC485.
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Appendix 3 n : 1 Connection (Multi-link) App3-3 For V706: For V706 + DU-01, refer to “For V7 Series:” above. Since MJ2 is adapted to 4-wire connection, it is necessary to change the signal connection from 4-wire to 2-wire for multi-link 2 connection. When a jumper is required on the PLC: V706 MJ2 * Signal Name Shield To the PLC’s RS-422 port of the link unit Pin No.
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App3-4 Appendix 3 n : 1 Connection (Multi-link) When Connecting Directly to the CPU of the MITSUBISHI QnA Series: Use the GD port of Hakko Electronics’ optional dual port interface V-MDD. For V7 Series: V7+TC485 V7+TC485 V7+TC485 Signal Name Signal Name V-MDD GD port Signal Name Pin No.
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App3-5 Appendix 3 n : 1 Connection (Multi-link) V-SFT Setting The following settings must be made on the V-SFT editor. Only the points different from those described in “V-SFT Setting (1 : 1 Connection)” (page 1-10) are explained here. PLC Selection Select the PLC that is connected. Check that the PLC to be connected is ready for multi-link connection. Refer to “Connection Compatibility List” at the back of this manual.
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App3-6 Appendix 3 n : 1 Connection (Multi-link) Please use this page freely.
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Appendix 4 1 : n Connection (Multi-drop) Appendix 4 1 : n Connection (Multi-drop) 1 : n Connection One V7 series is connected to multiple PLCs. (Maximum connectable PLCs: 31) V7 series Maximum length (V7 series to the terminating PLC) = 500 m RS-422/RS-485 connection CN1 PLC1 PLC2 PLC3 PLCn (n = 1 to 31) V706 MJ2 * RUN STOP ... ... ... ... ... ... ... ... PLC1 ... ... ... ... ... ... ... ... Maximum length (V706 to the terminating PLC) = 500 m RS-422/RS-485 connection RUN STOP ... ... ...
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App4-2 Appendix 4 1 : n Connection (Multi-drop) Wiring (RS-422/485) For connecting information, refer to the instruction manual for the PLC. Example: The following example shows how one V7 series is connected to three PLCs made by MITSUBISHI. For more information, refer to MITSUBISHI’s instruction manual for the PLC. V706 V Series MJ2 CN1 Link unit Link unit Signal Pin No. Pin No.
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Appendix 4 1 : n Connection (Multi-drop) App4-3 Notes on Communication Errors Processing for PLC Failure • If a communication error/timeout is detected during communications with a PLC, the PLC failure information is stored in internal system memory addresses $s 114 to 129 of the V7. No further communication with the PLC is attempted until a macro command is executed or the display screen changes.
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App4-4 Appendix 4 1 : n Connection (Multi-drop) Please use this page freely.
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Appendix 5 Ethernet App5-1 Appendix 5 Ethernet Ethernet • Transferring data in memory Data in memory can be transferred to the V7 series on the Ethernet or to the PLCs linked to the V7 series as a host by using macro commands (EREAD/EWRITE). Ethernet SYSTEM SYSTEM F1 F1 F2 F2 F3 F3 F4 F4 F5 F5 F6 F6 F7 F7 POWER POWER RS-232C RS-485 • Communications between the server and the V7 series - “HKEtn10.
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App5-2 Appendix 5 Ethernet - Screen data can be transferred from the V-SFT editor on the server to the V7 series. Server V-SFT Ethernet SYSTEM SYSTEM F1 F1 F2 F2 F3 F3 F4 F4 F5 F5 F6 F6 F7 F7 PROGRAMMER POWER Ethernet-ready PLC POWER RS-232C RS-485 PROGRAMMER • Communications between the Ethernet-ready PLC and the V7 series - The MONITOUCH can communicate with the PLC on the Ethernet.
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Appendix 5 Ethernet App5-3 Notes on Ethernet Communications For V7i: • To use Ethernet communications on V7i, use the 10BASE-T connector (LAN) provided on the unit. It is not possible to use Ethernet or FL-net (OPCN-2) communications by attaching the communication I/F unit CU-03-2 to V7i at the same time. When CU-03-2 is mounted, the 10BASE-T connector (LAN) provided on the unit cannot be used. • When using Ethernet communications with CU-03-2 mounted, the Web server or e-mail function cannot be used.
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App5-4 Appendix 5 Ethernet Names and Functions of Components 1 2 3 ADR - LOW - HI FUSE 0V 10B-T RX TX LNK CI 6 AUI 4 +12V 5 1. LED Indicates the status of the communication. Name Contents On Off RX Data receive status Currently receiving Not receiving Not sending TX Data send status Currently sending LNK Link status (for 10BASE-T only) Normal Error Cl Collision Data collision Normal 2.
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Appendix 5 Ethernet Option Unit DU-01 Specifications Item Baud rate Transmission method Maximum network distance or maximum node interval Maximum segment length Maximum number of nodes Minimum node interval Connecting cable Specifications 10BASE-T 10 Mbps Base band 500 m (4 HUBs) 100 m (between the node and the HUB) 2/segment None UTP (unshielded twisted pair) 22-26AWG Port Position When the DU-01 mounted on the V706, the LAN port faces downward.
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App5-6 Appendix 5 Ethernet Wiring 10BASE-T Connection • Cable connection diagram HUB UTP cable Straight or cross cable (For more information, refer to the HUB specifications.
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Appendix 5 Ethernet App5-7 AUI Connection • 10BASE5 The following devices are required for 10BASE5 connection: - Coaxial cable for 10BASE5 - AUI cable - N-type connector - N-type terminator - Transceiver - Power supply for the transceiver: 12 VDC 1 segment (max. 500 m, max. 100 nodes) Minimum node interval 2.5 m AUI cable (max 50 m) PLC Ethernet unit CU-03 Repeater Node To extend the length or increase the number of nodes, use repeaters.
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App5-8 Appendix 5 Ethernet • 10BASE2 The following devices are required for 10BASE2 connection: - Coaxial cable for 10BASE2 - AUI cable - T-type adaptor - Terminator for 10BASE2 - Transceiver - Power supply for the transceiver: 12 VDC • Transceiver 1 segment (max. 185 m, max. 30 nodes) Minimum node interval 0.5 m AUI cable (max 50 m) CU-03 PLC PLC Ethernet unit *1 Ethernet unit Repeater V7 To extend the segment distance or increase the number of nodes, use repeaters.
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Appendix 5 Ethernet App5-9 Transferring Screen Data This section describes the procedure for transferring screen data from the V-SFT editor on the server to MONITOUCH via Ethernet. For the procedure using the V6-CP cable, refer to the Reference Manual (Operation).
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App5-10 Appendix 5 Ethernet Transferring Screen Data from V-SFT Editor 1. Click the [Transfer] icon. The [Transfer] dialog is displayed. 2. Attach a check mark ( Ethernet]. ) to [ Transfer through 3. Click the [Detail Setting] button. The [IP Address Setting] dialog is displayed. 4. Enter the IP address of the V7 series to which the screen data is to be transferred. When a list is shown, select the IP address of the V7 series, and click the [<<] button.
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Appendix 5 Ethernet 5. Check the IP address, and click [PC->]. IP address for transfer target 6. Data transfer is started.
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App5-12 Appendix 5 Ethernet V-SFT Setting: PLC Type/Communication Parameter To enable Ethernet communications between the V7 series and a PLC, the following setting is required on the V-SFT editor. • PLC type setting • Communication parameter setting • Network table editing In this section, the PLC type setting and communication parameter setting are explained.
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Appendix 5 Ethernet App5-13 (B) Connecting to the PLC on the Ethernet 1. PLC type setting Select [System Setting] → [PLC Type] and select the PLC that shows [xxxxx (Ethernet XXXXX)]. At present (February, 2004), the following PLC models are supported.
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App5-14 Appendix 5 Ethernet 2. Communication parameter setting • Select [System Setting] → [Comm. Parameter]. Set the PLC to the V7 series which is connected. When the network table is not set: Network table No. 0 is displayed. It is not possible to select an option for [Connect To]. Select [System Setting] → [Network Table Setting] → [Ethernet] →. The [Edit Network Table] window is displayed. Set the network table, and then go back to the communication parameter setting.
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Appendix 5 Ethernet App5-15 Set the port number (network table number) of the PLC in the [Memory Input] dialog for each part. For more information on the network table, refer to page App5-16.
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App5-16 Appendix 5 Ethernet V-SFT Setting: Network Table Editing To enable Ethernet communications on the V7 series, the following network table setting is required on the V-SFT editor. Network table • The V7 series, PLCs and PCs on the Ethernet must be registered on the network table. In the case of the network illustrated below, the nodes with (∗) should be registered on the network table.
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Appendix 5 Ethernet App5-17 Starting and Closing • Starting Select [System Setting] → [Network Table Setting] → [Ethernet]. The network table edit window is displayed. [Close] button • Closing Select [File] → [Exit], or click the [Close] button. Menu and Icons Each menu item corresponds to the icons as shown below. [File] menu - Import Network Table Imports a network table saved as a file “∗.ntb.” - Export Network Table Exports a network table as a file “∗.ntb.
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App5-18 Appendix 5 Ethernet - Cancel Monitor Registration Click this menu when canceling monitor registration. [View] menu The items with a check mark are shown on the network table editing window. 1 2 1 3 3 2 Editing the Network Table Double-click the number. The [Set Network Table No. *] dialog is displayed. Network table number [Host Name] Set the name for the V7 series, etc. to be used on the Ethernet. [IP Address] Set the IP address.
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Appendix 5 Ethernet App5-19 IP Address This is an address that is used for recognizing each node on the Ethernet and should be unique. The IP address is 32-bit data which consists of the network address and the host address and can be classified into A to C depending on the network size.
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App5-20 Appendix 5 Ethernet [Sub Net Mask] Attach a check mark ( ) when setting the subnet mask. When this option is checked, it is set to [255.255.255.0]. Subnet Mask A subnet mask is used for dividing one network address into multiple networks (subnet). The subnet is assigned by specifying a part of the host address in the IP address as a subnet address. Class B 10 255. Subnet mask Host address (16) Network address (14) 11111111 255. 11111111 Network address 255.
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Appendix 5 Ethernet App5-21 V-SFT Setting: Macro This section explains the macro commands (SEND/EREAD/EWRITE) used for the Ethernet. For more information on macro commands, refer to the Reference Manual (Function). Macro Command [EREAD] Words from the F1 memory in the V7 series of the network table number specified for F3 are read into the F0 memory. F2 designates the number of words to be read.
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App5-22 Appendix 5 Ethernet [EWRITE] Words from the F2 memory are written into the F0 memory in the V7 series of the network table number specified for F1. F3 designates the number of words to be written. Usable Devices Internal Memory PLC Memory Constant Memory Card Indirect Designation Doubleword IP Address F0 F1 F2 F3 EWRITE: Write to memory EWRITE F0 F1 = F2 C: F3 Example: Macro command at the V7 (A) The macro command for V7 (A) to write data in V7 (A) to PLC (B) is shown below.
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Appendix 5 Ethernet App5-23 [SEND] Words from the F0 memory are transferred to the server of the network table number specified for F2. F1 designates the number of words to be transferred. Usable Devices Internal Memory PLC Memory Memory Card Constant Indirect Designation Doubleword IP Address F0 F1 F2 SEND: Send to server SEND F0 C: F1 TO: F2 Example: Macro command at the V7 (B) The macro command for V7 (B) to transfer data to server (A) is shown below.
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App5-24 Appendix 5 Ethernet System Memory The Ethernet status is output to the system memory ($s) of the V7 series. This section explains the memory addresses ($s514 to 619) where the Ethernet status is output. For other memory addresses, refer to the Reference Manual (Function).
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Appendix 5 Ethernet Address Contents $s553 Network table 33 status 554 Network table 34 status 555 Network table 35 status 556 Network table 36 status 557 Network table 37 status 558 Network table 38 status 559 Network table 39 status 560 Network table 40 status 561 Network table 41 status 562 Network table 42 status 563 Network table 43 status 564 Network table 44 status 565 Network table 45 status 566 Network table 46 status 567 Network table 47 status 568 Network table 4
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App5-26 Appendix 5 Ethernet Address Contents $s600 Network table 80 status 601 Network table 81 status 602 Network table 82 status 603 Network table 83 status 604 Network table 84 status 605 Network table 85 status 606 Network table 86 status 607 Network table 87 status 608 Network table 88 status 609 Network table 89 status 610 Network table 90 status 611 Network table 91 status 612 Network table 92 status 613 Network table 93 status 614 Network table 94 status 615 Networ
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Appendix 5 Ethernet App5-27 Addresses • $s514, 515 These addresses are related to macro commands [SEND], [EREAD] and [EWRITE]. $s514: Sets the executing status of the macro. In the case of “0,” the next step of the macro is executed without waiting for the completion of the command when a command request is given to the Ethernet. In the case of other than “0,” the wait status continues until the command completes, and then the next step of the macro is executed.
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App5-28 Appendix 5 Ethernet Ethernet Access Functions (HKEtn10.DLL) To enable Ethernet communications between the server and the V7 series, it is necessary to create an application based on HKEtn10.dll (for UDP/IP) provided by us, using Visual C++, Visual Basic, etc. Sample Folder The “Sample” folder for Ethernet communications is included in the V-SFT CD-ROM. The [Ethernet] folder contains sample programs created using Visual C++, and the [VBA] folder contains those created using VBA.
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Appendix 5 Ethernet App5-29 • Notes on use of the sample programs The data type to be set when creating a program varies depending on whether Visual C++ or Visual Basic is used. For the data type and range, refer to the following tables.
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App5-30 Appendix 5 Ethernet Function Specifications List • Read PLC Memory Word int HKEtn_ReadPlcMemory(WORD *dp,unsigned short Wordcnt,int DeviceType,DWORD addr,char *lpAddr,int DFlag=1) PLC memory Double-word int HKEtn_ReadPlcMemory2(DWORD *dp,unsigned short Wordcnt,int DeviceType,DWORD addr,char *lpAddr,int DFlag=1) Internal memory Word int HKEtn_ReadInternalMemory(WORD *dp,unsigned short Wordcnt,int DeviceType,DWORD addr,char *lpAddr,int DFlag=1) Memory card memory Word int HKEtn_ReadCardMemory
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Appendix 5 Ethernet App5-31 Read Read Words from PLC Memory int HKEtn_ReadPlcMemory(WORD *dp,unsigned short Wordcnt,int DeviceType,DWORD addr,char *lpAddr, int DFlag=1) This function is retained until PLC data is transferred from the V7 series. • Parameters *dp Target pointer of the data to be read Wordcnt DeviceType addr Contents Word Count No. 1 1 No. 2 1 • • • • • • No. n 1 Word count to be read (max. 2000 words) Address of the device to be read (Refer to “Chapter 2” to “Chapter 33.
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App5-32 Appendix 5 Ethernet Read Double-words from PLC Memory int HKEtn_ReadPlcMemory2(DWORD *dp,unsigned short Wordcnt,int DeviceType,DWORD addr,char *lpAddr, int DFlag=1) This function is retained until PLC data is transferred from the V7 series. • Parameters *dp Wordcnt DeviceType addr *lpAddr DFlag • Return values Success Failure Error details Target pointer of the data to be read Contents Word Count No. 1 2 No. 2 2 • • • • • • No. n 2 Word count to be read (max.
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Appendix 5 Ethernet App5-33 Read Words from Memory Card Memory int HKEtn_ReadCardMemory(WORD *dp,unsigned short Wordcnt,int FileNo,int RecordNo,DWORD addr,char *lpAddr,int DFlag=1) This function is retained until data is transferred from the V7 series. • Parameters *dp Wordcnt FileNo RecordNo addr *lpAddr DFlag • Return values Success Failure Error details Target block pointer Contents Word Count No. 1 1 No. 2 1 • • • • • • No. n 1 Word count to be transferred (max.
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App5-34 Appendix 5 Ethernet Read Bits from Internal Memory int HKEtn_ReadInternalBitMemory(int *lpOnFlag,int DeviceType,DWORD addr,int BitNo,char *lpAddr) This function is retained until data is transferred from the V7 series. • Parameters *IpOnFlag DeviceType addr BitNo *lpAddr • Return values Success Failure Error details Returns the bit status.
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Appendix 5 Ethernet App5-35 Write Write Words to PLC Memory int HKEtn_WritePlcMemory(WORD *sp,unsigned short Wordcnt,int DeviceType,DWORD addr,char *lpAddr, int DFlag=1) This function is retained until write completion is received from the V7 series. (It is reset on receipt of write completion to the PLC memory.) • Parameters *sp Wordcnt DeviceType addr *lpAddr DFlag • Return values Success Failure Error details Target block pointer Contents Word Count No. 1 1 No. 2 1 • • • • • • No.
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App5-36 Appendix 5 Ethernet Write Double-words to PLC Memory int HKEtn_WritePlcMemory2(DWORD *sp,unsigned short Wordcnt,int DeviceType,DWORD addr,char *lpAddr, int DFlag=1) This function is retained until write completion is received from the V7 series. (It is reset on receipt of write completion to the PLC memory.) • Parameters *sp Wordcnt DeviceType addr *lpAddr DFlag • Return values Success Failure Error details Target block pointer Contents Word Count No. 1 2 No. 2 2 • • • • • • No.
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Appendix 5 Ethernet App5-37 Write Words to Memory Card Memory int HKEtn_WriteCardMemory(WORD *sp,unsigned short Wordcnt,int FileNo,int RecordNo,DWORD addr,char *lpAddr,int DFlag=1) This function is retained until write completion is received from the V7 series. (It is reset on receipt of write completion to the memory card memory.) • Parameters *sp Wordcnt FileNo RecordNo addr *lpAddr DFlag • Return values Success Failure Error details Target block pointer Contents Word Count No. 1 1 No.
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App5-38 Appendix 5 Ethernet Write Bits to Internal Memory int HKEtn_WriteInternalBitMemory(int DeviceType,DWORD addr,int BitNo,int OnFlag,char *lpAddr) This function is retained until write completion is received from the V7 series. (It is reset on receipt of write completion to the internal memory.
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Appendix 5 Ethernet Receive Wait from V7 int HKEtn_Recvfrom(BYTE *dp,short *lpCnt) This function is retained internally until data is received from the V7 series. The function returns a response and ends only when a command is received. The user should interpret the received data and create the next action. This function must be executed within the thread. • Parameters *dp *lpCnt • Return values Success Failure Error details Top pointer of receive buffer Allocate 5000 bytes.
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App5-40 Appendix 5 Ethernet Get Error Contents int HKEtn_GetLastError() • Error codes and solutions Code Contents Solution −1 Undefined command (receive timeout) Check the command. −2 Undefined IP address Check the IP address. −3 Target station busy Reduce the frequency of communications. −4 Illegal packet bytes Check response processing at the target station. −5 Packet bytes exceed the maximum number. Reduce the send packet size.
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Appendix 5 Ethernet App5-41 Server Communication Procedure Data Request from V7 to Server (1) Execute the receive wait thread using “int HKEtn_RecvFrom()” on the application of the server. (2) Send the command from the V7 series to the server using macro command SEND. (3) The server analyzes the command and takes the appropriate action. Server (1) (2) Ethernet User data format Transfer from the V7 series Item Application (3) Bytes Packet bytes 2+2+1+n 2 Transaction No.
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App5-42 Appendix 5 Ethernet Error Display Error messages displayed on the V7 series and those stored in the system memory are explained. Communication Errors The Ethernet status is stored in system memory address $s518 of the V7 series during Ethernet communications The communication error occurs when a code other than “0” (normal) is stored in system memory address $s518. • In the RUN mode Communication Error Ethernet Error:XXXX Screen No. : * When [Continue] is selected for [Comm. Err.
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Appendix 5 Ethernet App5-43 • System memory: $s518 No. 0 Contents Solution Normal 200 Failed in send request Check cable connection and network table setting of the target station. 201 Send error Check that the setting on the target station is consistent with the network table setting. 202 Internal port error The communication unit is in the older version or is faulty. 204 TCP connection over The number of connections reaches the maximum, and no more connection is possible.
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App5-44 Appendix 5 Ethernet Errors during Macro Command Execution The execution result of macro commands SEND/EREAD/EWRITE is stored in system memory address $s515. • System memory address: $s515 (response to the request) Code 0 200 to 2000 Contents Solution Normal Communication error Refer to “Communication Errors.” −30 Timeout Check if an error is occurring to the target V7. −31 The number of words being sent exceeds the limit. Check the number of words that can be sent in macro editing.
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Appendix 6 Universal Serial Communications App6-1 Appendix 6 Universal Serial Communications Interface Outline of Communication V series internal user memory V series Screen No. 0 1234 5678 0 1234 5678 General-purpose computer (ON) Dedicated commands disc RESET Read Write 100 200 300 Screen No. 1 100 200 300 16383 As shown in the diagram above, when a general-purpose computer communicates with the V series, the general-purpose computer acts as the host and the V series acts as the slave.
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App6-2 Appendix 6 Universal Serial Communications Differences between Connecting to a General-purpose Computer and Connecting to the PLC • Input format (code) The input format used for screen number, block number, message number, etc, is fixed in [DEC]. • Write area When connecting to the PLC, only the three words shaded in the diagram below are used, but when connecting to a general-purpose computer, all 16 words shown below are used.
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Appendix 6 Universal Serial Communications App6-3 Memory settings (for lamp, data display, etc.) are required during screen creation, and the memory addresses are mapped as shown below. The memory addresses are $u0 to 16383. Assign memory addresses for system, lamp, data display, and mode within this range. V series internal user memory ($u) 0 V series screen data Screen No. 0 1234 1234 0016 0017 General-purpose computer Dedicated commands 0020 disc RESET Read Write 0030 1200 1201 1202 Screen No.
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App6-4 Appendix 6 Universal Serial Communications System Composition • 1 : 1 connection (one computer, one V series unit) (For wiring, refer to page App6-6 to page App6-9.) The system composition for a 1 : 1 connection is shown. 1) Can be used when the transmission distance via RS-232C is within 15 m, or the transmission distance of RS-422 (485) is not greater than 500 m. 2) It is possible to use an interrupt when connecting a computer to a V series unit in a 1 : 1 connection.
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Appendix 6 Universal Serial Communications App6-5 Input/Output Connector The connection method for communication between a general-purpose personal computer and a V series unit is shown in the diagram below.
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App6-6 Appendix 6 Universal Serial Communications CN1: RS-232C Connector Specifications The specifications for the RS-232C connector that links to the communication device are shown below. Pin No.
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Appendix 6 Universal Serial Communications App6-7 • Interface connector - Use the following types of RS-232C cable connectors. D-sub 25-pin connector (male) DDK type 17JE23250-02 (D8A) or equivalent • Twist-shielded cables - Use twist-shielded cables provided by the following manufacturers. Manufacturer Type Hitachi Cable CO-SPEV-SB(A) 3P × .3SQ Mitsubishi Cable SPEV-SB-MPC 3P × .
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App6-8 Appendix 6 Universal Serial Communications <2-wire system> General-purpose computer V series (CN1) Signal Name Pin No. Signal Name FG 1 FG +SD 12 RDA −SD 13 RDB +RD 24 SDA −RD 25 SDB 7 SG * Use twist-shielded cables. * Use TC485 (Terminal Converter, optional) when V series is connected on the terminal block. For more information, refer to “TC485 (Terminal Converter) Operation Instructions.” TC485 can not be used.
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App6-9 Appendix 6 Universal Serial Communications 1 : n Connection * When you go to [Comm. Parameters] under the [System Setting], to [Main2], and check [Execute 4 Wire Control], 1 : n connection is not available. • Wiring Perform wiring as shown below.
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App6-10 Appendix 6 Universal Serial Communications MJ2 (V706 only) Specifications as an RS-232C Connector CAUTION To use an MJ2 on a V706 as an RS-232C connector, set the slide switch on the V706 to the upper position: RS-232C. For details, refer to the separate V706 Hardware Specifications. The pins of modular jack 2 correspond to signals as given below. MJ2 Pin No.
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Appendix 6 Universal Serial Communications App6-11 MJ2 (V706 only) Specifications as an RS-422 Connector CAUTION To use an MJ2 on a V706 as an RS-422 connector, set the slide switch on the V706 to the lower position: RS-422. For details, refer to the separate V706 Hardware Specifications. The pins of modular jack 2 correspond to signals as given below. MJ2 Pin No.
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App6-12 Appendix 6 Universal Serial Communications 1 : n Connection * When you go to [Comm. Parameters] under the [System Setting], to [Main2], and check [Execute 4 Wire Control], 1 : n connection is not available. • Wiring Perform wiring as shown below. <2-wire system> General-purpose computer Signal Name V706 (MJ2) Terminating resistance (OFF) Signal Name Pin No.
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Appendix 6 Universal Serial Communications App6-13 <4-wire system> General-purpose computer Signal Name V706 (MJ2) Terminating resistance (OFF) Signal Name Pin No. +SD 1 FG +SD RDA -SD 2 -SD RDB +RD 7 +RD SDA -RD 8 -RD SDB SG 5 SG SG V706 (MJ2) Terminating resistance (OFF) Signal Name Pin No. +SD 1 +SD -SD 2 -SD +RD 7 +RD -RD 8 -RD SG 5 SG V706 (MJ2) Terminating resistance (ON) Signal Name Pin No.
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App6-14 Appendix 6 Universal Serial Communications System Setting Model Setting Select universal serial as the model that will communicate with the V series. 1) From the menu bar, go to [System Setting] and click on [PLC Type]. 2) The [Select PLC Type] dialog comes up. Select [Universal Serial] and click the [OK] button. Communication Parameter Make communication parameter settings. 1. From the menu bar, go to [System Setting], and click on [Comm. Parameter].
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Appendix 6 Universal Serial Communications App6-15 2. The [Comm. Parameter] dialog comes up. In the [Main 1], [Main 2], and [Detail] tab windows, set the baud rate, the signal level, etc. When using multi-drop, go to the [Detail] tab window, check [1 : n] for [Connection], and enter [Local No]. It is possible to set the transmission mode by going to the [Detail] tab window and making settings for [Trans. Mode]. Setting Items • Baud Rate Set the communication speed between the host and the V series.
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App6-16 Appendix 6 Universal Serial Communications • Read Area This memory area is necessary when the display screen is changed by a command received from the host. Be sure to allocate only $u memory. Address allocation is shown in the table below. For details on addresses, refer to Chapter 1 in the Reference Manual (Function).
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Appendix 6 Universal Serial Communications App6-17 - System memory ($s) within internal memory Address 000 Contents Screen number 001 002 Overlap 0 Status 0: OFF 1: ON 003 Overlap 1 Status 0: OFF 1: ON 004 Overlap 2 Status 0: OFF 1: ON 080 Universal serial port switch output 0 Output code 0 - 15 081 Universal serial port switch output 1 Output code 16 - 31 082 Universal serial port switch output 2 Output code 32 - 47 083 Universal serial port switch output 3 Output code 48 - 63
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App6-18 Appendix 6 Universal Serial Communications - n + 7 (ENT2) entry information 2 The entry mode window number where a write operation was executed is written. The relationship between the window number and base and the window number and overlap is shown in the following table. Window No.
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Appendix 6 Universal Serial Communications App6-19 • Read Clear Escape (Backup) Address Set the top address for the read clear backup area. The area size will be the same as the previously described read clear area. The number of words written in the read clear backup area are the same as the number specified for the read clear area. - Read Clear and Read Clear Backup Action The action that occurs when a read command from the host tries to access to the read clear area is shown in the following diagram.
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App6-20 Appendix 6 Universal Serial Communications • Interrupt There are five interrupt settings: Switch ON interrupt Switch OFF interrupt Keypad interrupt Screen interrupt Macro: OUT_ENQ For details, refer to page App6-38. • Execute Flow Control (disabled for V706) Check the [Execute Flow Control] when interrupt from V series is needed to be prohibited. (e.g. when the host cannot receive interrupt data) The action when you check the [Execute Flow Control] is shown below.
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Appendix 6 Universal Serial Communications App6-21 • Data Length Fixed at 8 bits. • Stop Bit Stop bit settings are shown below. 1 bit 2 bits • Code Fixed at DEC. • Text Process When using text process, choose either [LSB to MSB] or [MSB to LSB] in order to make arrangements for the order of the first and the second bytes in one word.
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App6-22 Appendix 6 Universal Serial Communications Connection (1 : 1), Transmission Mode (w/ sum check) Used when one host communicates with one V series unit (1 : 1).
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Appendix 6 Universal Serial Communications App6-23 • Interrupt conditions An interrupt code is sent to the host for the following actions. - When the switch status changes from ON to OFF or from OFF to ON - When the [ENTER] switch on the keypad changes from OFF to ON. (If [ Use the Write Flag] in [System Setting] is checked, write enable bit must be set in order to send interruption.
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App6-24 Appendix 6 Universal Serial Communications Connection (1 : 1), Transmission Mode (w/ sum check and CR/LF) Used when one host communicates with one V series unit (1 : 1).
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Appendix 6 Universal Serial Communications App6-25 • Interrupt conditions An interrupt code is sent to the host for the following actions. - When the switch status changes from ON to OFF or from OFF to ON - When the [ENTER] switch on the keypad changes from OFF to ON. (If [ Use the Write Flag] in [System Setting] is checked, write enable bit must be set in order to send interruption.
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App6-26 Appendix 6 Universal Serial Communications Connection (1 : n), Transmission Mode (w/ sum check) It is possible to attach as many as 32 V series units to one host. (For information on the global command, refer to page App6-30.) Contents Protocol S C t S a o D D E S Transmission Transmission t m data data T oi m L L T U n a n E Part A E Part B X M X N d Host side o.
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Appendix 6 Universal Serial Communications App6-27 Connection (1 : n), Transmission Mode (w/ sum check and CR/LF) It is possible to attach as many as 32 V series units to one host. (For information on the global command, refer to page App6-30.) Contents Protocol S C t E S S a o D D Transmission Transmission t m C L data data T U T oi m L L R F n a n E Part A E Part B X M X N d Host side o.
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App6-28 Appendix 6 Universal Serial Communications Data Items for Protocols • Transmission control code The transmission control codes are shown in the table below.
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Appendix 6 Universal Serial Communications App6-29 Response Time and BUSY Response time varies depending on the type of command. • RM / RI / RC These commands immediately send a response once receipt of data is complete. No NAK [01] (BUSY) signal is given. Host side (command) V series (Response) T T = 10 msec or less • WM / TR / WI / WC Once receipt of data is complete, these commands first check the display status.
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App6-30 Appendix 6 Universal Serial Communications Global Port Number (FFH) Active for connection mode (1 : n). When the port number is set as [FFH] and a command is executed, all V series units that are connected send a response in reply to a command from the host. Commands for which global port number are active are shown below. If commands other than these are used, a command error will occur.
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Appendix 6 Universal Serial Communications App6-31 Read CHR Command When memory contents are in the form of characters when data is read, 1 character (1 byte) is converted into 2-byte ASCII code and transmitted. However, when this command is used, contents are not converted before transmission, and thus, the transmission time is decreased by approximately 1/2.
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App6-32 Appendix 6 Universal Serial Communications Read Memory Command Note: Due to the fact that communication speed is increased when you use the read CHR command to read characters, it is recommended that you use this command.
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Appendix 6 Universal Serial Communications App6-33 Write CHR Command When memory contents are in the form of characters, it is necessary to use a write command to convert 1 character (1 byte) into 2 byte ASCII code and then transmit. However, with this command contents are transmitted just as they are, and consequently, the transmission time is decreased by 1/2. (Character codes from 00 to 1F cannot be used.
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App6-34 Appendix 6 Universal Serial Communications Write Memory Command Note: Due to the fact that communication speed is increased when you use the write CHR command to write characters, it is recommended that you use this command.
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Appendix 6 Universal Serial Communications App6-35 Retry Command Use this command when a write command/write CHR command is sent and an NAK error code [01] is returned. • Retry command Command A Retry command S T X E S TR T U X M * Retry command re-sends the command A which is waiting. Host side HL V series side A C K Error code 01H * In the case that error code [01] is returned, command A is on standby as the V series is currently engaged in display processing.
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App6-36 Appendix 6 Universal Serial Communications Interrupt Setting Command • Interrupt setting command Interrupt setting command D E S a T U t a X M S T WI X Host side HL HL V series side A C K - Host side Interrupt conditions can be specified when the interrupt data bit is set.
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Appendix 6 Universal Serial Communications App6-37 Interrupt Status Read Command • Interrupt status read command Interrupt status read command S T E S RI X T U X M Host side HL V series side S D E S a T T U t X a X M HL HL - Host side Interrupt status is read. Data: Interrupt status (HEX ASCII) 07 06 05 04 03 02 01 00 Switch ON 0: Interrupt prohibited 1: Interrupt allowed Switch OFF Keypad write & character entry Screen internal switching Example: Interrupt status is read.
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App6-38 Appendix 6 Universal Serial Communications Interrupt (ENQ) When interrupt is used when the connection mode is (1 : 1)*, this code is transmitted. The transmission occurs when a regular key is pressed or when the [ENTER] key is pressed in the entry mode. (For information on interrupt timing, refer to page App6-23.) Interrupt data becomes the contents of write areas n + 2 to n + 7. (Refer to page App6-16.) * For RS-422 (485) 2-wire connection, interrupts cannot be used.
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Appendix 6 Universal Serial Communications App6-39 It is possible to use a macro command to initiate an interrupt. There are two ways to use a macro command to transmit data. You can either convert the data into HEX code and transmit it, or you can transmit the data just as it is without converting it. Use the macro command (OUT_ENQ). For details, refer to Chapter 13 in the Reference Manual (Function).
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App6-40 Appendix 6 Universal Serial Communications Switch Output (See page App6-16, page App6-23 and page App6-38.) When [Output Action] of a switch is set to [Momentary] and [Output Memory] is set in location ($s80-95) of system memory, the following actions occur when the switch is pressed. When the bit memory specified in system memory is set, and the switch is released, it is reset. The switch number that corresponds to the bit is written in write areas n + 3 and n + 4.
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Appendix 6 Universal Serial Communications App6-41 The switch number is written in the following way in write areas n + 3 and n + 4. n + 3, n + 4 (SW0/SW1) 15 14 13 12 11 10 09 08 0 0 0 0 0 0 0 07 06 05 04 Switch status 0: OFF 1: ON 03 02 01 00 Switch number When the MONITOUCH is connected to the host in a 1 : 1 connection, interrupt occurs as is shown below. * For RS-422 (485) 2-wire connection, interrupts cannot be used.
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App6-42 Appendix 6 Universal Serial Communications 09H: Received data over The number of write command data received from the host exceeded that of data shown below. • Write memory command = 512 words • Write CHR command = 1024 bytes 0BH: Retry command error When a retry command is received, there is no BUSY status (NAK [01]) command. 0FH: ETX error No ETX code is found. 10H: DLE error There is no DLE code. 11H: Character error A character not used in the received data is found.
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Appendix 6 Universal Serial Communications App6-43 1-byte Character Code List Upper 0 0 1 3 4 5 6 7 SP 0 @ P ’ p 2 1 ! 1 A Q a q 2 " 2 B R b r 3 # 3 C S c s 4 $ 4 D T d t 5 % 5 E U e u 6 & 6 F V f v 7 ’ 7 G W g w 8 ( 8 H X h x 9 ) 9 I Y i y : J Z j z [ k { l | Lower A B + ; K C , < L = M ] m } ~ D E .
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App6-44 Appendix 6 Universal Serial Communications Memory Map Memory Inside the V series, there is internal memory necessary for screen display called “user memory ($u),” as well as memory that the V series uses for the system called “system memory ($s).” User Memory ($u) 16384 words are available for user memory. This area is usable as desired for screen data. Also the host computer can write to and read from the area. The memory map is as shown below.
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Appendix 6 Universal Serial Communications App6-45 System Memory ($s) System memory is memory that writes V series action status when the V Series is currently displaying something. With this written information, it is possible to check overlap status, buffer area, printer, backlight, and slave station status in multi-drop connection mode. * System memory cannot be read or written from the host computer. In the table below, a small part ($s80 to 95) of system memory is extracted.
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App6-46 Appendix 6 Universal Serial Communications • Address 0080 to 0095 The [Output Memory] of a switch is assigned to bits in this area. Set [Output Action] to [Momentary]. When a switch is pressed, bit memory is set to “1” and the corresponding switch number is written in system setting areas n + 3 and n + 4. (Refer to page App6-16.) The relationship between the bit and the switch number is shown in the following diagram. For details about the output of a switch, refer to page App6-40.
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App6-47 Appendix 6 Universal Serial Communications Switch ON Macro Action The macro command that controls a repeat function in the switch ON macro, as well as the processing sequence, is shown in the following diagram.
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App6-48 Appendix 6 Universal Serial Communications Please use this page freely.
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Appendix 7 V-Link App7-1 Appendix 7 V-Link V-Link • “V-Link” is the network where the computer reads from and writes to the internal memory of the V7 series, memory card, PLC memory or temperature control/PLC2 memory using a dedicated protocol. Dedicated commands Read disc SYSTEM Write F1 F2 F3 F4 F5 RESET F6 F7 POWER PC PLC V7 series • Connection with computer When connecting to the V7 series or a V706 equipped with DU-01, use the MJ1 port.
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App7-2 Appendix 7 V-Link Wiring Cable Use Hakko Electronics’ cable “V6-TMP” (3 m) for connection with a computer. The shielded cable of V6-TMP is connected to FG (frame ground) when the V7 series is used and to SG (signal ground) when the V706 is used. V6-TMP * Notes on Use of V6-TMP There are six wires in the V6-TMP cable as shown on the right. The wires to be used are determined depending on the connecting method. For the wires not used, be sure to properly insulate with tape, etc.
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Appendix 7 V-Link App7-3 RS-485 (V7 series: maximum 31 sets) RS-232C → RS-485 conversion Computer a Terminal block Terminal block }* }* b V6-TMP Terminal block }* MJ2/1 MJ2/1 MJ2/1 V7 Local Port 1 V7 Local Port 2 V7 Local Port 31 CN1 CN1 CN1 PLC PLC PLC * 0.5 m recommended (1.
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App7-4 Appendix 7 V-Link V-SFT Setting The V-SFT settings required for V-Link are explained. V-Link Setting 1. Click [System Setting] → [V-Link Setting]. 2. The [V-Link Setting] dialog is displayed. 3. Check [ Use MJ Port as V-Link] and make the setting for communications between the V7 series and the computer. [Refer to Modular] Select the modular jack to be used.
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Appendix 7 V-Link Protocol Read (with sum check and CR/LF) Read Command Command * S V7 Number Read target E S C L Read of words T U T local memory command to read X M R F X No. setting 1 Response (Normal communication) 2 2 2 18 S V7 A Memory data T local C X No. K 0 1 2 2 1 2 1 1 Bytes Memory E S C L data T U X M R F n 4 1 4 2 1 1 Bytes (When an error occurs) S V7 N E S C L T local A T U X No.
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App7-6 Appendix 7 V-Link Write (with sum check and CR/LF) Write Command Command * S V7 Number Write target Memory Write of words T local memory data command to write X No. setting 0 1 2 2 2 18 Memory E S C L T U data X M R F n 4 1 4 2 1 1 Bytes Response (Normal communication) S V7 A E S C L T local C T U X No. K X M R F 1 2 2 1 2 1 1 Bytes (When an error occurs) S V7 N E S C L T local A T U X No.
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Appendix 7 V-Link App7-7 Data Items for Protocols • Transmission control code: 1 byte Signal Name Code (Hexadecimal) Contents STX 02H Start of transmission block ETX 03H End of transmission block CR 0DH Carriage return LF 0AH Line feed • V7 port number: 2 bytes Port numbers are used so that the host computer can identify each V7 series for access. The data range is from 01H to 1FH (1 to 31) and is converted into the ASCII code before use.
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App7-8 Appendix 7 V-Link - Expansion code Set the slot number of the CPU memory of the MITSUBISHI PLC or the CPU number of the YOKOGAWA PLC. Example: MITSUBISHI Slot No. 0: 00H MITSUBISHI Slot No. 1: 01H YOKOGAWA CPU No. 1: 00H YOKOGAWA CPU No. 2: 01H * If no expansion code or port number is required, enter “00” (= 3030 in the ASCII code). - Port number 1 : 1, Multi-link ....................................................Not used Multi-drop............................................................
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Appendix 7 V-Link NAK: Error Codes 02H: Overrun/Framing error An overrun or framing error is detected in the received data. Send the command again. 03H: Parity error A parity error is detected in the received data. Send the command again. 04H: Sum check error A sum error occurs with the received data. 06H: Count error The memory read/write count is “0.” 0FH: ETX error No ETX code is found. 11H: Character error A character not used in the received data is found.
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App7-10 Appendix 7 V-Link 1-byte Character Code List Upper 0 0 1 3 4 5 6 7 SP 0 @ P ’ p 2 1 ! 1 A Q a q 2 " 2 B R b r 3 # 3 C S c s 4 $ 4 D T d t 5 % 5 E U e u 6 & 6 F V f v 7 ’ 7 G W g w 8 ( 8 H X h x 9 ) 9 I Y i y : J Z j z [ k { l | Lower A B + ; K C , < L = M ] m } ~ D E .
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List-1 Connection Compatibility List V712/V710/V708/V706+DU-01 • • • • • • • 1 : 1..............................One set of the V7 series is connected to one PLC (1:1 connection). 1 : n..............................One V7 series is connected to multiple PLCs. Multi-link2 ....................One PLC is connected to a maximum of four V7 series. n : 1 (Multi-link) ............One PLC is connected to multiple V7 series.
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List-2 Manufacturer PLC 1:1 1:n (Multi-drop) Multi-link 2 n:1 (Multi-link) A series link Ethernet Field Network Controller Network CC-Link OPCN-1 Net10 CC-Link Net10 *2 CC-Link Net10 *2 CC-Link Net10 PLC2Way A series CPU QnA series link QnA series CPU with V-MDD QnH (Q) series link QnH (A) series CPU MITSUBISHI ELECTRIC QnH (Q) series CPU Q00J/00/01CPU FX series CPU FX2N series CPU FX1S series CPU FX series link (A Protocol) A link + Net10 MODICON *3 *1 Modbus RTU MOELLER PS4
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List-3 V706 • • • • • • 1 : 1..............................One set of the V706 series (MJ2) is connected to one PLC (1:1 connection). 1 : n..............................One V7 series is connected to multiple PLCs. Multi-link2 ....................One PLC is connected to a maximum of four V7 series. n : 1 (Multi-link) ............One PLC is connected to multiple V7 series. To use Ethernet communications, a communication interface unit is necessary.
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List-4 Manufacturer PLC 1:1 1:n (Multi-drop) Multi-link 2 n:1 (Multi-link) Ethernet Field Network Controller Network PLC2Way A series link A series CPU QnA series link *2 QnA series CPU with V-MDD QnH (Q) series link *2 QnH (A) series CPU MITSUBISHI ELECTRIC QnH (Q) series CPU Q00J/00/01CPU FX series CPU *6 FX2N series CPU FX1S series CPU FX series link (A Protocol) A link + Net10 MODICON *3 *1 Modbus RTU MOELLER PS4 SYSMAC C *2 SYSMAC CV *2 OMRON SYSMAC CS1/CJ1 SYSMAC CS1/CJ1 DNA
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Hakko Electronics Co., Ltd.