JP2010108219A - Control system, communication relay device and portable programmable display unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To establish connection between a programmable display unit and a PLC, with ease and without incorrect setup, when the portable programmable display unit is used by switching the connection between a plurality of the PLCs. <P>SOLUTION: Conversion adapters 21-24 are respectively connected to a plurality of the PLCs 11-14 to which the IP address is set up. ID corresponding to the IP addresses of the connected PLCs 11-14 is set up to the conversion adapters 21-24, respectively. A portable programmable display unit 30 stores the list in which the IP addresses set up in each of the PLCs 11-14 are associated with the ID of respective conversion adapters 21-24. The programmable display unit acquires the ID from the connected conversion adapter 21, identifies the IP address corresponding to the ID from the list, sets up it in a communication driver, communicates with the PLC11 in which the IP address is set via the conversion adapter 21. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a communication relay device that facilitates connection between a portable programmable display and a plurality of programmable logic controllers each having an IP address, a portable programmable display connected thereto, and a control system including the same. Is.

  The programmable display has a communication interface with a controller such as a programmable logic controller (PLC), temperature controller, inverter, etc., and displays the operation status of the controller and operation inputs for giving control instructions to the controller. This is an operation-type display device with a function of accepting from. In general, since the programmable display has a graphic display function, it can display an operation panel, a switch, an indicator lamp, and the like, and serves as an operation terminal in the control system. In such a control system, display of the operating status of each controller and control instructions to the controller are performed by a programmable display.

For example, as disclosed in Patent Document 1, such a programmable display is connected not only to the PLC but also to a host computer or the like by utilizing the communication function, and exchanges data with each device. In the control system disclosed in Patent Document 1, a plurality of PLCs, a plurality of programmable displays, and a host computer are connected via a network. In this control system, the PLC, the programmable display, and the host computer store the preset IP address and port number of themselves and the destination, respectively. In such a control system, the programmable display is always connected to the network.
JP 2002-111680 A (released on June 14, 2002)

  The programmable display used in the above control system is a stationary type model incorporated in an apparatus or the like. In addition to such stationary programmable displays, portable programmable displays also exist.

  When such a portable programmable display is used as a programmable display for the above control system, when changing the PLC connected to the programmable display, it is set to the offline state and the IP address of the connection destination PLC is newly connected. The IP address of the PLC to be changed must be changed. Specifically, after the programmable display is set to an offline state, the IP address of the connection destination PLC is changed in a state where a screen for setting communication conditions is displayed.

  However, since other setting items are also displayed on the setting screen, there is a possibility that the setting items may be changed by mistake. In particular, when an operator who is not familiar with the operation of the setting screen changes the setting, or when the setting is changed every time the PLC connection is frequently switched, the possibility increases. When such an erroneous setting occurs, there is a possibility that normal communication cannot be performed.

  The present invention has been made in view of the above-described problems. When a portable programmable display is used by switching the connection to a plurality of PLCs, the connection between the programmable display and the PLC can be easily performed without erroneous settings. The purpose is to establish.

  The control system according to the present invention includes a portable programmable display, a plurality of programmable logic controllers each set with an IP address, and a plurality of communication relays that relay communication between each programmable logic controller and the portable programmable display. A control system capable of establishing a connection between any of the programmable logic controllers in the plurality of programmable logic controllers and the portable programmable display, wherein each communication relay device is one of the IP addresses ID storage means for registering an ID set in association with one, and reading the ID from the ID storage means in response to a transmission request from the portable programmable display and transmitting it to the portable programmable display ID transmission means The portable programmable display is registered with the storage means for storing each association between the IP address and the ID, and the ID corresponding to the IP address of the programmable logic controller to establish a connection. The transmission request means for making an ID transmission request to the communication relay device, the IP address corresponding to the transmitted ID is specified from the association as the IP address of the communication partner, and the IP address is set. And communication establishing means for establishing communication with the programmable logic controller.

  The communication relay device according to the present invention is a communication relay device that relays communication between a programmable logic controller in which an IP address is set and a portable programmable display, and an ID set in association with the IP address. And an ID transmission means for reading the ID from the ID storage means and transmitting it to the portable programmable display in response to a transmission request from the portable programmable display. It is a feature.

  Moreover, the portable programmable display which concerns on this invention is a portable programmable display which can be connected with the said communication relay apparatus, Comprising: The memory | storage means which memorize | stores each matching with the said IP address and the said ID, and connection Transmission request means for requesting transmission of an ID to the communication relay apparatus in which the ID corresponding to the IP address of the programmable logic controller to be established is registered; and the IP address corresponding to the transmitted ID It is characterized by comprising communication establishing means for establishing communication with the programmable logic controller in which the IP address is set by specifying from the correspondence as the IP address of the communication partner.

  In said structure, when a portable programmable display requests | requires transmission of ID to the connected communication relay apparatus, ID registered into ID memory | storage means will be transmitted to a portable programmable display by ID transmission means. When the portable programmable display device acquires the ID, the communication establishment unit specifies the IP address corresponding to the ID from the association stored in the storage unit, and registers the IP address as the communication partner's IP address. Establish communication with the programmable logic controller for which the IP address is set.

  Thereby, the programmable logic controller to be connected by the portable programmable display according to the ID acquired by the transmission request from the portable programmable display in association with switching the connection of the portable programmable display to the communication relay device IP address is set. As a result, unlike the conventional stationary programmable display, it is not necessary to go offline and reset the IP address on the setting screen by the user. Incorrect settings can be avoided.

  The control system according to the present invention includes a plurality of programmable logic controllers in which IP addresses are set, a plurality of the communication relay devices corresponding to the programmable logic controllers, and the portable programmable display that can be connected to each communication relay device. Therefore, the IP address of the programmable logic controller whose connection has been switched can be easily and accurately registered in the portable programmable display. Therefore, there is an effect that the switching operation between the portable programmable display and the plurality of programmable logic controllers can be efficiently performed.

  The embodiment of the present invention will be described with reference to FIGS. 1 to 6 as follows.

  As shown in FIG. 1, the control system 1 according to the present embodiment includes PLCs (programmable logic controllers) 11 to 14, conversion adapters 21 to 24, and a programmable display 30.

  The PLCs 11 to 14 are individually set with IP (Internet Protocol) addresses so that network communication is possible. The PLCs 11 to 14 are connected to the corresponding conversion adapters 21 to 24 via LAN (Local Area Network) cables. The PLCs 11 to 14 are input devices (various sensors, various switches) via an input unit at predetermined scan times such as several tens of ms according to a sequence program (ladder program or the like) created by the user. Etc.) and control instructions are given to output devices (actuators, relays, solenoid valves, indicators, etc.).

  The memories (device memories) in the PLCs 11 to 14 store data (word data and bit data) indicating the state of the device (output value from the device and set value to the device) in an area specified by the device address. ing. In the memory, a word device and a bit device are set. The word device is set as an area for storing word data such as numeric values as input / output data, and is designated by a word address (device address). The bit device is set as an area for storing bit data such as an on / off state, and is set by a bit address (device address). With such a setting, it is possible to control a device by simply accessing an arbitrary word device or bit device in the memory by specifying a device address, or to individually retrieve information relating to the state of the device.

  The conversion adapters 21 to 24 are devices that relay communication between the PLCs 11 to 14 and the programmable display 30 connected thereto. Moreover, IDs corresponding to the IP addresses of the connected PLCs 11 to 14 are registered in the conversion adapters 21 to 24, respectively. Details of the conversion adapters 21 to 24 will be described in detail later.

  The programmable display 30 which is a portable programmable display has an interface that is communicably connected to any of the conversion adapters 21 to 24. Moreover, the programmable display 30 has memorize | stored the address list which matched individually the IP address set to each PLC11-14, and ID of each conversion adapter 21-24. Moreover, the programmable display 30 acquires ID from the connected one of the conversion adapters 21-24, specifies IP address corresponding to the said ID from said address list, and sets it to a communication driver. Thereby, the programmable display 30 communicates via the conversion adapter connected with one of PLC11-14 in which this IP address is set. The programmable display 30 will also be described in detail later.

  Further, another control system 2 shown in FIG. 2 will be described.

  In the control system 2, the same components as those in the control system 1 are denoted by the same reference numerals, and the description thereof is omitted.

  As shown in FIG. 2, another control system 2 according to the present embodiment includes a host computer 4, a hub 5, PLCs 11 to 14, conversion adapters 21 to 24, and a programmable display 30. Various devices such as processing devices and manufacturing devices are connected to the PLCs 11 to 14, and the control system main body is configured by the hub 5, the PLCs 11 to 14, the conversion adapter, and the various devices (not shown).

  In this control system 2, the PLCs 11 to 14 and the conversion adapters 21 to 24 are connected to each other via a hub 5 that is a star-type LAN concentrator, and the host computer 4 is also connected to the hub 5. With such a configuration, the programmable display 30 is connected to one of the PLCs 11 to 14 in which the IP address corresponding to the ID acquired from one of the connected conversion adapters 11 to 14 is set, and the connected conversion. Communication is performed via the adapter and the hub 5. Further, the host computer 4 gives control instructions or collects data by communicating with the PLCs 11 to 14 and the programmable display 30 via the hub 5, for example.

  Next, the conversion adapters 21 to 24 will be described. As shown in FIG. 3, here, a conversion adapter 20 that represents the conversion adapters 21 to 24 will be described.

  As shown in FIG. 3, the conversion adapter 20 includes an interface unit (indicated by “I / F” in the figure) 201, a microcomputer 202, and a rotary dip switch (indicated by “SW” in the figure) 203. Yes.

  The interface unit 201 is a part including a connector connected to the programmable display 30. Ethernet (registered trademark) data DATA is exchanged between the programmable display 30 and the PLC 10 (corresponding to the PLCs 11 to 14) via the interface unit 201. Further, an ID request command COM and an ID described later are exchanged between the programmable display 30 and the microcomputer 202 via the interface unit 201. The interface unit 201 also includes a connector for outputting a power supply voltage input from the outside to the conversion adapter 20 to the programmable display 30 (not shown) in order to perform a function of supplying power to the programmable display 30. It is out.

  The cable for connecting the conversion adapter 20 and the programmable display 30 is as thin as possible (light) and flexible in order to reduce the weight applied to the programmable display 30 and not to impair the operability of the programmable display 30. It is preferable that Therefore, the cable is formed so that the communication line and the power supply line are combined into one cable. Specifically, in one cable, a communication line is arranged on the center side, and a power supply line is arranged so as to surround the periphery.

  The microcomputer 202 includes a CPU and a memory, and has an ID memory 202a and an ID management unit 202b for registering the ID set by the rotary dip switch 203 and reading it by a request from the programmable display 30. is doing. The ID memory 202a is composed of the memory provided in the microcomputer 202 and stores an ID. The ID management unit 202b writes the ID set by the rotary dip switch 203 to the ID memory 202a, while receiving the ID request command COM from the programmable display 30, reads the ID stored in the ID memory 202a, It transmits to the programmable display 30. The ID management unit 202b is a functional block part realized by the CPU executing an ID management program stored in a program memory (not shown) of the microcomputer 202.

  The rotary dip switch 203 is a rotary dip switch and is provided for setting an ID. By configuring the rotary dip switch 203 with a combination of a plurality of dip switches, a large number of IDs can be set. For example, when two dip switches that can set four values are combined, 16 IDs can be set.

  Next, the programmable display 30 will be described.

  The programmable display 30 includes an arithmetic processing unit such as a CPU, and realizes an operation function and a display function unique to the programmable display by displaying a screen for input operation and display based on screen data created by the user. It is a dedicated computer. A programmable display 30 that is preferably used as an HMI (Human Machine Interface) device includes PLCs 11 to 11 based on screen data determined by combining processing definition information that defines various types of processing performed in association with a user screen. The operation when displaying the state of the device connected to the screen 14 and the operation when controlling the state of the device according to the operation on the screen are specified.

  This programmable display 30 has a function of acquiring the state of each device to be displayed on the screen via the PLCs 11 to 14 through communication with the PLCs 11 to 14 and displaying the state of each device on a display 32 described later, for example. . Moreover, the programmable display 30 has a function which instruct | indicates control of a device to PLC11-14 according to operation to the below-mentioned touch panel 35. FIG.

  In order to realize the above functions, the programmable display 30 includes an HMI control unit 31, a display 32, a touch panel 33, a user memory 32, a work memory 33, and an interface unit (I / F in the figure) 34. A communication driver 35 and a memory card reader / writer 36. Hereinafter, each main part of the programmable display 30 will be described in detail.

  As the display 32, a flat panel display such as a liquid crystal display, an EL display, or a plasma display is preferably used to make the programmable display device 1 thin. The touch panel 33 is an input device provided for performing touch input on the display image of the display 32.

  The interface unit 34 is a communication control unit for connecting the programmable display 30 to a network (LAN or the Internet) to perform communication with the PLCs 11 to 14 and other devices. The interface unit 34 is configured to be able to perform network communication based on the IP address of a device such as the PLCs 11 to 14 in accordance with a processing procedure defined by the communication driver 35.

  Further, since the programmable display 30 does not have a power source or a dedicated power input terminal and receives power supply from the conversion adapter 20 as described above, the interface unit 34 has a circuit for power input, a terminal structure, and the like. Is included.

  The user memory 32 is a memory for storing screen data, the above communication protocol, and the like, and FEPROM (Flash Erasable and Programmable ROM) is used. Since FEPROM is a rewritable read-only flash memory, it plays the role of a hard disk drive in a general personal computer. A flash memory does not have a movable part and is resistant to impacts, and thus operates stably even in a poor ambient environment.

  The screen data is a screen file in which data of one or more user screens (unit screens configured by screen data for one frame) displayed on the programmable display 30 is collected. As the screen data, a series of related screen data corresponding to a target system or a product manufactured by the target system is usually prepared as a set of project files. The screen data (project file) is created by using screen creation software installed in a personal computer or the like.

  Further, the user memory 32 stores address list data (address list data) in which the IP addresses of the PLCs 11 to 14 are associated with the conversion adapters 21 to 24. In the address list, for example, as shown in Table 1, IP addresses and IDs are associated with each other.

  The work memory 33 is constituted by, for example, a DRAM, and is used for temporary storage of data exchanged with the PLCs 11 to 14 in addition to being used for work during arithmetic processing such as display control. The work memory 33 stores ID data acquired from the conversion adapters 21 to 24.

  The programmable display 30 includes a data memory (not shown) in addition to the user memory 32 and the work memory 33 described above. The data memory is composed of SRAM, and stores data obtained from the PLCs 11 to 14 and data generated by the programmable display 30.

  The communication driver 35 is driver software for causing the interface unit 34 to perform network communication. The communication driver 35 is set with the IP address and port number of the programmable display 30 and the IP address and port number of the communication partner device (for example, the PLCs 11 to 14). Perform communication processing.

  Each setting described above for the communication driver 35 is performed in the creation of screen data. The IP address set in the communication driver 35 can be changed by the IP address setting unit 31a as will be described later, but can also be changed by using the export and import functions. Specifically, the IP address is exported to an external editor in the CSV format, and the IP address edited by the editor is read by import.

  The memory card reader / writer 36 is a device that writes and reads data to and from the memory card 6 that is detachably connected to the programmable display 30. For example, the memory card 6 stores screen data (project file). A CF card (registered trademark) is preferably used as the memory card 6.

  The HMI control unit 31 acquires the device state as state data from the device memory of the PLCs 11 to 14 by communicating with the PLCs 11 to 14 at every predetermined time interval or every predetermined event, and in the programmable display 30 Are written in a temporary memory space prepared in the above, for example, a specific area (state memory area) of the aforementioned working memory. Further, the HMI control unit 31 rewrites the state data of the device in the state memory area so as to update the state data in the device memory of the PLCs 11 to 14 and transmits it to the PLCs 11 to 14. Based on the above-mentioned screen data, the HMI control unit 31 acquires device state data from the PLCs 11 to 14 and draws and displays it on the display 33, and the state of the device 6 according to the operation on the screen. The operation when the change is instructed is specified by the process definition information.

  The HMI control unit 31 includes an IP address setting unit 31a.

  The IP address setting unit 31a transmits an ID request command COM for requesting transmission of ID data to the connected conversion adapters 21 to 24. The IP address setting unit 31 a stores the ID data transmitted from the conversion adapters 21 to 24 in the work memory 33. In addition, the IP address setting unit 31 a reads the address list data stored in the user memory 32 into the work memory 33 and refers to the IP address corresponding to the ID data stored in the work memory 33 to identify the communication driver 35. Set to.

  The HMI control unit 31 is a functional block realized by causing an arithmetic processing unit such as a CPU provided in the programmable display 30 to execute the HMI control program. The above HMI control program can be recorded on a recording medium configured to be separable from the programmable display 30 and may be installed in the programmable display 30 from the recording medium. The HMI control program is individually prepared for each model in order to exhibit a function corresponding to the model of the programmable display 30.

  The above recording media include tape systems such as magnetic tapes and cassette tapes, magnetic disk systems such as flexible disks and hard disks, optical disk systems such as CD-ROM, MO, MD, and DVD, IC cards (including memory cards), optical A card system such as a card is preferred. In addition, the program medium may be a medium that carries a fixed program including a semiconductor memory such as a mask ROM, EPROM, EEPROM, flash ROM, or the like.

  Further, as long as the programmable display 30 is configured to be connectable to a communication network including the Internet, it may be a medium that fluidly carries the program so as to download the program from the communication network. However, when the program is downloaded from the communication network in this way, the download program may be stored in advance in the programmable display 30 or may be installed from another recording medium.

  Here, an operation for establishing communication between the programmable display 30 and the PLCs 11 to 14 in the control systems 1 and 2 configured as described above will be described with reference to the flowcharts of FIGS. 5 and 6.

  First, ID data transmission processing performed by the microcomputer 202 in the conversion adapter 20 (conversion adapters 21 to 24) will be described.

  First, as shown in FIG. 5, when the CPU of the microcomputer 202 is initialized (step S1), it enters a standby state in which a command can be received (step S2). When a command from the programmable display 30 is received in step S2, it is determined whether or not the command is an ID request command COM (step S3). If the received command is an ID request command, the ID is transmitted to the programmable display 30 (step S4).

  Next, ID data acquisition processing and IP address setting processing performed by the HMI control unit 31 (IP address setting unit 31a) in the programmable display 30 will be described. Here, a case where the programmable display 30 is connected to the conversion adapter 21 will be described.

  First, as shown in FIG. 6, when the HMI control unit 31 is initialized as the programmable display 30 is turned on (step S11), an ID request command COM is issued from the IP address setting unit 31a to the conversion adapter 21. (Send) (Step S12). Next, in response to the ID request command COM, it is determined whether or not the ID transmitted from the microcomputer 202 of the conversion adapter 21 has been acquired (received) in step S4 (step S13). Here, when the ID is acquired, it is stored in the work memory 33, and when the ID cannot be acquired, the process is terminated.

  Then, referring to the address list data in the user memory 32, the IP address corresponding to the acquired ID is specified (step S15). Further, the IP address is set in the communication driver 35 (step S16), communication is started with the PLC 11 in which the IP address is set (step S17), and the processing is ended when the communication is completed.

  As described above, the control devices 1 and 2 in the present embodiment include the conversion adapters 21 to 24 for registering IDs associated with the IP addresses of the individually programmable display devices 11 to 14 and programmable display devices. 30 is configured to specify the IP address of the PLCs 11 to 14 to be connected based on the ID acquired from the conversion adapters 21 to 24 to which the communication adapter 30 is connected, and set the IP address in the communication driver 35 to establish communication. Yes. Thereby, when the connection of the programmable display 30 to the conversion adapters 21 to 24 is switched, the PLCs 11 to 14 are automatically connected via the conversion adapters 21 to 24 only by turning on the power of the programmable display 30. Connection is made. As a result, unlike the conventional stationary programmable display, it is not necessary to go offline and reset the IP address on the setting screen by the user. Incorrect settings can be avoided.

  In particular, in the control system 2, if the PLCs 11 to 14 are provided at the front, both sides, and the rear of the control system main body in which the PLCs 11 to 14 are incorporated, the operator moves to various places on the control system main body. Therefore, it is necessary to monitor the movable state and give a control instruction to the PLCs 11 to 14. In such a case, since the connection change of the programmable display 30 to the PLCs 11 to 14 is frequently performed, the work efficiency can be significantly improved by changing the setting of the IP address accompanying the connection change.

  Further, in the conversion adapters 21 to 24, the operator can change the ID even when the programmable display 30 is in an online state by operating the rotary dip switch 203. Specifically, the IP address setting unit 31a does not transmit the ID request command COM only after the initialization as in the process of step S12 described above, but periodically transmits the ID request command COM. If the ID is changed, the ID can be acquired accordingly. Thereby, in the state connected to the same conversion adapter 21-24, since PLC11-14 connected to the programmable display 30 is switched, without switching the connection to the conversion adapter 21-24 of the programmable display 30, Different PLCs 11-14 can be monitored and controlled.

  In the present embodiment, the configuration in which the control systems 1 and 2 each include four PLCs 11 to 14 and four conversion adapters 21 to 24 has been described, but the number of each is not limited thereto.

  In the present embodiment, when the connection of the programmable display 30 to the conversion adapters 21 to 24 is switched, the IP address is also changed accordingly. However, the IP address may be changed. For example, when there are a plurality of control system bodies shown in FIG. 2 as devices having different PLC 11 to 14 models and manufacturers, a plurality of project files corresponding to each device are stored in the memory card 6 and the conversion adapter 21 is stored. When the connection to .about.24 is switched, the corresponding project file may be read from the memory card 6 for display. Thereby, for example, when the programmable display 30 is connected to the conversion adapters 21 to 24 of the device X constituted by the PLCs 11 to 14 of the manufacturer A, the corresponding project file is read out. Therefore, the operation for changing the project file can be omitted.

  The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope shown in the claims. That is, embodiments obtained by combining technical means appropriately modified within the scope of the claims are also included in the technical scope of the present invention.

  For example, in the above embodiment, the ID registered in the conversion adapter is changed using the DIP switch. However, the conversion adapter uses a memory card (external storage medium) such as a CF card (registered trademark). It has a memory card connection part that can be connected and can read at least data from the memory card, and an internal memory (storage part of the conversion adapter) that stores data read from the memory card, and reads from the memory card to the internal memory The ID may be written, and the written ID may be overwritten (changed) with the read data.

  Also, various data such as various display screens may be written from the memory card to the internal memory. Then, the written various data may be associated with the IP address of the PLC via the ID.

  If it does in this way, the screen suitable for PLC which established the connection can be displayed on a programmable display, for example.

  The control system of the present invention includes a plurality of communication relay devices in which IDs corresponding to IP addresses set in a plurality of programmable logic controllers (PLCs) are set, and a communication relay device to which a portable programmable display is connected Since the communication is established by setting the IP address of the PLC to be connected based on the ID acquired from the portable communication display, the communication with the PLC to be connected to the portable programmable display can be easily established. This can be suitably used to improve the working efficiency when changing the connection of the device to the PLC.

It is a block diagram which shows the structure of the control system which concerns on embodiment of this invention. It is a block diagram which shows the structure of the other control system which concerns on embodiment of this invention. It is a block diagram which shows the structure of the conversion adapter in the said both control systems. It is a block diagram which shows the structure of the programmable display in both the said control systems. It is a flowchart which shows the procedure of the transmission process of ID data by the said conversion adapter. It is a flowchart which shows the procedure of the acquisition process of ID data by the said programmable display, and the setting process of an IP address.

Explanation of symbols

1, 2 Control system 5 Hub 11-12 PLC
21-22 Conversion adapter (communication relay device)
30 Programmable display (portable programmable display)
31a IP address setting unit (transmission request means, communication establishment means)
33 User memory (storage means)
38 Communication driver 202a ID memory (ID storage means)
202b ID management unit (ID transmission means)

Claims (3)

A portable programmable display; a plurality of programmable logic controllers each set with an IP address; and a plurality of communication relay devices that relay communication between each programmable logic controller and the portable programmable display. A control system capable of establishing a connection between any of the programmable logic controllers in the programmable logic controller and the portable programmable display,
Each communication relay device includes an ID storage means for registering an ID set in association with any one of the IP addresses, and the ID storage means in response to a transmission request from the portable programmable display. And ID transmitting means for reading from and transmitting to the portable programmable display,
In the portable programmable display, the storage means for storing each association between the IP address and the ID, and the ID corresponding to the IP address of the programmable logic controller to establish a connection are registered. The transmission request means for making an ID transmission request to the communication relay device, and the IP address corresponding to the transmitted ID is identified from the association as the IP address of the communication partner, and the IP address is set A control system comprising communication establishment means for establishing communication with a programmable logic controller. A communication relay device that relays communication between a programmable logic controller set with an IP address and a portable programmable display,
ID storage means for registering an ID set in association with the IP address;
A communication relay device comprising: an ID transmission unit that reads the ID from the ID storage unit and transmits the ID to the portable programmable display in response to a transmission request from the portable programmable display. A portable programmable display that can be connected to the communication relay device according to claim 2,
Storage means for storing each association between the IP address and the ID;
Transmission request means for requesting transmission of an ID to the communication relay apparatus in which the ID corresponding to the IP address of the programmable logic controller to be connected is registered, and the IP address corresponding to the transmitted ID And a communication establishment means for establishing communication with the programmable logic controller to which the IP address is set by specifying the communication address as an IP address of the communication partner. vessel.

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