The disclosure relates mainly to a programmable logic controller.
EtherCAT is known as an industrial open network. EtherCAT is used as a field network. An IO-Link system constructed with a master that conducts point-to-point communication with a device such as a sensor and an actuator is known.
A network system constructed with a programmable controller including a function as an EtherCAT master, a device including a function as an EtherCAT slave and a function of an IO-Link master, and an IO-Link device has been conventionally used.
A function block (setting value reading FB) that acquires an operation setting value of the IO-Link device from the IO-Link device and a function block (setting value writing FB) that reflects the operation setting value held by the PLC in the IO-Link device are mounted on the PLC.
In order that the setting value writing FB causes the IO-Link device to change operation setting of the IO-Link device, it is necessary for a user to previously record a setting data file for the IO-Link device in the PLC, various operation setting values corresponding to the operation setting being described in the setting data file for the IO-Link device.
A network system including many IO-Link devices that should perform the operation based on the same operation setting is considered as a specific example of the network system.
In such a network system, in order that the many IO-Link devices are caused to perform the operation, it is necessary for the user to previously record the setting data files as many as the number of IO-Link devices in the PLC. This is troublesome for the user (problem 1).
A network system including the IO-Link devices of various vendors is considered as another specific example of the network system.
In such a network system, in the case that the PLC calls the setting value writing FB to reflect the operation setting value related to the IO-Link device of an A company in the IO-Link device of a B company, the IO-Link device of the B company can malfunction (problem 2).
Considering the problem 1, one or more aspects may make a PLC that can select a control object device that changes the operation setting value using a specific setting data file without limiting to a control object device indicated by destination information included in the setting data file. One or more aspects may make a PLC that solves the problem 2 (that is, a PLC in which a possibility of the malfunction of the control object device due to a false setting change is reduced than ever before).
In order to solve the problems, according to a first aspect, a programmable logic controller includes: a function block (FB) executing unit configured to execute an FB including a function of changing an operation setting value of a control object device; and a storage in which a setting data file referred to during operation of the FB is stored. The FB executing unit includes an object specification unit configured to specify a destination of the control object device, and the object specification unit can switch between the specification of the destination of the control object device based on destination information included in the setting data file and the specification of the destination of the control object device based on separately-designated information.
In order to solve the problems, according to a second aspect, a method for controlling a programmable logic controller including: a function block (FB) executing unit configured to execute an FB including a function of changing an operation setting value of a control object device; and a storage in which a setting data file referred to during operation of the FB is stored, the method for controlling the programmable logic controller includes the step of specifying a destination of the control object device using the FB executing unit. The specification of the destination of the control object device based on destination information included in the setting data file and the specification of the destination of the control object device based on separately-designated information can be switched in the object specification step.
In order to solve the problems, according to a third aspect, a programmable logic controller includes: a function block (FB) executing unit configured to execute an FB including a function of changing an operation setting value of a control object device; and a storage in which a setting data file referred to during operation of the FB is stored. The FB executing unit includes a device matching unit configured to match a device ID of the control object device, and the device matching unit acquires the device ID of the control object device, and matches the acquired device ID with device ID information included in the setting data file.
In order to solve the problems, according to a fourth aspect, a method for controlling a programmable logic controller including: a function block (FB) executing unit configured to execute an FB including a function of changing an operation setting value of a control object device; and a storage in which a setting data file referred to during operation of the FB is stored, the method for controlling the programmable logic controller includes the step of matching a device ID of the control object device using the FB executing unit. In the device matching step, the device ID of the control object device is acquired, and the acquired device ID is matched with device ID information included in the setting data file.
In the programmable logic controller of a first aspect, the control object device that changes the operation setting value using a specific setting data file can be selected without limiting to the control object device indicated by the destination information included in the setting data file.
In the programmable logic controller of a third aspect, the possibility of the malfunction of the control object device due to the false setting change is reduced than ever before.
An industrial network system according to a first embodiment will be described below with reference to
An outline and a configuration of the industrial network system of a first embodiment will be described with reference to
As can be seen from
The HMI 10 is a device that is used to change an operation setting of the IO-Link device 400 by an on-site operator. A touch panel type display is provided in the HMI 10.
Many UI components are displayed on the display during the actual operation of the industrial network system 1. The on-site operator touches the proper UI component (specific UI component) selected from many UI components, which allows the on-site operator to cause the desired device 400 (control object device) in plural devices 400 to perform desired operation in predetermined plural kinds of operation.
When receiving a touch operation on the UI component, the HMI 10 issues an instruction to the PLC 200 to perform the control such that the desired device 400 performs desired operation. That is, the HMI 10 transmits instruction data indicating a specific content of the instruction to the PLC 200.
The PC 100 is a personal computer that is used by a system manager in order to produce a setting data file including various operation setting values used to cause the device 400 to perform desired operation and to record a produced setting data file in the PLC 200.
The PLC 200 is an EtherCAT master, and conducts EtherCAT communication with the slave device.
The PLC 200 holds a function block (setting value writing FB) having a function of changing various operation setting values of the device 400 (control object device).
When the PLC 200 calls the setting value writing FB with an instruction (setting change instruction) from the HMI 10 as a trigger, the setting value writing FB performs the following operation. That is, the setting value writing FB refers to a specific setting data file corresponding to the specific UI component in many setting data files held by the PLC 200, and transmits the referred-to setting data file to the control object device.
The slave device (device 300-1, device 300-2) acts as an EtherCAT slave and an IO-Link master. The slave device transfers the setting data file to the IO-Link device 400 when acquiring the setting data file from the PLC 200 in order to change the operation setting value of the IO-Link device 400 point-to-point connected to own device.
The devices 300-1 and 300-2 will more specifically be described below.
The device 300-1 is a device in which plural functional units are connected through a system bus while being able to exchange data with each other. One of the plural functional units controls communication with the EtherCAT master and data exchange with other functional units through the system bus. Another one of the plural functional units is operated as the IO-Link master that is connected to the IO-Link device 400 to conduct communication.
The device 300-2 includes a function of conducting communication with the EtherCAT master and a function of conducting communication with the IO-Link device 400.
When the setting data file is transferred from the IO-Link device 400, the device 400 changes various operation setting values of the own device based on a content of the setting data file, and performs the operation desired by the on-site operator.
The device 500 is a device (control object device such as a sensor and an actuator) that acts as not the IO-Link master but the EtherCAT slave.
The device 600 is a device (the control object device such as a sensor and an actuator) connected to one of functional units of the slave device (the slave device that acts as not the IO-Link master but the EtherCAT slave) including plural functional units.
Configurations of the PC 100 and PLC 200 will be described below with reference to
As illustrated in
The CPU 110 integrally controls a whole of the PC 100.
The storage 120 is a recording medium in which a predetermined tool application is installed. A setting data file produced by the tool application is also stored in the storage 120. Details of the tool application will be described later.
The display 130 is a display screen on which a screen of the tool application is displayed.
The operation unit 140 is an operation device (such as a keyboard) that operates the tool application.
The Ethernet I/F unit 150 is a communication interface that conducts Ethernet communication (TCP/IP communication).
The CPU 110 acts as a setting data generation processor 111 and a transmission processor 112 by reading the tool application.
The setting data generation processor 111 generates a setting data file that is referred to by a setting value writing FB of the PLC 200.
The setting data generation processor 111 includes a display input controller 1111 and an IODD file acquisition processor 1112.
The display input controller 1111 produces the setting data file from an IODD file that is of a file related to at least one item indicating the operation setting value of the device 400, and displays a tool application screen indicating at least one item in the setting data file on the display 130. The display input controller 1111 also control setting of a value of the item by input from a user.
The IODD file acquisition processor 1112 acquires an IODD file from an outside (in a first embodiment, a predetermined server). The IODD file of a first embodiment is a file in which a value settable for the functional item and a default operation setting value of the functional item in each functional item of the device 400 are indicated.
The transmission processor 112 transmits the setting data file generated by the setting data generation processor 111 to the PLC 200.
As illustrated in
The CPU 210 integrally controls a whole of the PLC 200.
The Ethernet I/F unit 220 is a communication interface that conducts Ethernet communication (TCP/IP communication).
The EtherCAT I/F unit 230 is a communication interface that conducts EtherCAT communication.
The storage 240 is a recording medium in which various FBs such as a setting value reading FB and the setting value writing FB are recorded. The setting data file transmitted from the PC 100 is also recorded in the storage 240.
The CPU 210 acts as a setting data acquisition processor 211, a setting change instruction receiver 212, and an FB processor 213.
The setting data acquisition processor 211 acquires the setting data file transmitted from the PC 100 to the PLC 200, and records the acquired setting data file in the storage 240.
The setting change instruction receiver 212 causes the FB processor 213 to call the setting value writing FB with the setting change instruction from the HMI 10 as the trigger.
FB processor 213 (FB executing unit) reads various FBs and executes the read FB.
In the case that the FB processor 213 calls the setting value writing FB by the setting change instruction from the HMI 10, the setting value writing FB reads the specific setting data file corresponding to the content of the setting change instruction from the storage 120, and transmits the read setting data file to an EtherCAT network (the slave device connected to the control object device).
In a first embodiment, the FB processor 213 includes a device matching unit 2131 and a destination specification unit 2132 (object specification unit).
In the case that a predetermined input variable of the setting value writing FB is a predetermined value, the device matching unit 2131 acquires a vendor ID and a device ID from the device 400 designated by the on-site operator. When a vendor ID stored in the setting data file is matched with the vendor ID acquired from the device 400, and when a device ID (device ID information) stored in the setting data file is matched with the device ID acquired from the device 400, the device matching unit 2131 outputs information indicating “successful matching”, and outputs information indicating “failed matching” otherwise.
In a first embodiment, the device matching unit 2131 can change whether the matching processing is performed according to the setting of the industrial network system 1.
The destination specification unit 2132 specifies a destination of the control object device by a method based on the setting change instruction from the HMI 10.
The destination of the control object device is specified based on destination information included in the specific setting data file. In this case, the “specific setting data file” is, for example, a file having a file name indicating a name of the control object device and the content of the post-setting-change operation, and is a setting data file including the destination information and various operation setting values corresponding to the post-setting-change operation.
The destination of the control object device is specified based on separately-designated destination information (destination information included in the instruction data from the HMI 10). In this case, the “specific setting data file” is, for example, a file having a file name indicating the content of the post-setting-change operation, and is a setting data file including the destination information and various operation setting values corresponding to the post-setting-change operation.
The destination specification unit 2132 can appropriately switch the method 1 and the method 2 according to the setting of the industrial network system 1.
The destination information of a first embodiment is at least one of (1) a node address of the EtherCAT network managed by the PLC 200, (2) a unit number of a device (not illustrated, the slave device) including plural units, the device being connected to the PLC 200, and (3) a port number of the slave device including plural ports, the slave device being connected to the PLC 200.
Examples of the destination information include a combination (the destination information about the device 400 connected to the device 300-1) of a node address (node number), a unit number, and a port number, a combination (the destination information about the device 600) of the node address and the unit number, a combination (the destination information about the device 400 connected to the device 300-2) of the node address and the port number, and the node number (the destination information about the device 500).
The configurations of the PC 100 and PLC 200 are described above.
How to produce the setting data file using the tool application installed in the PC 100 will be described in detail with reference to
When the PC 100 starts up the tool application, the tool application (display input controller 1111) detects the PLC 200 and at least one slave device in the industrial network system 1, and displays a screen indicating a network configuration on the display 130 based on a detection result as illustrated in
When a user (system manager) performs operation to select the slave device that acts as the IO-Link master through the screen in
When the user performs operation to select the device 400 (IO-Link device 400) through the screen in
The tool application (display input controller 1111) reads the downloaded IODD file, and displays a screen in
When the user presses an “ALL EXPORT” button or a “Changed part Export” button after changing various operation setting values related to the device 400 through the screen in
Specifically, the setting data generation processor 111 generates the setting data file including information (all the pieces of setting data related to the device 400) about all the items when the “ALL EXPORT” button is pressed, and generates the setting data file including not the operation setting values of the not-changed items but the operation setting values of the changed items when the “Changed part Export” button is pressed.
The tool application (transmission processor 112) transmits the generated setting data file to the PLC 200.
The user can produce N setting data files by performing the above work at least N (N≧1) times with respect to the selected device 400. That is, the user can produce the setting data file including the operation setting value used to cause the selected device 400 to perform the operation with respect to each of N kinds of the operation.
A “Set default value” button on the screen in
A screen in which a third button for export is provided may be displayed on the screen in
Details of the setting data file will be described with reference to
As illustrated in
The setting data includes meta information and actual information, and the meta information about the setting data includes various pieces of information (such as a data length of the actual information) related to the actual information about the setting data.
Details of the instruction data and setting value writing FB will be described with reference to
As can be seen from
The variable NodeAdr is a variable that is referred to by EC_IOLWRITE in order to specify the destination of the control object device (the device 400).
The variable UnitProxy is a variable that is referred to by NX_IOLWRITE in order to specify the destination of the control object device. As illustrated in
In the case that the destination of the control object device is set by the method 1, the HMI 10 transmits the instruction data including a value “0” of the variable NodeAdr to the PLC 200. In the case that the destination of the control object device is set by the method 2, the HMI 10 transmits the instruction data including a value i (i is an integer of 1 to 192) of the variable NodeAdr to the PLC 200.
As can be seen from
As can be seen from
The variable PortNo is a variable that is referred to by EC_IOLWRITE and NX13 IOLWRITE in order to specify the destination of the control object device.
In the case that the destination of the control object device is set by the method 1, the HMI 10 transmits the instruction data including the value “0” of the variable PortNo to the PLC 200. In the case that the destination of the control object device is set by the method 2, the HMI 10 transmits the instruction data including a value j (j is an integer of 1 to 16) of the variable PortNo to the PLC 200.
As can be seen from
The variable IDcheck is a variable that is referred to by EC_IOLWRITE and NX_IOLWRITE in order to determine whether the matching processing is performed. That is, the variable IDcheck is the “predetermined input variable”.
The HMI 10 transmits the instruction data including a value “FALSE” (the “predetermined value”) of the variable IDcheck to the PLC 200 in the case that the performance of the matching processing is set to be valid, and the HMI 10 transmits the instruction data including a value “TRUE” of the variable IDcheck to the PLC 200 in the case that the performance of the matching processing is set to be invalid.
As can be seen from
EC_IOLWRITE(NX_IOLWRITE) performs the matching processing when the determination that the matching processing is performed is made (device matching step).
As a result of the performance of the matching processing in the device matching step, when the vendor ID stored in the setting data file is not matched with the vendor ID acquired from the device 400, or when the device ID stored in the setting data file is not matched with the device ID acquired from the device 400, EC_IOLWRITE(NX_IOLWRITE) outputs the information indicating “failed matching”. That is, EC_IOLWRITE and NX_IOLWRITE output five output variables in
On the other hand, as a result of the performance of the matching processing in the device matching step, when the vendor ID stored in the setting data file is matched with the vendor ID acquired from the device 400, and when the device ID stored in the setting data file is matched with the device ID acquired from the device 400, EC_IOLWRITE(NX_IOLWRITE) outputs the information indicating “successful matching”. EC_IOLWRITE(NX_IOLWRITE) transmits the setting data file to the EtherCAT network (the slave device connected to the control object device) in the case that EC_IOLWRITE(NX_IOLWRITE) outputs the information indicating “successful matching”.
An input variable FileName is a variable indicating a file name of the “predetermined setting data file” (that is, the setting data file to be restore by the control object device), which should be read from the storage 240 by EC_IOLWRITE(NX_IOLWRITE) and transmitted to the control object device.
The details of the instruction data and setting value writing FB are described above.
As a result of the above processing performed by the setting value writing FB, the control object device receives and records the setting data file to be restored, and changes the operation setting value of the own device based on the restored setting data file. That is, the control object device performs the operation desired by the on-site operator.
An industrial network system according to a second embodiment will be described below with reference to
As illustrated in
The PC 100′ differs from the PC 100 in the following point.
In the case that the user performs the operation to select the device 400 on the screen in
The tool application performs the following processing in the case that the fourth button or the fifth button is pressed while the PC 100′ and the control object device are directly connected to each other by a cable.
That is, in the case that the fourth button is pressed, the tool application (change data generator) generates the operation setting value change data including the information about a predetermined part of the items, and transmits (downloads) the generated operation setting value change data to the device 400.
Similarly, in the case that the fifth button is pressed, the tool application (change data generator) generates the operation setting value change data including not the operation setting value of the not-changed items but the operation setting value of the changed items, and transmits (downloads) the generated operation setting value change data to the device 400.
A site where the industrial network system is installed may be divided into plural sections. One device 400 or plural devices 400 of the same kind may be installed in each section.
In this case, the HMI 10 may display the UI component that causes all the devices 400 (control object devices) installed in an object section to perform the desired operation with respect to each of the plural sections. The system manager may set the industrial network system such that the PLC 200 adopts the method 2 in order to specify the destination of the device 400.
When the on-site operator performs the operation to tap a specific UI component, the HMI 10 may generate the instruction data including “the variable NodeAdr indicating the node address of the device 400” with respect to all the devices 400 (Q control object devices) in the section corresponding to the UI component.
When the PLC 200 acquires the instruction data generated by the HMI 10, the destination specification unit 2132 may refer to each (separately-designated information) of the Q variables NodeAdr included in the instruction data, and specify plural (Q) destinations of the control object device based on the separately-designated information.
In the first modification, the system manager may produce the setting data files as many as the number of kinds of the operation that the on-site operator desires using the device 400 installed in the object section in each section.
That is, in the first modification, the system manager needs not to produce the setting data files as many as the number of kinds of the operation that the on-site operator desires using the object device 400 in each device.
Accordingly, in the first modification, the system manager can produce all the necessary setting data files with less labor and time.
In first and second embodiments, when a vendor ID stored in the setting data file is matched with the vendor ID acquired from the device 400, and when a device ID (device ID information) stored in the setting data file is matched with the device ID acquired from the device 400, the device matching unit 2131 outputs the information indicating the “successful matching”, and outputs the information indicating the “failed matching” otherwise. However, the present invention is not limited to the above configuration, but a configuration according to the following modification is also included in the scope of the present invention.
A system according to a second modification differs from the systems of first and second embodiments in the following points.
That is, a serial number unique to the device 400 is described in the setting data file in addition to various pieces of information (such as a device ID unique to a type corresponding to the device 400) described in the setting data files of first and second embodiments.
In the second modification, in the case that the performance of the matching processing is set to be valid, the device matching unit 2131 outputs the information indicating the “successful matching” when the following three conditions are satisfied, and outputs the information indicating the “failed matching” otherwise.
The vendor ID stored in the setting data file is matched with the vendor ID acquired from the device 400.
The device ID stored in the setting data file is matched with the device ID acquired from the device 400.
The serial number stored in the setting data file is matched with the serial number acquired from the device 400.
The PLC including the following device matching unit is also included in the scope of the present invention.
That is, the PLC including the device matching unit that outputs the information indicating “successful matching” when any one (for example, the condition 2 or the condition 3) or two of the conditions 1 to 3 are satisfied and outputs the information indicating the “failed matching” otherwise is also included in the scope of the present invention.
The systems of first and second embodiments include the slave device (such as the device 300-1 and the device 300-2) that acts as the IO-Link master while acting as the EtherCAT slave and the slave device (such as the device 500) that acts as not the IO-Link master but the EtherCAT slave.
However, the present invention is not limited to the systems of first and second embodiments.
That is, all the slave devices (the device acting as the EtherCAT slave) included in the systems may be the device acting as the IO-Link master. Alternatively, all the slave devices included in the systems may be the device that does not act as the IO-Link master. In other words, in one or more embodiments, the IO-Link master and the IO-Link device are not necessarily provided.
The PLCs 200 of first and second embodiments are the programmable logic controller that solves the problems 1 and 2. However, the programmable logic controller of the present invention is not limited to the PLC 200.
For example, the PLC (the PLC including not the device matching unit 2131 but the destination specification unit 2132) that solves not the problem 2 but the problem 1 or the PLC (the PLC including not the destination specification unit 2132 but the device matching unit 2131) that solves not the problem 1 but the problem 2 is also included in the scope of the programmable logic controller of the present invention.
The PCs (PCs 100 and 100′) of first and second embodiments and a control block (particularly, the setting data generation processor 111, the transmission processor 112, and the FB processor 213) of the PLC 200 may be constructed with a logic circuit (hardware) formed in an integrated circuit (IC chip), or implemented by software using a central processing unit (CPU).
In the latter, the PCs and the PLC include the CPU that executes a command of the program that is of the software implementing each function, a read only memory (ROM) or a storage device (referred to as a recording medium) in which the program and various pieces of data are stored while being readable by a computer (or the CPU), and a random access memory (RAM) in which the program is expanded. The computer (or the CPU) reads the program from the recording medium, and executes the program. A “non-transient physical medium” such as a tape, a disk, a card, a semiconductor memory, and a programmable logic circuit can be used as the recording medium. The program may be supplied to the computer through any transmission medium (such as a communication network and a broadcasting wave) in which the program can be transmitted. One or more embodiments can be made in a form of a data signal embedded in a carrier wave, the data signal being materialized by electronic transmission of the program.
According to a first aspect, a programmable logic controller includes: a function block (FB) executing unit configured to an FB including a function of changing an operation setting value of a control object device; and a storage in which a setting data file referred to during operation of the FB is stored. The FB executing unit includes an object specification unit configured to specify a destination of the control object device, and the object specification unit can switch between the specification of the destination of the control object device based on destination information included in the setting data file and the specification of the destination of the control object device based on separately-designated information.
According to the configuration, the specification of the destination of the control object device based on destination information included in the setting data file and the specification of the destination of the control object device based on separately-designated information can be switched when the FB changes the operation setting value of the control object device.
That is, the control object device that changes the operation setting value using a specific setting data file can be selected without limiting to the control object device indicated by the destination information included in the setting data file.
According to a second aspect, a method for controlling a programmable logic controller includes: a function block (FB) executing unit configured to execute an FB including a function of changing an operation setting value of a control object device; and a storage in which a setting data file referred to during operation of the FB is stored, and the method for controlling the programmable logic controller includes the step of specifying a destination of the control object device using the FB executing unit. The specification of the destination of the control object device based on destination information included in the setting data file and the specification of the destination of the control object device based on separately-designated information can be switched in the object specification step.
According to the configuration, the method has the effect similar to that of the programmable logic controller.
In the programmable logic controller, the object specification unit may specify plural destinations of the control object device using the separately-designated information.
According to the configuration, the PLC can specify the plural destinations of the control object device, user's labor and time can largely be reduced in the case that the similar operation setting value is set to the plural control object devices.
In the programmable logic controller, the object specification unit may specify the destination of the control object device using at least one of (1) a node address of a network managed by the programmable logic controller, (2) a unit number of a slave device including plural units, the slave device being connected to the programmable logic controller, and (3) a port number of the slave device including the plural units, the slave device being connected to the programmable logic controller.
According to the configuration, the programmable logic controller can properly specify the destination of the control object device using at least one of the node address, the unit number, and the port number.
According to a third aspect, a programmable logic controller includes: a function block (FB) executing unit configured to execute an FB including a function of changing an operation setting value of a control object device; and a storage in which a setting data file referred to during operation of the FB is stored. The FB executing unit includes a device matching unit configured to match a device ID of the control object device, and the device matching unit acquires the device ID of the control object device, and matches the acquired device ID with device ID information included in the setting data file.
According to the configuration, the programmable logic controller acquires the device ID of the control object device, and matches the acquired device ID with the device ID information included in the setting data file. Therefore, the malfunction caused by improperly setting the operation setting value to the control object device due to an error of the destination information included in the setting data file can be prevented.
According to a fourth aspect, a method for controlling a programmable logic controller includes: a function block (FB) executing unit configured to execute an FB including a function of changing an operation setting value of a control object device; and a storage in which a setting data file referred to during operation of the FB is stored, and the method for controlling the programmable logic controller includes the step of matching a device ID of the control object device using the FB executing unit. In the device matching step, the device ID of the control object device is acquired, and the acquired device ID is matched with device ID information included in the setting data file.
According to the configuration, the method has the effect similar to that of the programmable logic controller.
In the programmable logic controller, the device matching unit may acquire the device ID of the control object device, and switch whether matching processing of matching the acquired device ID with the device ID information included in the setting data file is performed.
In the programmable logic controller, the device matching unit may acquire a serial number unique to the control object device, and switch whether matching processing of matching the acquired serial number with a serial number described in the setting data file is performed.
According to the configuration, whether the matching processing is performed is switched, so that the matching processing can be performed as needed. Therefore, in the case that the matching processing is not required, omission of the matching processing can reduce a processing time, a load on a communication line, and a load on the PLC.
The scope of the present invention includes a control program causing a computer to act as the programmable logic controller according to one or more aspects, and causing the computer to act as the FB executing unit.
The present invention is not limited to the above embodiments, various changes can be made without departing from the scope of the claims, and an embodiment acquired by a combination of technical means disclosed in different embodiments is also included in the technical scope of the present invention. Additionally, a new technical feature can be made by a combination of technical means disclosed in different embodiments.
One or more embodiments can suitably be used in the industrial network system.
100, 100′ PC
110 CPU
111 setting data generation processor
112 transmission processor
1111 display input controller
1112 IODD file acquisition processor
200 programmable logic controller (PLC)
210 CPU
213 FB processor (FB executing unit)
2131 device matching unit
2132 destination specification unit (object specification unit)
240 storage
300-1, 300-2 slave device
400 IO-Link device (control object device)
Number | Date | Country | Kind |
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2015-078088 | Apr 2015 | JP | national |
This application is a continuation application of International Application No. PCT/JP2016/059199, filed on Mar. 23, 2016, which claims priority based on the Article 8 of Patent Cooperation Treaty from prior Japanese Patent Application No. 2015-078088, filed on Apr. 6, 2015, the entire contents of which are incorporated herein by reference.
Number | Date | Country | |
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Parent | PCT/JP2016/059199 | Mar 2016 | US |
Child | 15714495 | US |