JP2017111563A - Information display apparatus, method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an information display apparatus for reducing the workload of a user.SOLUTION: An information display apparatus includes: a system configuration data generation unit for generating system configuration data including a system block diagram of an industrial system; an image data acquisition unit for acquiring image data on one of a plurality of industrial devices, from an imaging apparatus; a device identifying unit for identifying an industrial device captured by the imaging apparatus, on the basis of the image data; a block diagram display unit for displaying a block diagram of the industrial device identified by the device identifying unit, on a display unit, on the basis of the system block diagram; and an operation information display unit for communicating with the industrial device identified by the device identifying unit when a component in the block diagram displayed on the display unit is selected, and acquires operation information of the selected component, to be displayed on the display unit.SELECTED DRAWING: Figure 12

Description

  The present invention relates to an information display device, a method, and a program for displaying operation information representing an operation state of an industrial system.

  In the industrial field exemplified by the production of articles, an industrial system in which a plurality of industrial devices are connected to a network is used.

  In order to grasp the connection relationship between a plurality of industrial devices included in the industrial system, there is a request to create a system configuration diagram representing the connection relationship between the plurality of industrial devices.

  In view of the above request, the following Patent Document 1 discloses a control system engineering apparatus that displays a system configuration of a control system.

International Publication No. 2008/146380

  Furthermore, there is a request to monitor operation information indicating the operation state of a plurality of industrial devices. In response to such a request, each industrial device is provided with a programmable display, and the operation information of each industrial device can be monitored by operating the programmable display.

  However, in order to monitor the operation information of each industrial device with the programmable display provided in each industrial device, the user must go to the installation location of each industrial device. Therefore, the work burden on the user for monitoring the operation information of the industrial apparatus is large. In particular, when the industrial device to be monitored is arranged on the second floor of the factory building, the user must ascend to the second floor, and the work burden on the user is large.

  In addition, when the user intends to monitor the operating state of another industrial device with a programmable display provided in one industrial device, a drawing depicting the arrangement of a plurality of industrial devices in a factory building If there is, the user reads the information specifying the industrial device to be monitored from the drawing and inputs the information to the programmable display, thereby monitoring the operating state of the industrial device to be monitored by the programmable display. It is also possible to do. However, even if the drawing is present at the work site in the factory building, the user must read information identifying the device to be monitored from the drawing and input it to the programmable display. The work burden is large. Also, if the above drawing is not present at the work site in the factory building, the user cannot input information specifying the industrial device to be monitored to the programmable display, so the operating state of the industrial device to be monitored is described above. It cannot be monitored with a programmable display.

  The present invention has been made in view of the above, and an object of the present invention is to obtain an information display device that can reduce a user's workload.

  In order to solve the above-described problems and achieve the object, the present invention is an information display device that displays operation information indicating an operation state of an industrial system including a plurality of industrial devices connected to a network, and includes images or characters. A display unit for displaying the image, a system configuration data generation unit for generating system configuration data including a system configuration diagram of the industrial system, and image data for acquiring image data obtained by imaging one of a plurality of industrial devices from the imaging device An acquisition unit, a device identification unit that identifies an industrial device imaged by the imaging device based on the image data, and a configuration diagram of the industrial device identified by the device identification unit based on the system configuration diagram are displayed on the display unit When the component in the configuration diagram display unit and the component in the configuration diagram displayed on the display unit are selected, the selected component is displayed by communicating with the industrial device specified in the device specifying unit. And operation information display section for displaying on the display unit acquires the operation information, characterized in that it comprises a.

  The information display device according to the present invention has an effect of reducing the work burden on the user.

The figure which shows the structure of the industrial system concerning Embodiment 1. FIG. The figure which shows the external appearance of the 1st industrial apparatus concerning Embodiment 1. The figure which shows the external appearance of the 2nd industrial apparatus concerning Embodiment 1. The figure which shows the external appearance of the 3rd industrial apparatus concerning Embodiment 1. FIG. The figure which shows the hardware constitutions of the engineering tool concerning Embodiment 1. The figure which shows the functional block of the engineering tool concerning Embodiment 1. The figure which shows the 1st project data concerning Embodiment 1. The figure which shows the 2nd project data concerning Embodiment 1. The figure which shows the 3rd project data concerning Embodiment 1. The figure which shows the hardware constitutions of the 1st control apparatus concerning Embodiment 1. FIG. The figure which shows the hardware constitutions of the 1st programmable display concerning Embodiment 1. FIG. The figure which shows the functional block of the 1st programmable display concerning Embodiment 1. FIG. The figure which shows the system block diagram concerning Embodiment 1. FIG. A flowchart showing system configuration data creation processing of the first programmable display according to the first embodiment. 1 is a flowchart showing information display processing of a first programmable display according to a first embodiment; The figure which shows the display screen of the 1st programmable display concerning Embodiment 1. FIG. The figure which shows the display screen of the 1st programmable display concerning Embodiment 1. FIG. The figure which shows the display screen of the 1st programmable display concerning Embodiment 1. FIG.

  Hereinafter, an information display device, method, and program according to embodiments of the present invention will be described in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
FIG. 1 is a diagram illustrating a configuration of an industrial system according to the first embodiment. The industrial system 1 executes a plurality of production processes. The industrial system 1 includes an engineering tool 2, a first industrial device 3, a second industrial device 4, and a third industrial device 5. The 1st industrial apparatus 3, the 2nd industrial apparatus 4, and the 3rd industrial apparatus 5 share and perform several production processes, respectively.

  The first industrial device 3 includes an inverter 31 that supplies AC power to a load, and a first control device 32 that controls the inverter 31. Examples of the first control device 32 include programmable controllers (JIS B 3502: 2011, programmable controllers (PLC)). The inverter 31 is a controlled device controlled by the first control device 32.

  The first industrial device 3 includes a first programmable display (JIS B 3551: 2012, programmable display) 33 for a user to monitor data of the inverter 31 and the first control device 32.

  An imaging device 34 that captures an image is connected to the first programmable display 33. The imaging device 34 is exemplified by a digital still camera or a digital video camera. The imaging device 34 is connected to the first programmable display 33 via the cable C. The cable C is exemplified by a USB (Universal Serial Bus) cable. The imaging device 34 may be always connected to the first programmable display 33, or may be connected to the first programmable display 33 by the user only when used by the user.

  The second industrial device 4 includes a servo amplifier 41 that drives the motor, a second control device 42 that controls the servo amplifier 41, and a second programmable device that allows the user to monitor data of the servo amplifier 41 and the second control device 42. Display 43. The second controller 42 is exemplified by a motion controller. The servo amplifier 41 is a controlled device controlled by the second control device 42.

  The third industrial device 5 includes a robot 51 for manipulating an object, a third control device 52 for controlling the robot 51, and a third programmable display 53 for a user to monitor data of the robot 51 and the third control device 52. And including. The third controller 52 is exemplified by a programmable controller. The robot 51 is a controlled device controlled by the third control device 52.

  The engineering tool 2, the first control device 32, the second control device 42, and the third control device 52 are communicably connected via a ring-type network N. The network N is not limited to the ring connection, and may be a line connection or a star connection. The network N is exemplified by Ethernet (registered trademark).

  The engineering tool 2 creates a plurality of project data including control programs executed by the first control device 32, the second control device 42, and the third control device 52, respectively. A plurality of project data created by the engineering tool 2 is transferred to the first control device 32, the second control device 42, and the third control device 52 via the network N, respectively.

  FIG. 2 is a diagram illustrating an appearance of the first industrial device according to the first embodiment. FIG. 3 is a diagram illustrating an appearance of the second industrial device according to the first embodiment. FIG. 4 is a diagram illustrating an appearance of the third industrial device according to the first embodiment.

  The inverter 31, the first control device 32, and the first programmable display 33 included in the first industrial device 3 are housed in a housing 35. The housing 35 includes a main body 35a and a door 35b that opens and closes the opening of the main body 35a. The door portion 35b is coupled to the main body portion 35a by a support portion 35c, and rotates around the support portion 35c to open and close the opening of the main body portion 35a.

  The user can visually check the inverter 31, the first control device 32, and the first programmable display 33 accommodated in the main body 35a by opening the door 35b. Moreover, the user can monitor the operating state of the inverter 31 and the 1st control apparatus 32 by operating the 1st programmable display 33, after opening the door part 35b.

  An identifier 35b1 that can uniquely identify the first industrial device 3 is attached to the upper right portion of the main surface on the front side of the door portion 35b. In the first embodiment, the identifier 35b1 is a circular figure, but is not limited to this. Other examples of the identifier 35b1 include an IP (Internet Protocol) address, a MAC (Media Access Control) address, a barcode, or a two-dimensional barcode. The two-dimensional barcode is exemplified by a QR code (registered trademark).

  The identifier 35b1 may be stamped on the door portion 35b. The identifier 35b1 may be painted on the door portion 35b. If the identifier 35b1 is painted on the door 35b, the identifier 35b1 can be easily rewritten. Further, the medium on which the identifier 35b1 is printed may be attached to the door portion 35b. The medium is exemplified by paper or film. If the medium on which the identifier 35b1 is printed is pasted on the door portion 35b, the identifier 35b1 can be easily pasted.

  Moreover, it replaces with attaching identifier 35b1 to the door part 35b, and the shape of the housing | casing 35 may be a shape which can identify the 1st industrial apparatus 3 uniquely.

  The servo amplifier 41, the second control device 42, and the second programmable display 43 included in the second industrial device 4 are housed in a housing 44. An identifier 44b1 that can uniquely identify the second industrial device 4 is attached to the upper right portion of the main surface on the front side of the door 44b of the housing 44. In the first embodiment, the identifier 44b1 is a triangular figure, but is not limited to this.

  Moreover, it replaces with attaching the identifier 44b1 to the door part 44b, and the shape of the housing | casing 44 may be a shape which can identify the 2nd industrial apparatus 4 uniquely. In this manner, the distance between the location where the imaging device 34 is located, that is, the location where the first industrial device 3 is installed and the location where the second industrial device 4 is installed is greater than the distance that the imaging device 34 can clearly capture the identifier 44b1. Even when it is long, the imaging device 34 can clearly capture the shape of the housing 44. Thereby, the 1st programmable display 33 can identify the 2nd industrial apparatus 4 uniquely based on the image of the shape of the housing | casing 44 imaged by the imaging device 34. FIG.

  The third control device 52 and the third programmable display 53 included in the third industrial device 5 are housed in a housing 54. An identifier 54b1 that can uniquely identify the third industrial device 5 is attached to the upper right portion of the main surface on the front side of the door portion 54b of the housing 54. In Embodiment 1, the identifier 54b1 is a star-shaped figure, but is not limited to this.

  Moreover, it replaces with attaching the identifier 54b1 to the door part 54b, and the shape of the housing | casing 54 may be a shape which can identify the 3rd industrial apparatus 5 uniquely. In this way, the distance between the location where the imaging device 34 is located, that is, the location where the first industrial device 3 is installed and the location where the third industrial device 5 is installed is greater than the distance that the imaging device 34 can clearly capture the identifier 54b1. Even when it is long, the imaging device 34 can clearly capture the shape of the housing 54. Thereby, the 1st programmable display 33 can identify the 3rd industrial apparatus 5 uniquely based on the image of the shape of the housing | casing 54 imaged by the imaging device 34. FIG.

  FIG. 5 is a diagram illustrating a hardware configuration of the engineering tool according to the first embodiment. The engineering tool 2 according to the first embodiment can be realized using a computer. The computer includes a central processing unit (CPU) 21, a random access memory (RAM) 22, a read only memory (ROM) 23, a storage unit 24, an input unit 25, a display unit 26, a network interface 27, including. The CPU 21, RAM 22, ROM 23, storage unit 24, input unit 25, display unit 26, and network interface 27 are connected via a bus B.

  The CPU 21 executes programs stored in the ROM 23 and the storage unit 24 while using the RAM 22 as a work area. The program stored in the ROM 23 is exemplified by BIOS (Basic Input / Output System) or UEFI (Unified Extensible Firmware Interface). Examples of the program stored in the storage unit 24 include an operating system program and an engineering tool program. The storage unit 24 is exemplified by a solid state drive (SSD) or a hard disk drive (HDD).

  The input unit 25 receives an operation input from the user. The input unit 25 is exemplified by a keyboard or a mouse. The display unit 26 displays characters or images. The display unit 26 is exemplified by a liquid crystal display device. The network interface 27 communicates with the first control device 32, the second control device 42, and the third control device 52.

  FIG. 6 is a diagram illustrating functional blocks of the engineering tool according to the first embodiment. The CPU 21 executes the engineering tool program stored in the storage unit 24. Thereby, the engineering tool part 21a is implement | achieved.

  The engineering tool unit 21a creates first project data 24a, second project data 24b, and third project data 24c based on input from the user. The engineering tool unit 21a transfers the first project data 24a, the second project data 24b, and the third project data 24c to the first control device 32, the second control device 42, and the third control device 52, respectively.

  FIG. 7 is a diagram of first project data according to the first embodiment. FIG. 8 is a diagram of second project data according to the first embodiment. FIG. 9 is a diagram of third project data according to the first embodiment.

  The first project data 24a defines a control program 24a1 executed by the first control device 32, a control parameter 24a2 referred to when the control program 24a1 is executed, and a plurality of work areas in the memory of the first control device 32. Device memory 24a3 which is data for which description is made, and connection information 24a4 which defines the connection relationship between the first control device 32 and the inverter 31.

  Each of the plurality of work areas defined in the device memory 24a3 is called a device. These plurality of devices are to be monitored by the first programmable display device 33.

  The first project data 24a includes identification information 24a5 that can uniquely identify the first industrial device 3. In the first embodiment, the identifier 35b1 that can uniquely identify the first industrial device 3 is a circular figure. Accordingly, the identification information 24a5 is image data of a circular figure. The identification information 24a5 is not limited to image data. Another example of the identification information 24a5 is data obtained by converting image data of a circular figure into text data.

  The second project data 24b defines a control program 24b1 executed by the second control device 42, a control parameter 24b2 referred to when the control program 24b1 is executed, and a plurality of work areas in the memory of the second control device 42. Device memory 24b3, which is data described in the above, and connection information 24b4 that defines the connection relationship between the second control device 42 and the servo amplifier 41.

  The second project data 24b includes identification information 24b5 that can uniquely identify the second industrial device 4. In the first embodiment, the identifier 44b1 that can uniquely identify the second industrial device 4 is a triangular figure. Therefore, the identification information 24b5 is image data of a triangular figure.

  The third project data 24c defines a control program 24c1 executed by the third control device 52, a control parameter 24c2 referred to when the control program 24c1 is executed, and a plurality of work areas in the memory of the third control device 52. Device memory 24c3, which is data for which description is made, and connection information 24c4 that defines the connection relationship between the third control device 52 and the robot 51.

  The third project data 24c includes identification information 24c5 that can uniquely identify the third industrial device 5. In the first embodiment, the identifier 54b1 that can uniquely identify the third industrial device 5 is a star-shaped figure. Therefore, the identification information 24c5 is image data of a star-shaped figure.

  FIG. 10 is a diagram of a hardware configuration of the first control device according to the first embodiment. The first control device 32 includes a main board 32a and a sub board 32b.

  The main board 32a includes a CPU 32a1, a memory 32a2 that is a RAM, a communication interface 32a3, a network interface 32a4, a bus interface 32a5, and a storage unit 32a6. The CPU 32a1, the memory 32a2, the communication interface 32a3, the network interface 32a4, the bus interface 32a5, and the storage unit 32a6 are connected via the internal bus B1.

  The communication interface 32a3 communicates with the first programmable display 33. The communication interface 32a3 is exemplified by RS-422.

  The network interface 32a4 communicates with the engineering tool 2.

  The bus interface 32a5 is a bus bridge circuit that connects the internal bus B1 and the expansion bus B2. The sub board 32b is connected to the main board 32a via the expansion bus B2. The sub board 32 b is connected to the inverter 31.

  The storage unit 32a6 stores the project data 24a received from the engineering tool 2. The storage unit 32a6 is exemplified by SSD or HDD.

  Note that the hardware configurations of the second control device 42 and the third control device 52 are the same as the hardware configuration of the first control device 32, and thus description and illustration thereof are omitted.

  FIG. 11 is a diagram of a hardware configuration of the first programmable display according to the first embodiment. The first programmable display 33 includes a CPU 33a, a RAM 33b, a storage unit 33c, a display unit 33d, an input unit 33e, a communication interface 33f, and a USB interface 33g.

  The CPU 33a executes the information display program stored in the storage unit 33c while using the RAM 33b as a work area.

  The display unit 33d displays characters and images. The display unit 33d is exemplified by a liquid crystal display device. The input unit 33e receives input from the worker. The input unit 33e is exemplified by a touch panel. The liquid crystal display device and the touch panel may be configured integrally, or the touch panel may be attached to the front surface of the liquid crystal display device.

  The communication interface 33f communicates with the first control device 32. The USB interface 33g acquires image data from the imaging device 34.

  FIG. 12 is a functional block diagram of the first programmable display device according to the first embodiment. The CPU 33a executes an information display program stored in the storage unit 33c. Thereby, the information display unit 33a1 is realized.

  The information display unit 33a1 is a system configuration diagram 33c1a of the industrial system 1, first project data 24a including identification information 24a5 that identifies the first industrial device 3, and a second project that includes identification information 24b5 that identifies the second industrial device 4. It includes a system configuration data creation unit 33a1a that creates system configuration data 33c1 including third project data 24c including data 24b and identification information 24c5 that identifies the third industrial device 5.

  FIG. 13 is a diagram illustrating a system configuration diagram according to the first embodiment. The system configuration diagram 33c1a includes an image 33c1a1 corresponding to the first control device 32, an image 33c1a2 corresponding to the inverter 31, an image 33c1a3 corresponding to the second control device 42, an image 33c1a4 corresponding to the servo amplifier 41, and a third control device 52. And an image 33c1a6 corresponding to the robot 51.

  The system configuration data creation unit 33a1a communicates with the first control device 32, the second control device 42, and the third control device 52, and creates the system configuration diagram 33c1a by using the existing system configuration diagram creation technology. Can do. As an existing system configuration drawing creation technique, the technique described in Patent Document 1 is exemplified.

  Referring to FIG. 12 again, the information display unit 33a1 acquires image data obtained by imaging one of the first industrial device 3, the second industrial device 4, and the third industrial device 5 from the imaging device 34. Part 33a1b.

  The information display unit 33a1 includes a device specifying unit 33a1c that specifies an industrial device imaged by the imaging device 34.

  The information display unit 33a1 includes a configuration diagram display unit 33a1d that displays the configuration diagram of the industrial device specified by the device specification unit 33a1c on the display unit 33d based on the system configuration diagram 33c1a.

  When a component in the configuration diagram displayed on the display unit 33d is selected, the information display unit 33a1 communicates with the industrial device specified by the device specifying unit 33a1c, thereby obtaining the operation information of the selected component. An operation information display unit 33a1e that is acquired and displayed on the display unit 33d is included.

  When the operation information display unit 33a1e communicates with the first industrial device 3, the second industrial device 4, or the third industrial device 5 to acquire the operation information, the operation information display unit 33a1e creates the operation information 33c2. The operation information 33c2 includes first operation information 33c2a, second operation information 33c2b, and third operation information 33c2c. When the operation information display unit 33a1e communicates with the first industrial device 3 and acquires the operation information, the operation information display unit 33a1e creates the first operation information 33c2a. When the operation information display unit 33a1e communicates with the second industrial device 4 and acquires the operation information, the operation information display unit 33a1e creates the second operation information 33c2b. When the operation information display unit 33a1e communicates with the third industrial device 5 and acquires the operation information, the operation information display unit 33a1e creates the third operation information 33c2c.

  As described above, the user can monitor the operating state of the first control device 32 and the inverter 31 by opening the door 35b of the housing 35 and operating the first programmable display 33.

  Similarly, the user can monitor the operating states of the second control device 42 and the servo amplifier 41 by opening the door 44b of the housing 44 and operating the second programmable display 43. However, in order to operate the second programmable display 43, the user has to go to the installation location of the housing 44.

  Similarly, the user can monitor the operating states of the third control device 52 and the robot 51 by opening the door portion 54b of the housing 54 and operating the third programmable display 53. However, in order to operate the third programmable display 53, the user has to go to the installation location of the housing 54.

  Therefore, the work burden on the user for monitoring the operating states of the second control device 42, the servo amplifier 41, the third control device 52, and the robot 51 is large. In particular, when the housing 35 is disposed on the first floor of the factory building and the housing 44 and the housing 54 are disposed on the second floor of the factory building, the user can use the second control device 42, the servo amplifier 41. In order to monitor the operating states of the third control device 52 and the robot 51, the user has to climb up to the second floor, which is a heavy work burden on the user.

  If the user wants to monitor the operating state of the second control device 42, the servo amplifier 41, the third control device 52, or the robot 51 with the first programmable display 33, the industrial system 1 as a whole in the factory building If there is a drawing in which the arrangement of the second control device 42 and the servo amplifier is read, the user reads information identifying the device to be monitored from the drawing and inputs the information to the first programmable display 33. 41, it is also possible to monitor the operating state of the third control device 52 or the robot 51 with the first programmable display 33. However, even if the drawing is present at the work site in the factory building, the user must read information specifying the device to be monitored from the drawing and input it to the first programmable display 33. The work burden on the user is large. Further, if the above drawing is not present at the work site in the factory building, the user cannot input information specifying the device to be monitored to the first programmable display 33, so that the second control device 42, the servo amplifier 41, The operating state of the third control device 52 or the robot 51 cannot be monitored by the first programmable display 33.

  In view of the circumstances as described above, the industrial system 1 according to the first embodiment has the second control device 42, the servo amplifier 41, and the third control device 52 without going to the installation location of the housing 44 or the housing 54. In addition, it is possible to monitor the operating state of the robot 51 and reduce the work load on the user.

  FIG. 14 is a flowchart of the system configuration data creation process of the first programmable display according to the first embodiment.

  The first programmable display 33 executes a system configuration data creation process shown in FIG. 14 when an instruction to create the system configuration data 33c1 is input by the user or when a preset timing is reached. Examples of the preset timing include daily start time, daily end time, or every hour.

  In step S100, the system configuration data creation unit 33a1a communicates with the first control device 32, the second control device 42, and the third control device 52, so that the system configuration diagram 33c1a, the first project data 24a, and the second project data System configuration data 33c1 including 24b and third project data 24c is created.

  The system configuration data creation unit 33a1a can create the system configuration diagram 33c1a by using an existing system configuration diagram creation technique. As an existing system configuration drawing creation technique, the technique described in Patent Document 1 is exemplified.

  Specifically, when the technology described in Patent Document 1 is used, the system configuration data creation unit 33a1a is connected to the first programmable display 33, and the system configuration data creation unit 33a1 is the second control unit 32a1. It is assumed that the control device is a starting point for communicating with the control device 42 and the third control device 52. Next, the system configuration data creation unit 33a1a makes the first control device 32, the second control device 42, and the third control device 52 the first industrial device 3, the second control device 32, the first control device 32 as a starting point of communication. It requests the transmission of network configuration information including the configurations of the industrial device 4 and the third industrial device 5 and the network N. When the first control device 32, the second control device 42, and the third control device 52 receive a request for transmission of network configuration information from the system configuration data creation unit 33a1, the first control device 32, the second control device 42, and the third control device 52 transmit the network configuration information to the system configuration data creation unit 33a1. . Next, the system configuration data creation unit 33a1a uses the components of the industrial system 1 as objects, and the configurations of the first industrial device 3, the second industrial device 4, and the third industrial device 5, and each industrial device and the network N. By calculating the coordinates necessary for displaying the connection relationship using the object, the system configuration diagram 33c1a of the entire industrial system 1 including the first industrial device 3, the second industrial device 4, and the third industrial device 5 is obtained. Can be created.

  Further, the system configuration data creation unit 33a1a requests the first control device 32 to transmit the first project data 24a. When receiving a request for transmission of the first project data 24a from the system configuration data creation unit 33a1a, the first control device 32 transmits the first project data 24a to the system configuration data creation unit 33a1a. Accordingly, the system configuration data creation unit 33a1a can acquire the first project data 24a from the first control device 32.

  In addition, the system configuration data creation unit 33a1a requests the second control device 42 to transmit the second project data 24b using the first control device 32 as a communication starting point. When receiving a request for transmission of the second project data 24b from the system configuration data creation unit 33a1a, the second control device 42 transmits the second project data 24b to the system configuration data creation unit 33a1a. Thereby, the system configuration data creation unit 33a1a can obtain the second project data 24b from the second control device 42.

  In addition, the system configuration data creation unit 33a1a requests the third control device 52 to transmit the third project data 24c using the first control device 32 as a communication starting point. Upon receiving a request for transmission of the third project data 24c from the system configuration data creation unit 33a1a, the third control device 52 transmits the third project data 24c to the system configuration data creation unit 33a1a. As a result, the system configuration data creation unit 33a1a can acquire the third project data 24c from the third control device 52.

  In the first embodiment, the system configuration data creation unit 33a1a includes the first project data 24a, the second project data 24b, and the third project data 24c in the system configuration data 33c1, but the identification information 24a5, 24b5 And 24c5 may be included in the system configuration data 33c1.

  FIG. 15 is a flowchart of information display processing of the first programmable display according to the first embodiment.

  When an instruction to monitor one of the first industrial device 3, the second industrial device 4, and the third industrial device 5 is input by the user, the first programmable display 33 displays the information display process shown in FIG. Execute.

  In step S102, the image data acquisition unit 33a1b stores the image data of the housing 35, the housing 44, or the housing 54 that houses one of the first industrial device 3, the second industrial device 4, and the third industrial device 5. Is acquired from the imaging device 34. In the first embodiment, it is assumed that the user images the housing 54 that houses the third industrial device 5 with the imaging device 34. When the user points the imaging device 34 toward the housing 54 and presses the shutter, the imaging device 34 transmits the image data of the housing 54 to the image data acquisition unit 33a1b. Thereby, the image data acquisition unit 33a1b can acquire the image data of the housing 54.

  When the location of the imaging device 34, that is, the installation location of the first industrial device and the installation location of the third industrial device 5 is long, the imaging device 34 clearly identifies the identifier 54b1 attached to the housing 54. It is conceivable that the image cannot be captured. In this case, as described above, instead of attaching the identifier 54b1 to the housing 54, the shape of the housing 54 may be a shape that can uniquely identify the third industrial device 5. In this way, the distance between the location where the imaging device 34 is located, that is, the location where the first industrial device 3 is installed and the location where the third industrial device 5 is installed is greater than the distance that the imaging device 34 can clearly capture the identifier 54b1. Even when it is long, the imaging device 34 can clearly capture the shape of the housing 54. Thereby, the 1st programmable display 33 can identify the 3rd industrial apparatus 5 uniquely based on the image of the shape of the housing | casing 54 imaged by the imaging device 34. FIG.

  FIG. 16 is a diagram illustrating a display screen of the first programmable display according to the first embodiment. The display unit 33d of the first programmable display 33 has an image display area 33d1. The image display area 33d1 is a window, and the user can enlarge, reduce, and move the image display area 33d1.

  The image display area 33d1 is a normal operation of the first programmable display 33 when an instruction to monitor one of the first industrial device 3, the second industrial device 4, and the third industrial device 5 is input by the user. It is displayed overlapping on the near side of the normal screen that is sometimes displayed. Alternatively, instead of the image display area 33d1 being displayed overlapping the front side of the normal screen, the operating state of one of the first industrial device 3, the second industrial device 4, and the third industrial device 5 is changed. A monitoring-dedicated screen for monitoring the operating state to be monitored may be displayed.

  The image data acquisition unit 33a1b displays an image based on the image data acquired from the imaging device 34 in the image display area 33d1. The image data acquired from the imaging device 34 is exemplified by JPEG (Joint Photographic Expert Group) data or bitmap data. In the first embodiment, the image data acquisition unit 33a1b displays the image 33d1a of the housing 54 in the image display area 33d1 by writing data obtained by decoding JPEG data or bitmap data into the video RAM of the display unit 33d. . The image 33d1a has an image 31d1b corresponding to the identifier 54b1.

  A button 33d2 for setting whether or not to display operation information is displayed on the right side of the image display area 33d1 in the drawing. The button 33d2 is toggled on or off when touched.

  The button 33d2 displays the image display area 33d1 and is overlapped with the front side of the normal screen. Alternatively, the button 33d2 may be displayed overlapping the front side of the normal screen when an instruction to display the button 33d2 is input by the user. Alternatively, the operating state of one of the first industrial device 3, the second industrial device 4, and the third industrial device 5 is monitored instead of the button 33d2 being displayed overlapping the near side of the normal screen. A dedicated monitor screen for monitoring the operating state may be displayed.

  The user can easily set whether or not to display the operation information by operating the button 33d2.

  Further, it is preferable that the button 33d2 is set to ON at the initial time. As a result, the user can display the operation information of the third control device 5 only by turning the imaging device 34 toward the housing 54 without setting the button 33d2 on.

  Referring to FIG. 15 again, in step S104, the device specifying unit 33a1c collates the image 33d1a of the housing 54 with the identification information 24a5, 24b5, and 24c5 stored in the storage unit 33c, so that the imaging device The industrial apparatus accommodated in the housing | casing 35,44, or 54 imaged by 34 is specified. Specifically, the device specifying unit 33a1c collates the image 31d1b of the identifier 54b1 with the identification information 24c5, and the image 31d1b and the identification information 24c5 match, so that the device is stored in the housing 54 imaged by the imaging device 34. The third industrial device 5 is identified.

  If the shape of the housing 54 is a shape that can uniquely identify the third industrial device 5 instead of attaching the identifier 54b1 to the door portion 54b, the device specifying unit 33a1c When the shape of the housing 54 matches the identification information 24c5, and the shape of the housing 54 matches the identification information 24c5, the third industrial device 5 housed in the housing 54 imaged by the imaging device 34 can be specified.

  In step S106, the configuration diagram display unit 33a1d determines whether or not the button 33d2 is set to ON. If the configuration diagram display unit 33a1d determines that the button 33d2 is set to ON (Yes), the process proceeds to step S108. If the configuration diagram display unit 33a1d determines that the button 33d2 is set to OFF (No), the process ends.

  In step S108, the configuration diagram display unit 33a1d displays the configuration diagram of the third industrial device 5 identified by the device identification unit 33a1c on the display unit 33d based on the system configuration diagram 33c1a. The configuration diagram of the third industrial device 5 is a part of the system configuration diagram 33c1a, and includes an image 33d1c1 corresponding to the third control device 52 and an image 33d1c2 corresponding to the robot 51. The configuration diagram display unit 33a1d writes the image data including the image 33d1c1 corresponding to the third control device 52 and the image 33d1c2 corresponding to the robot 51 to the video RAM of the display unit 33d, so that the third industrial device 5 The configuration diagram is displayed on the display unit 33d.

  FIG. 17 is a diagram illustrating a display screen of the first programmable display according to the first embodiment. The configuration diagram display unit 33a1d writes the image data of the configuration diagram 33d1c of the third industrial device 5 in the video RAM of the display unit 33d, and thereby displays the configuration diagram 33d1c of the third industrial device 5 on the right side in the drawing of the image 33d1a. indicate. The configuration diagram display unit 33a1d may display part or all of the configuration diagram 33d1c so as to overlap the image 33d1a.

  The user selects the image 33d1c1 corresponding to the third control device 52 and the image 33d1c2 corresponding to the robot 51 by touching the image of the device to be monitored.

  Referring to FIG. 15 again, the operation information display unit 33a1e determines whether or not a component in the configuration diagram 33d1c is selected in step S110. If the operation information display unit 33a1e determines that the component is not selected (No), the operation information display unit 33a1e stands by in Step S110. If the operation information display unit 33a1e determines that the component is selected (Yes), the operation proceeds to Step S112. In the first embodiment, the user selects the image 33d1c1 corresponding to the third control device 52 by touching it.

  In step S112, the operation information display unit 33a1e acquires and displays the operation information of the third control device 52 that is the selected component by communicating with the third industrial device 5 specified by the device specifying unit 33a1c. This is displayed on the part 33d. Specifically, the operation information display unit 33a1e requests the third industrial device 5 to transmit operation information. When the third industrial device 5 receives a request for transmission of operation information from the operation information display unit 33a1e, the third industrial device 5 transmits the operation information to the operation information display unit 33a1e. When the operation information display unit 33a1e acquires the operation information by communicating with the third industrial device 5, the operation information display unit 33a1e creates the third operation information 33c2c in the storage unit 33c.

  FIG. 18 is a diagram illustrating a display screen of the first programmable display according to the first embodiment. The operation information display unit 33a1e displays the operation information 33d1d on the right side of the configuration diagram 33d1c by writing image data for displaying the third operation information 33c2c in the video RAM of the display unit 33d. The operation information display unit 33a1e may display part or all of the operation information 33d1d so as to overlap the configuration diagram 33d1c.

  The operation information 33d1d is exemplified by production quantity or wear information. When the third control device 52 includes a nonvolatile semiconductor memory device exemplified by an SSD or an SD card (registered trademark), the nonvolatile semiconductor memory device has an upper limit on the number of data writes. That is, the nonvolatile semiconductor memory device has a lifetime with respect to the number of data writing times. Therefore, the wear information is exemplified by the number of data writes or the total data write amount of the nonvolatile semiconductor memory device.

  As described above, the operation information display unit 33a1e can display the operation information 33d1d of the third control device 52, which is the selected component, on the display unit 33d. Thus, if the user images the housing 54 using the imaging device 34 at the installation location of the first industrial device 3, the user does not go to the installation location of the third industrial device 5. The operation information 33d1d can be monitored. Therefore, the information display unit 33a1 can reduce the work burden on the user.

  The device specifying unit 33a1c is stored in the casing 35, 44, or 54 imaged by the imaging device 34 by comparing the image data acquired from the imaging device 34 with the identification information 24a5, 24b5, and 24c5. Industrial equipment can be specified. Accordingly, the user can specify the industrial device to be monitored by simply imaging the industrial device to be monitored with the imaging device 34 without inputting information specifying the industrial device to be monitored. That is, even if there is a drawing in which the layout of the entire industrial system 1 in the factory building is drawn, the user does not read the drawing and input it to the first programmable display 33, but the industry to be monitored. The industrial device to be monitored can be identified simply by imaging the device with the imaging device 34. Therefore, the information display unit 33a1 can reduce the work burden on the user. Further, even if the user does not have the drawing, the user can specify the industrial device to be monitored by imaging the industrial device to be monitored with the imaging device 34. Therefore, the information display unit 33a1 can enable the first programmable display 33 to monitor the operation information of the third industrial device 5.

  The configuration described in the above embodiment shows an example of the contents of the present invention, and can be combined with another known technique, and can be combined with other configurations without departing from the gist of the present invention. It is also possible to omit or change the part.

  DESCRIPTION OF SYMBOLS 1 Industrial system, 2 Engineering tool, 3 1st industrial apparatus, 4 2nd industrial apparatus, 5 3rd industrial apparatus, 24a 1st project data, 24a5 identification information, 24b 2nd project data, 24b5 identification information, 24c 3rd project Data, 24c5 identification information, 31 inverter, 32 first control device, 33 first programmable display, 33c1 system configuration data, 33c1a system configuration diagram, 33d1c configuration diagram, 33d1d operation information, 34 imaging device, 35, 44, 54 housing Body, 35b1, 44b1, 54b1 identifier, 41 servo amplifier, 42 second controller, 43 second programmable indicator, 51 robot, 52 third controller, 53 third programmable indicator.

Claims (6)

An information display device that displays operation information indicating an operation state of an industrial system including a plurality of industrial devices connected to a network,
A display unit for displaying images or characters;
A system configuration data creation unit for creating system configuration data including a system configuration diagram of the industrial system;
An image data acquisition unit for acquiring image data obtained by imaging one of the plurality of industrial devices from the imaging device;
A device specifying unit for specifying the industrial device imaged by the imaging device based on the image data;
Based on the system configuration diagram, a configuration diagram display unit that displays a configuration diagram of the industrial device identified by the device identification unit on the display unit;
When the component in the configuration diagram displayed on the display unit is selected, the operation information of the selected component is acquired by communicating with the industrial device specified by the device specifying unit. An operation information display unit to be displayed on the display unit,
An information display device comprising: The system configuration data creation unit
Creating the system configuration data including a system configuration diagram of the industrial system and a plurality of identification information respectively specifying the plurality of industrial devices;
The device specifying unit is
The information display device according to claim 1, wherein the industrial device imaged by the imaging device is specified by collating the image data with the identification information. The housing that houses one of the plurality of industrial devices has an identifier that identifies the industrial device housed in the housing,
The device specifying unit is
3. The information display device according to claim 2, wherein the industrial device housed in the casing imaged by the imaging device is specified by collating the image of the identifier with the identification information. . A housing that houses one of the plurality of industrial devices has a shape that identifies the industrial device housed in the housing,
The device specifying unit is
3. The information display according to claim 2, wherein the industrial device housed in the housing imaged by the imaging device is specified by collating the image of the housing with the identification information. apparatus. An information display method for displaying operation information representing an operation state of an industrial system including a plurality of industrial devices connected to a network,
A system configuration data creating step for creating system configuration data including a system configuration diagram of the industrial system;
An image data acquisition step of acquiring image data obtained by imaging one of the plurality of industrial devices from the imaging device;
A device identifying step for identifying the industrial device imaged by the imaging device based on the image data;
Based on the system configuration diagram, a configuration diagram display step for displaying a configuration diagram of the industrial device identified in the device identification step on a display unit;
When a component in the configuration diagram displayed on the display unit is selected, the operation information of the selected component is acquired by communicating with the industrial device specified in the device specifying step. Operation information display step to be displayed on the display unit,
An information display method comprising: An information display program for displaying operation information indicating an operation state of an industrial system including a plurality of industrial devices connected to a network,
A system configuration data creating step for creating system configuration data including a system configuration diagram of the industrial system;
An image data acquisition step of acquiring image data obtained by imaging one of the plurality of industrial devices from the imaging device;
A device identifying step for identifying the industrial device imaged by the imaging device based on the image data;
Based on the system configuration diagram, a configuration diagram display step for displaying a configuration diagram of the industrial device identified in the device identification step on a display unit;
When a component in the configuration diagram displayed on the display unit is selected, the operation information of the selected component is acquired by communicating with the industrial device specified in the device specifying step. Operation information display step to be displayed on the display unit,
An information display program characterized by causing a computer to execute.

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