JP2018189299A - Image generation device, display divice, equipment management device, and equipment management system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image generation device, a display device, an equipment management device, and an equipment management system that can acquire information representing constitution of object equipment and easily generate management images.SOLUTION: An image generation device 400 generates management images representing constitution of object equipment connected to a control device which controls air conditioning. The image generation device 400 comprises an information acquisition part 410 which acquires constitution character information representing the constitution of the object equipment related to constitution identification information from the control device, and a generation part 430 which generates the management images based upon the constitution character information that the information acquisition part 410 acquires.SELECTED DRAWING: Figure 16

Description

  The present invention relates to an image generation device, a display device, a device management device, and a device management system.

  In an air conditioning system provided in a railway vehicle, a plurality of air conditioners and sensors, and a control device that controls the plurality of air conditioners are provided in each vehicle. The control device is monitored and controlled by a management device provided in the interior wall of the vehicle, the electrical room, or the like. Since the type, number and control contents of the air conditioner and sensor differ depending on the railway vehicle specifications, the names of the devices displayed on the screen of the management apparatus and the control contents also differ depending on the railway vehicle specifications. Therefore, in order to generate a management image displayed on the screen of the management apparatus, information representing the name of the device and the content of control is stored in advance in the management apparatus.

  Patent Document 1 discloses a control device for an air conditioner in which data is sent from an external setting display means, and stored program data and setting data are rewritten.

JP 2001-91031 A

  Since many air conditioning equipment and sensors are installed in railroad vehicles, an image displayed on the screen of the management device is set for each air conditioning system, and the air conditioning equipment and sensors required to generate the image displayed on the screen are set. In order to memorize | store the information which shows a structure in a management apparatus, a great effort and expense are needed. Also in the control device of Patent Document 1, a great amount of labor and cost are required to set an image to be displayed on the screen and store a large amount of setting data in the external setting display means. Similar problems occur not only with air-conditioning equipment on railway vehicles, but also with various equipments and their management devices.

  The present invention has been made in view of the above circumstances, and provides an image generation device, a display device, a device management device, and a device management system that can acquire information indicating the configuration of a target device and easily generate a management image. The purpose is to do.

In order to achieve the above object, an image generation apparatus of the present invention provides:
An image generation device that generates a management image indicating a configuration of a target device connected to a control device that controls air conditioning, the target device associated with configuration identification information that identifies the configuration of the target device from the control device The information acquisition part which acquires the structure character information which shows this structure, and the production | generation part which produces | generates a management image based on the structure character information which the information acquisition part acquired.

  According to the present invention, since the information acquisition unit acquires the configuration character information associated with the configuration identification information from the control device, the image generation device acquires the information indicating the configuration of the target device and easily obtains the management image. Can be generated.

The figure which shows the structure of the air-conditioning equipment management system which concerns on Embodiment 1 of this invention. The figure which shows the air conditioning apparatus which concerns on Embodiment 1 of this invention. The block diagram which shows the structure of the control apparatus which concerns on Embodiment 1 of this invention. The figure which shows the apparatus identification information which concerns on Embodiment 1 of this invention. The figure which shows the operation identification information in the driving | running condition which concerns on Embodiment 1 of this invention. The figure which shows the operation identification information in the operation mode which concerns on Embodiment 1 of this invention. The figure which shows the apparatus character information which concerns on Embodiment 1 of this invention The figure which shows the operation character information which shows the driving condition which concerns on Embodiment 1 of this invention The figure which shows the operation character information which shows the operation mode which concerns on Embodiment 1 of this invention. The figure which shows the hardware constitutions of the control apparatus which concerns on Embodiment 1 of this invention. The block diagram which shows the structure of the temperature sensor and humidity sensor which concern on Embodiment 1 of this invention. The block diagram which shows the structure of the indoor air blower which concerns on Embodiment 1 of this invention, and an outdoor air blower. The block diagram which shows the structure of the compressor which concerns on Embodiment 1 of this invention. The block diagram which shows the structure of the apparatus management apparatus which concerns on Embodiment 1 of this invention. The figure which shows the structure of the hardware of the apparatus management apparatus which concerns on Embodiment 1 of this invention. 1 is a block diagram showing a configuration of an image generation unit according to Embodiment 1 of the present invention. The flowchart which shows the display process of the management image which concerns on Embodiment 1 of this invention. The flowchart which shows the information acquisition process which concerns on Embodiment 1 of this invention. The flowchart which shows the display process which concerns on Embodiment 1 of this invention. The figure which shows the management image which shows the driving | running state which concerns on Embodiment 1 of this invention. The figure which shows the management image which shows the operation mode which concerns on Embodiment 1 of this invention. The figure which shows the apparatus display data based on Embodiment 2 of this invention The figure which shows the operation | movement display data based on Embodiment 2 of this invention. The figure which shows the control apparatus identification information which concerns on Embodiment 3 of this invention. The figure which shows the connection data based on Embodiment 3 of this invention The flowchart which shows the information acquisition process by the connection data which concerns on Embodiment 3 of this invention.

  Hereinafter, an embodiment in which an image generation unit according to an embodiment of the present invention is applied to a management apparatus for air conditioning equipment of a railway vehicle will be described with reference to the drawings. In each embodiment, the image generation unit automatically generates a management image indicating the configuration of the target device connected to the air conditioning control device of the railway vehicle, and the management device displays this management image. Further, in this specification, the image generation unit functions as an image generation device.

Embodiment 1 FIG.
With reference to FIGS. 1-21, the air-conditioning equipment management system 10 which concerns on Embodiment 1 of this invention is demonstrated. In the device management apparatus 300 of the air conditioning device management system 10, the image generation unit 400 acquires configuration identification information that identifies the configuration of the target device 100 and configuration character information that indicates the configuration of the target device 100 from the control devices 200 </ b> A to 200 </ b> D. Then, a management image indicating the configuration of the target device 100 is generated. Hereinafter, the control devices 200A to 200D are collectively referred to as the control device 200.

The air conditioning equipment management system 10 is provided in a train (not shown). The air conditioning equipment management system 10 manages the temperature and humidity in the vehicle.
As shown in FIG. 1, the air conditioning equipment management system 10 includes a control device 200 that controls air conditioning, a temperature sensor 102 and a humidity sensor 104 that are connected to the control device 200, and an air conditioning device 106 that harmonizes the air in the vehicle. And a device management apparatus 300 that manages the control apparatus 200. As shown in FIG. 2, the air conditioner 106 includes an indoor fan 106A, an outdoor fan 106B, a compressor 106C, and a compressor 106D that are connected to and controlled by the control device 200. In this specification, it is assumed that the air conditioner 106 is connected to the control device 200 via the indoor fan 106A, the outdoor fan 106B, and the compressors 106C and 106D.
In the present embodiment, the target device 100 connected to each of the control devices 200A to 200D includes a temperature sensor 102, a humidity sensor 104, an air conditioner 106, an indoor fan 106A and an outdoor fan 106B included in the air conditioner 106. And compressor 106C and compressor 106D. Note that the number and type of control devices 200 managed by the device management apparatus 300 and the number and type of target devices 100 to which the control devices 200 are connected are arbitrary.

  The control device 200 and the device management device 300 are connected by wire or wireless. For example, the control device 200 and the device management device 300 are connected by a CAN (Controller Area Network). The target device 100 and the control device 200 are connected via an input / output interface.

First, the target device 100 and the control device 200 will be described.
The control device 200 is provided for each vehicle that forms a train. The control device 200 controls air conditioning in the vehicle. Specifically, the control device 200 acquires the temperature and humidity in the vehicle from the temperature sensor 102 and the humidity sensor 104. The control device 200 controls the indoor blower 106A, the outdoor blower 106B, and the compressors 106C and 106D of the air conditioner 106 based on the acquired temperature and humidity, and causes the air conditioner 106 to control the temperature and humidity in the vehicle. .

  As shown in FIG. 3, the control device 200 includes a storage unit 210 that stores information and programs, a temperature sensor 102, and a humidity sensor 104 that are used to control the indoor fan 106 </ b> A, the outdoor fan 106 </ b> B, and the compressors 106 </ b> C and 106 </ b> D. The temperature and humidity are acquired from the control unit 220, the control unit 220 that controls the operation of the indoor fan 106A, the outdoor fan 106B, and the compressors 106C and 106D, the communication unit 230 that communicates with the device management apparatus 300, and the target device 100. And an input / output unit 240.

  The storage unit 210 stores information and a program used for controlling the indoor fan 106A, the outdoor fan 106B, and the compressors 106C and 106D. The storage unit 210 stores configuration identification information and configuration character information associated with the configuration identification information.

  First, the configuration identification information will be described. The configuration identification information is information that identifies the configuration of the target device 100. In the present embodiment, the configuration identification information is device identification information for identifying the target device 100 and operation identification information for identifying the operation state of the target device 100.

The device identification information and the operation identification information will be described using the control device 200A as an example.
FIG. 4 shows device identification information stored in the storage unit 210 of the control device 200A. The device identification information is a device ID (Identifier) assigned to each target device 100 in order to identify the target device 100. In the present embodiment, for example, the device ID # 0006 is assigned to the compressor 106D controlled by the control device 200A. In FIG. 4, the target device 100 is not assigned to a device ID in which the target device is blank.

The operation identification information is information representing the operation state of the target device 100, and is an ID assigned to each operation state in order to identify the operation state of the target device 100. The operation identification information is provided for each operation state of the target device 100, for example, an operation state including operation, stop, and strength, an operation mode, and a sensor detection mode. FIG. 5 shows the operation identification information in the operation status of the indoor fan 106A, the outdoor fan 106B, and the compressors 106C and 106D. For example, the operation status ID # 0001 is assigned to “operation”. FIG. 6 shows the operation identification information in the operation mode of the air conditioner 106. For example, operation mode ID # 0006 is assigned to forced cooling. In FIG. 5 and FIG. 6, no operation state or operation mode is assigned to the blank.
Also in the control devices 200B to 200D, the device identification information and the operation identification information are stored in the storage unit 210 as in the control device 200A.

  Next, the constituent character information will be described. The configuration character information is character information that is associated with the configuration identification information and indicates the configuration of the target device 100. In the present embodiment, the constituent character information is device character information indicating the target device 100 and operation character information indicating the operation state of the target device 100. The device character information is associated with the device identification information, and the operation character information is associated with the operation identification information.

The device character information and the operation character information will be described using the control device 200A as an example.
FIG. 7 shows device character information. In the present embodiment, for example, the device ID # 0006 of the compressor 106D is associated with device character information representing the character “CP2”. In FIG. 7, the device character information is not associated with the blank.

FIG. 8 shows operation character information indicating the operation status of the indoor fan 106A, the outdoor fan 106B, and the compressors 106C and 106D. For example, operation character information representing characters of the driving status # 0001 “operation” and “ON” is associated. FIG. 9 shows operation character information indicating the operation mode of the air conditioner 106. Operation character information representing characters of the driving situation # 0006 “forced cooling” and “Kyosei Reibou” is associated. In FIG. 8 and FIG. 9, no action character information is associated with the blank.
Also in the control devices 200B to 200D, device character information and operation character information are stored in the storage unit 210, as in the control device 200A.

  Returning to FIG. 3, the controller 220 will be described. The control unit 220 acquires temperature and humidity from the temperature sensor 102 and the humidity sensor 104 based on an instruction from the device management apparatus 300. Further, the control unit 220 controls the operations of the indoor fan 106A, the outdoor fan 106B, and the compressors 106C and 106D based on an instruction from the device management apparatus 300. Further, the control unit 220 controls operations of the storage unit 210, the communication unit 230, and the input / output unit 240.

  The communication unit 230 communicates with the device management apparatus 300. The input / output unit 240 inputs / outputs signals between the target device 100 and the control unit 220.

  FIG. 10 shows a hardware configuration of the control device 200. The control unit 220 includes a CPU (Central Processing Unit) 242. The function of the control unit 220 is realized by the CPU 242 executing a program stored in the storage unit 210. The storage unit 210 includes a ROM (Read Only Memory) 243 and a RAM (Random Access Memory) 244. The communication unit 230 is a communication interface 245. The input / output unit 240 is an input / output interface 246. The CPU 242, ROM 243, RAM 244, communication interface 245, and input / output interface 246 are connected by a bus 248.

The target device 100 is provided in each vehicle that forms a train. The target device 100 is connected to the control device 200.
The target device 100 is a sensor that detects the environment in the vehicle used for controlling the air conditioner 106 that harmonizes the air in the vehicle, the device that the air conditioner 106 has, and the device that the air conditioner 106 has. In the present embodiment, the target device 100 is a temperature sensor 102, a humidity sensor 104, an air conditioner 106, an indoor fan 106A, an outdoor fan 106B, and compressors 106C and 106D of the air conditioner 106.

  As shown in FIG. 11, the temperature sensor 102 and the humidity sensor 104 include a detection unit 110 and an input / output unit 120.

  The detection unit 110 of the temperature sensor 102 detects the temperature inside the vehicle. The detection unit 110 of the temperature sensor 102 detects the temperature by, for example, a temperature measuring method. The detection unit 110 of the humidity sensor 104 detects the humidity inside the vehicle. The detection unit 110 of the humidity sensor 104 detects humidity by, for example, a polymer capacitance type. The input / output unit 120 is an input / output interface, and inputs and outputs signals between the detection unit 110 and the control device 200.

  As shown in FIG. 12, the indoor fan 106 </ b> A and the outdoor fan 106 </ b> B include a fan 150 and an input / output unit 160. The fan 150 of the indoor fan 106A sends air to the evaporator of the air conditioner 106 described later. The fan 150 of the outdoor fan 106B sends air to the condenser of the air conditioner 106 described later. The input / output unit 160 is an input / output interface, and inputs / outputs signals between the fan 150 and the control device 200.

  As shown in FIG. 13, the compressors 106 </ b> C and 106 </ b> D include a compression unit 170 and an input / output unit 180. The compression unit 170 compresses and circulates the refrigerant. The input / output unit 180 is an input / output interface, and inputs / outputs signals between the compression unit 170 and the control device 200.

  The air conditioner 106 is provided in each of the vehicles that form the train, and harmonizes the air in the vehicle by the indoor fan 106A, the outdoor fan 106B, the compressor 106C, and the compressor 106D. The air conditioner 106 is connected to the control device 200 via an indoor fan 106A, an outdoor fan 106B, a compressor 106C, and a compressor 106D. The air conditioner 106 has a known configuration including, in addition to the indoor fan 106A, the outdoor fan 106B, and the compressors 106C and 106D, a condenser that liquefies the refrigerant, an evaporator that vaporizes the refrigerant, a capillary tube, an outside air temperature sensor, and the like. . Note that devices other than the indoor fan 106 </ b> A, the outdoor fan 106 </ b> B, and the compressors 106 </ b> C and 106 </ b> D of the air conditioner 106 may be the target device 100 connected to the control device 200.

  Next, the device management apparatus 300 will be described. The device management apparatus 300 manages the control apparatus 200.

  As illustrated in FIG. 14, the device management apparatus 300 includes an input unit 310 that receives an instruction from a user, a storage unit 320 that stores information and a program, a communication unit 330 that communicates with the control device 200, and the control device 200. A control unit 340 that controls the management image, a display unit 350 that displays the management image, an image generation unit 400 that generates the management image, and a display control unit 450 that displays the management image on the display unit. Here, the management image is an image showing the configuration of the target device 100. The management image represents information necessary for the user to control or monitor the target device 100.

  FIG. 15 shows a hardware configuration of the device management apparatus 300. The input unit 310 is, for example, a touch panel 341, a keyboard, and a selection switch. The storage unit 320 includes a ROM 343 and a RAM 344. The communication unit 330 is a communication interface 345.

The functions of the control unit 340, the image generation unit 400, and the display control unit 450 are realized by the CPU 346 executing a program stored in the storage unit 320. The display unit 350 is a liquid crystal display 347, for example.
The CPU 346 and each unit are connected via a bus 348.

Returning to FIG. 14, the controller 340 will be described. The control unit 340 sends an instruction to the control device 200 based on the instruction from the user received by the input unit 310, and controls the indoor fan 106A, the outdoor fan 106B, the compressor 106C, and the compressor 106D. The control unit 340 controls the indoor fan 106A, the outdoor fan 106B, the compressor 106C, and the compressor 106D based on the temperature and humidity acquired from the temperature sensor 102 and the humidity sensor 104.
The control unit 340 causes the display control unit 450 to display a management image corresponding to the user instruction on the display unit 350 based on an instruction from the user. The control unit 340 further controls the storage unit 320, the communication unit 330, and the image generation unit 400.

  As illustrated in FIG. 16, the image generation unit 400 includes an information acquisition unit 410 that acquires configuration identification information and configuration character information associated with the configuration identification information from the control device 200, and a generation unit 430 that generates a management image. And a hierarchy information generation unit 440 that generates image hierarchy information representing transitions between management images. In this specification, the image generation unit 400 functions as the image generation apparatus 400.

  The information acquisition unit 410 acquires configuration identification information and configuration character information associated with the configuration identification information from the control device 200 via the communication unit 330 of the device management apparatus 300. The information acquisition unit 410 causes the storage unit 320 to store the acquired constituent character information. The generation unit 430 generates a management image based on the configuration identification information and the configuration character information acquired by the information acquisition unit 410.

  The hierarchy information generation unit 440 generates image hierarchy information representing a transition from one management image to the other management image. Since the information acquisition unit 410 acquires the configuration character information according to the configuration identification information, the hierarchical information generation unit 440 generates a management image based on the configuration character information from the configuration character information acquired by the information acquisition unit 410. Next, it is possible to set which constituent character information is used to change to the management image generated based on. The hierarchy information generation unit 440 causes the storage unit 320 to store image hierarchy information representing the set transition.

  Returning to FIG. 14, the display control unit 450 causes the display unit 350 to display the management image generated by the image generation unit 400.

Next, management image display processing will be described with reference to FIGS.
In the air conditioning equipment management system 10 provided in the train, power is supplied to the temperature sensor 102, the humidity sensor 104, the air conditioning apparatus 106, the control apparatus 200, and the equipment management apparatus 300, and the temperature and humidity in the vehicle are controlled by the air conditioning equipment management system. 10 is managed.

  In the management image display process, as shown in FIG. 17, an information acquisition process (step S11) for acquiring constituent character information is performed, and then a display process (step S12) for displaying the management image is performed. After the display process (step S12), if no end instruction is input to the control unit 340 (step S13; NO), the management image display process returns to the display process (step S12). When an end instruction is input to the control unit 340 (step S13; YES), the management image display process ends.

First, the information acquisition process (step S11) will be described with reference to FIG.
When power is supplied to the device management apparatus 300, the constituent character information stored in the storage unit 320 is deleted, and the image generation unit 400 is reset (step S101). The information acquisition unit 410 of the image generation unit 400 acquires configuration character information associated with the configuration identification information from the control device 200 (step S102). Specifically, the information acquisition unit 410 sequentially transmits an instruction signal for outputting the constituent character information to the control devices 200A to 200D, and receives the constituent character information from each of the control devices 200A to 200D. Note that if the information acquisition unit 410 does not receive the signal representing the constituent character information from the control devices 200A to 200D, the information acquisition unit 410 determines that the acquisition of the constituent character information has failed and has not received the signal representing the constituent character information. An instruction signal for outputting the constituent character information is transmitted to the control device 200 again.
The information acquisition unit 410 outputs the acquired constituent character information to the hierarchy information generation unit 440, and the hierarchy information generation unit 440 generates image hierarchy information and stores it in the storage unit 320 (step S103). The information acquisition unit 410 stores the acquired constituent character information in the storage unit 320 (step S104). When the constituent character information is stored in the storage unit 320, the information acquisition process (step S11) ends.

The display process (step S12) will be described with reference to FIG.
Upon receiving an instruction to display a management image from the user, the control unit 340 of the device management apparatus 300 indicates the current configuration of the target device 100 to the control device 200 based on the image hierarchy information stored in the storage unit 320. An instruction signal for outputting the configuration identification information is transmitted (step S201). The information acquisition unit 410 of the image generation unit 400 receives the configuration identification information from the control device 200, and outputs the configuration identification information to the generation unit 430 (step S202). The generation unit 430 generates a management image based on the acquired configuration identification information and the configuration character information acquired and stored in the storage unit 320 (step S203). The display control unit 450 displays the management image generated by the generation unit 430 on the display unit 350 (step S204).

  Next, the management image will be described in detail with reference to FIGS. 20 and 21 and FIGS. Here, for easy understanding, an air conditioner including a control device 200A, a temperature sensor 102 and a humidity sensor 104 connected to the control device 200A, an indoor fan 106A, an outdoor fan 106B, and compressors 106C and 106D. It is assumed that the device 106 is provided in the first vehicle.

  FIG. 20 shows a management image showing the operating status of the indoor fan 106A, the outdoor fan 106B, and the compressors 106C and 106D of the air conditioner 106 provided in the first vehicle. “EF”, “CF”, “CP1”, and “CP2”, which correspond to the name of the target device 100 and identify the target device 100, are generated based on the device character information shown in FIG. “EF”, “CF”, “CP1”, and “CP2” are associated with the indoor fan 106A, the outdoor fan 106B, the compressor 106C, and the compressor 106D, respectively. Further, “H” indicating the driving status of “EF”, “L” indicating the driving status of “CF”, and “ON” indicating the driving status of “CP1” and “CP2” are shown in FIG. It is generated based on operation character information in the operating status of the indoor fan 106A, the outdoor fan 106B, and the compressors 106C and 106D. In the device character information shown in FIG. 7, since the device character information is not associated with the device IDs # 0002 and # 0004, the columns corresponding to the device IDs # 0002 and # 0004 are blank.

  FIG. 21 shows a management image showing the operation mode of the air conditioner 106. For example, when the user selects “AC” in the management image indicating the list of the target devices 100, the management image indicating the operation mode is displayed based on the image hierarchy information. The “jidoraybow” indicating the operation mode of the air conditioner 106 is generated based on the operation character information in the operation mode shown in FIG.

  As described above, the image generation unit 400 can generate a management image based on the constituent character information acquired from the control device 200. Since the image generation unit 400 acquires component character information that is different for each air conditioning device management system 10 from the control device 200 and generates a management image, the device management device 300 or the image generation unit 400 stores the component character information in advance. The management image can be easily generated. Furthermore, since the image generation unit 400 generates the image hierarchy information from the acquired constituent character information, the management image can be generated more easily.

Embodiment 2. FIG.
The image generation unit 400 according to the second embodiment will be described with reference to FIGS. 22 and 23 and FIGS. In the first embodiment, the information acquisition unit 410 of the image generation unit 400 acquires the constituent character information. However, other information may be acquired in addition to the constituent character information.

  In the present embodiment, the information acquisition unit 410 acquires device display data and operation display data from the control device 200 before acquiring constituent character information. Since the constituent character information is the same as the constituent character information in the first embodiment, the device display data and the operation display data will be described here. In the present embodiment, control device 200 stores device display data and operation display data in storage unit 210.

  FIG. 22 shows device display data. The device display data is data in which device identification information is associated with information indicating the presence / absence of device character information associated with the device identification information. For example, since “CP2” represented by the device character information is associated with the device ID # 0006, which is the device identification information in FIG. 7, the device ID # 0006 and the device character information are “present” in the device display data. Is associated with information representing the. In addition, since device character information is not associated with device ID # 0002, which is device character information in FIG. 7, the device display data includes device ID # 0002 and information indicating that there is no device character information. Associated.

  FIG. 23 shows operation display data. The action display data is data in which action identification information is associated with information indicating the presence / absence of action character information associated with the action identification information. For example, in FIG. 9, the operation mode ID # 0006, which is the operation identification information, is associated with “Keisei Reibou” represented by the operation character information, so that the device display data includes the device ID # 0006 and the operation character information. "Is associated with the information indicating"

  In the present embodiment, the information acquisition unit 410 first acquires device display data and operation display data. Next, the information acquisition unit 410 acquires only the device character information associated with the device identification information and the operation character information associated with the operation identification information based on the device display data and the operation display data. As a result, the amount of communication between the device management apparatus 300 and the control apparatus 200 decreases, so that the risk of failure in acquiring the constituent character information is reduced, and the information acquisition unit 410 can acquire the constituent character information more reliably. Other configurations in the present embodiment are the same as those in the first embodiment.

  As described above, the information acquisition unit 410 acquires only the associated device character information and operation character information based on the device display data and the operation display data. You can get it. Further, since the information acquisition unit 410 acquires the constituent character information from the control device 200 as in the first embodiment, the image generation unit 400 can easily generate a management image. Since the image generation unit 400 generates the image hierarchy information from the acquired constituent character information, the management image can be generated more easily.

Embodiment 3 FIG.
The image generation unit 400 according to the third embodiment will be described with reference to FIGS.
The information acquisition unit 410 of the image generation unit 400 may acquire connection data from the control device 200 in addition to the constituent character information, device display data, and operation display data. The connection data is data in which control device identification information for identifying the control device 200 is associated with whether or not the device management device 300 and the control device 200 are connected.

  FIG. 24 shows control device identification information in the present embodiment. The control device identification information is a control device ID assigned to each control device 200. For example, the control device 200A is assigned to the control device ID # 1.

  FIG. 25 shows connection data in the present embodiment. The connection data is stored in the storage unit 210 of the control device 200 having the smallest control device ID. In the present embodiment, storage unit 210 of control device 200A stores connection data.

  In the present embodiment, the information acquisition unit 410 of the image generation unit 400 first acquires connection data from the control device 200 having the smallest control device ID. The information acquisition unit 410 determines the connected control device 200 based on the acquired connection data. The information acquisition unit 410 acquires device display data, operation display data, and constituent character information only from the control device 200 determined to be connected. Other configurations are the same as those in the first and second embodiments.

  In the present embodiment, an information acquisition process using connection data is performed instead of the information acquisition process of the first embodiment. Here, with reference to FIG. 26, an information acquisition process using connection data will be described.

  When power is supplied to the device management apparatus 300, the constituent character information stored in the storage unit 320 is deleted, and the image generation unit 400 is reset (step S301). The information acquisition unit 410 of the image generation unit 400 acquires connection data from the control device 200 (step S302). Specifically, the information acquisition unit 410 transmits an instruction signal for outputting connection data to the control device 200A to which the control device ID # 1 is assigned, and receives the connection data from the control device 200A. The information acquisition unit 410 initializes the control device ID, which is a variable for determining the presence / absence of connection, to 1 (step S303), and determines the presence / absence of connection with the control device 200 based on the connection data (step S304).

  If the connection with the control device 200 is “present” (step S304; YES), the information acquisition unit 410 acquires device display data, operation display data, and constituent character information (step S305). Next, the control device ID is set to the next value (step S306), and it is determined whether or not it is larger than the natural number N that is the maximum control device ID included in the connection data (step S307). When the control device ID is smaller than N (step S307; NO), the information acquisition unit 410 returns to the connection determination (step S304). If the control device ID is greater than N (step S307; YES), the information acquisition unit 410 proceeds to generation of image hierarchy information (step S308).

  If there is no connection with the control device 200 (step S304; NO), the control device ID is set to the next value (step S306), and it is determined whether it is greater than N (step S307). When the control device ID is smaller than N (step S307; NO), the information acquisition unit 410 returns to the connection determination (step S304), and when the control device ID is larger than N (step S307; YES), the image hierarchy The process proceeds to information generation (step S308).

  After the information acquisition unit 410 acquires the device display data, the operation display data, and the constituent character information (steps S303 to S307), the hierarchical information generation unit 440 generates the image hierarchical information as in the first embodiment, and the storage unit It is stored in 320 (step S308). The information acquisition unit 410 stores the acquired constituent character information in the storage unit 320 (step S309). When the constituent character information is stored in the storage unit 320, the information acquisition process using the connection data ends. In step S305, only the constituent character information may be acquired.

  As described above, the image generation unit 400 determines the connected control device 200 based on the connection data, and acquires device display data, operation display data, and constituent character information. Since the image generation unit 400 acquires the device display data, the operation display data, and the constituent character information from only the control device 200 determined to be connected, the device display data and the operation display can be efficiently performed in a shorter time. Data and constituent character information can be acquired. Further, since the information acquisition unit 410 acquires the constituent character information from the control device 200 as in the first embodiment, the image generation unit 400 can easily generate a management image. Since the image generation unit 400 generates the image hierarchy information from the acquired constituent character information, the management image can be generated more easily.

  As mentioned above, although several embodiment of this invention was described, this invention is not limited to said embodiment, A various change is possible in the range which does not deviate from the summary of this invention.

  For example, in Embodiments 1 to 3, the environment managed by the air conditioning equipment management system 10 is not limited to temperature and humidity. The air conditioning equipment management system 10 may manage the air environment, and may manage, for example, air cleanliness and airflow. Further, the number and type of target devices 100 are arbitrary. For example, the target device 100 may be a sensor that detects the density of passengers or a sensor that detects the cleanliness of air.

  Further, the number and type of control devices 200 are arbitrary. For example, the control apparatus 200 may be an apparatus that includes an inverter that changes the frequency and voltage of AC power and that controls the target device 100 using an inverter. Further, when the image generation unit 400 generates the image hierarchy information, the target device 100 that is controlled by the inverter can be managed separately by generating the image hierarchy information for the target device 100 that is controlled by the inverter.

  The device management apparatus 300 may be a device that monitors the state of the target device 100. Furthermore, the image generation unit 400 may be included in an independent image generation apparatus 400 that includes a CPU, a RAM, a ROM, and the like. The image generation device 400 may be included in an independent display device together with the display unit 350.

  Furthermore, the configuration identification information is not limited to the operation identification information and the device identification information, and may be information for identifying the installation location of the target device 100, for example. In the second embodiment, the image generation unit 400 may acquire one of device display data and operation display data. In the third embodiment, when the information acquisition unit 410 does not receive a signal representing connection data from the control device 200A, the information acquisition unit 410 determines that acquisition of connection data has failed, and again transmits connection data to the control device 200A. May be transmitted.

  DESCRIPTION OF SYMBOLS 10 Air-conditioning equipment management system, 100 Target equipment, 102 Temperature sensor, 104 Humidity sensor, 106 Air-conditioning apparatus, 106A Indoor fan, 106B Outdoor fan, 106C, 106D Compressor, 110 Detection part, 120, 160, 180, 240 Input / output part , 150 fan, 170 compression unit, 200, 200A, 200B, 200C, 200D control device, 210, 320 storage unit, 220, 340 control unit, 230, 330 communication unit, 242, 346 CPU, 243, 343 ROM, 244 344 RAM, 245, 345 communication interface, 246 input / output interface, 248, 348 bus, 300 device management device, 310 input unit, 341 touch panel, 347 liquid crystal display, 350 display unit, 400 image generation unit, image production Device 410 information acquisition unit, 430 generating section, 440 hierarchy information generation unit, 450 display control unit

Claims (10)

An image generation device that generates a management image and shows a configuration of a target device connected to a control device that controls air conditioning,
An information acquisition unit that acquires configuration character information indicating the configuration of the target device associated with configuration identification information that identifies the configuration of the target device from the control device;
A generation unit that generates the management image based on the constituent character information acquired by the information acquisition unit;
Image generation device. The configuration identification information includes device identification information for identifying the target device,
The component character information includes device character information indicating the target device associated with the device identification information.
The image generation apparatus according to claim 1. The information acquisition unit acquires, from the control device, device display data that associates the device identification information with the presence or absence of the device character information associated with the device identification information, and adds the device display data to the acquired device display data. Based on the device identification information associated with the device identification information,
The image generation apparatus according to claim 2. The configuration identification information includes operation identification information for identifying an operation state of the target device,
The component character information includes operation character information indicating an operation state of the target device associated with the operation identification information.
The image generation apparatus according to claim 1. The information acquisition unit acquires operation display data in which the operation identification information and presence / absence of the operation character information associated with the operation identification information are associated with the acquired operation display data. Obtaining the action character information associated with the action identification information,
The image generation apparatus according to claim 4. Based on the constituent character information acquired by the information acquisition unit, generates image hierarchy information representing a transition from one management image to the other management image in the plurality of management images.
The image generation apparatus according to claim 1. The control device is plural,
The information acquisition unit determines the control device that acquires the constituent character information based on connection data that associates control device identification information that identifies the control device and whether or not the control device is connected, and Obtaining the component character information from the control device determined to obtain;
The image generation apparatus according to claim 1. The image generation apparatus according to any one of claims 1 to 7,
A display unit for displaying the management image;
Display device. The display device according to claim 8 is provided.
Equipment management device. A control device for controlling air conditioning, a target device connected to the control device, and a management device,
The management apparatus includes a display unit that displays a management image indicating a configuration of the target device, and an image generation unit that generates the management image.
The image generation unit acquires, from the control device, an information acquisition unit that acquires configuration character information indicating a configuration of the target device associated with configuration identification information that identifies a configuration of the target device, and the information acquisition unit acquires A generating unit that generates the management image based on the component character information
Equipment management system.

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