JP2014030088A - Remote management system and gateway unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable remote management in a conventional manner for each apparatus installed at a facility without increasing cost, even if gateway units at facility side are integrated into one unit.SOLUTION: An integrated gateway 10 includes: a compressed module storing part 17 for storing modules in a compressed condition for each facility controller, where the modules are a basic function module for realizing an essential function for remote management at a management center and an additional function module for realizing an additional function; a decompression module determination part 12 for determining the additional function module to be decompressed, and loaded on a RAM, depending on a priority of the additional function module, according to the RAM capacity and a module size of each function module after decompression; and an environment determination part 13 for performing an environment setting for the integrated gateway 10, by decompressing the basic function module and the determined additional function module and loading them on the RAM.

Description

  The present invention relates to a remote management system for remotely managing equipment installed in a facility and a gateway device used in the remote management system.

  In a facility such as a building, if the equipment is, for example, an air conditioner, one or more air conditioners to be controlled are connected to an air conditioning control controller. When different types of air conditioners are installed, the air conditioners may be grouped for each model, and an air conditioning control controller may be prepared for each group. Then, a functional module dedicated to the equipment is installed in the gateway device, and a corresponding dedicated gateway device is connected to the equipment controller that controls the operation of each equipment such as an air conditioning control controller.

  When building a remote management system that remotely manages equipment such as air conditioners and substation equipment installed in a building, the remote management center that manages the equipment by configuring the building side as described above Remote management of each equipment was performed via a gateway device.

JP 2009-224852 A JP 2003-152812 A

  Conventionally, since it is necessary to install as many gateway devices as the number of equipment controllers in each facility, the cost required for the gateway device and the load and cost for the installation work have been enormous. In order to solve this problem, it is conceivable that, on the facility side, one gateway device is installed at the entrance / exit of the data transmission of the facility and the processing functions of the conventional gateway devices are integrated into one.

  However, when the processing function that has been distributed to a plurality of gateway devices is simply integrated into one gateway device, software that has realized the processing function in each of the plurality of gateway devices in the integrated gateway device ( Therefore, there is a possibility that the storage capacity for storing the functional modules and the memory capacity for operating the functional modules will be insufficient.

  As described above, there is a case where it is difficult to cope with a single gateway device by simply consolidating the processing functions without any ingenuity.

  An object of the present invention is to enable remote management of each equipment installed in a facility as in the past without increasing the cost even when the gateway devices installed on the facility side are integrated into one unit. And

  The remote management system according to the present invention includes a management center that remotely manages one or a plurality of equipment installed in each facility, and one or a plurality of equipment installed and connected in each facility. A plurality of equipment controllers, and a gateway device that relays information that is installed in each facility and communicates between the equipment and the management center via a network, and is prepared for each equipment controller Compression module storage means for storing a basic function module that realizes a function essential for remote management in the management center and an additional function module that realizes an additional function in a compressed state. Priority order storing at least priority order information indicating the priority order of the additional function module set for each equipment controller Information storage means, equipment information related to equipment information related to equipment equipment related to equipment installed in the facility, memory capacity of the gateway device and each equipment equipment corresponding to the equipment installed in the facility Based on the relationship with the module size after decompression of the function module, the function module is decompressed together with the basic function module corresponding to the equipment installed in the facility according to the priority order set in the priority order information and loaded into the memory of the gateway device. Decompression module determination means for determining an additional function module, a basic function module corresponding to the equipment controller, and an additional function module determined by the decompression module determination means, and loading them into the memory of the gateway device. Environment setting means for setting the environment of the device; And it has a.

  Further, the priority order information further includes setting information on the priority order of the connected equipment controllers.

  The equipment related information includes at least the number of the equipment controlled by the equipment controller, and the decompression module determining means determines the number of the equipment included in the equipment related information. The module size after decompression of each functional module is calculated with reference to the module size.

  The gateway apparatus according to the present invention connects one or more equipment controllers that control one or more equipment installed in a facility, and between the equipment and a management center that remotely manages the equipment. In a gateway device that relays information communicated via a network, a basic function module that realizes a function essential for remote management in the management center, which constitutes a function module prepared for each facility controller, and an additional function module Compression module storage means for storing additional function modules for realizing functions in a compressed state, and priority information storage for storing at least priority information indicating priority of the additional function modules set for each equipment controller And equipment-related information related to the equipment and equipment installed in the facility The priority set in the priority order information from the relationship between the equipment-related information acquisition means to be acquired, the memory capacity of the gateway device and the module size after decompression of each functional module corresponding to the equipment installed in the facility According to the order, when the additional function module to be decompressed together with the basic function module corresponding to the equipment installed in the facility and loaded into the memory of the gateway device is determined, the basic function module corresponding to the equipment controller and the decompression module are determined. And an environment setting means for setting the environment of the gateway device by decompressing the additional function module determined by the means and loading it into the memory of the gateway device.

  ADVANTAGE OF THE INVENTION According to this invention, even when the gateway apparatus installed in the facility side is integrated into 1 unit | set, the remote management of each installation apparatus installed in the facility is realizable, without increasing a cost.

1 is an overall configuration diagram showing an embodiment of a remote management system according to the present invention. It is a hardware block diagram of the integrated gateway in this Embodiment. It is a block block diagram of the integrated gateway in this Embodiment. In this Embodiment, it is the conceptual diagram which showed the relationship between the compressed functional module stored in HDD, and the functional module after decompression loaded to RAM. It is the figure which showed the data structural example of the priority information of the equipment controller 4 memorize | stored in the apparatus priority information storage part in this Embodiment. It is the figure which showed the data structural example of the functional module information memorize | stored in the functional module information storage part in this Embodiment. It is the flowchart which showed the decompression module determination process in this Embodiment.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is an overall configuration diagram showing an embodiment of a remote management system according to the present invention. FIG. 1 shows each building 1 as an example of a facility, and a remote management center 3 that remotely manages equipment installed in the building 1 via a network 2. The network 2 is an Internet network, a regional IP network, or the like. The remote management center 3 is provided with one or a plurality of server computers (not shown). The remote management center 3 performs remote management of equipment installed in the building 1 using a server computer. The remote management center 3 may have the same configuration as before.

  Each building 1 has a configuration in which an equipment controller 4 and an integrated gateway 10 are connected to an in-building network 5. The equipment controller 4 is a control device that classifies and connects equipment equipment (not shown) such as air conditioning equipment, power receiving / transforming equipment, disaster prevention equipment, and the like for each type of equipment. If the manufacturer is different even for the same equipment, or if the model is different for the same manufacturer, the equipment controller 4 may be provided for each manufacturer. The integrated gateway 10 can be realized by a general-purpose gateway device. Conventionally, the gateway device is provided corresponding to each equipment controller 4, but in the present embodiment, these conventional gateway devices are integrated and only one gateway device is installed in the building 1. As described above, in this embodiment, it is referred to as “integrated gateway”. In the present embodiment, the processing capability of the integrated gateway 10, specifically, the memory capacity, the storage capacity, etc., is simply because the processing functions installed in each of the plurality of gateway devices are consolidated into one integrated gateway 10. It is characterized by the fact that it is possible to cope with even the equivalent.

  FIG. 2 is a hardware configuration diagram of the integrated gateway 10 in the present embodiment. The computer incorporated in the integrated gateway 10 in the present embodiment can be realized with a general-purpose hardware configuration that has existed in the past. That is, as shown in FIG. 2, the computer includes a CPU 21, a ROM 22 as a non-volatile storage means, a RAM 23 as a volatile storage means, an HDD controller 25 to which a hard disk drive (HDD) 24 as an external storage device is connected, a communication means. The network controller 26 provided as is connected to an internal bus 27. In the present embodiment, a management terminal (not shown) is connected to the network controller 26, the display of the management terminal is used as the output means of the integrated gateway 10, and the keyboard and mouse of the management terminal are input means of the integrated gateway 10. However, the integrated gateway 10 may be provided with input / output means.

  FIG. 3 is a block diagram of the integrated gateway 10 in the present embodiment. The configuration of the integrated gateway 10 installed in each building 1 may be the same. In the following explanation, when the building 1, the equipment controller 4 and the equipment and the like are simply described, the integrated gateway 10, the equipment controller 4 and the equipment are in a relationship installed in the same building 1. And

  The integrated gateway 10 includes an equipment related information acquisition unit 11, a decompression module determination unit 12, an environment setting unit 13, an error notification unit 14, a control unit 15, a compression module storage unit 17, a device priority order information storage unit 18, and a functional module information storage. It has a part 19. The equipment related information acquisition unit 11 is provided as equipment equipment related information acquisition means, and acquires equipment related information related to equipment installed in the building 1. The decompression module determination unit 12 is provided as a decompression module determination unit. The priority information of the equipment controller 4 stored in the device priority information storage unit 18 and the priority order of the additional function modules stored in the function module information storage unit 19 In accordance with the priority set in the information, the equipment installed in the building 1 from the relationship between the memory capacity of the integrated gateway 10 and the module size after decompression of each functional module corresponding to the equipment installed in the building 1 The additional function module to be decompressed together with the basic function module corresponding to and loaded into the memory (RAM 23) of the integrated gateway 10 is determined. The environment setting unit 13 is provided as an environment setting unit, and extracts the basic function module corresponding to the equipment controller 4 and the function module determined by the decompression module determination unit 12 and loads them into the memory of the integrated gateway 10. 10 environment settings are made. When an error occurs during environment setting, the error notification unit 14 notifies a worker or the like of the occurrence, contents, and the like of the error. The control unit 15 performs overall control in the integrated gateway 10 in cooperation with the above-described components 11 to 14.

  By the way, in the present embodiment, the environment setting is performed for the integrated gateway 10 by loading the functional module into the memory of the integrated gateway 10. Each functional module to be loaded is prepared for each equipment controller as illustrated in FIG. The function modules are roughly classified into basic function modules and additional function modules. The basic function module is a function module for realizing a function essential for remote management of equipment in the remote management center 3. The additional function module is a function module other than the basic function module, and is a function module for realizing additional functions, services, and the like for remote management of equipment in the remote management center 3.

  The compression module storage unit 17 is provided as a compression module storage unit, and stores the basic function module and the additional function module constituting the function module prepared for each equipment controller in a compressed state. 4 shows the relationship between the memory (RAM 23) and the functional modules stored in the HDD 24. In the compression module storage unit 17 realized by the HDD 24, functional modules corresponding to the respective equipment controllers 4 are stored. The compressed version is stored. A function module (compressed version) suitable for remote management of each equipment is also prepared.

  FIG. 5 is a diagram showing a data configuration example of the priority information of the equipment controller 4 stored in the device priority information storage unit 18 in the present embodiment. As illustrated in FIG. 5, the priority order of the facility controllers 4 is set in the priority order information. The integrated gateway 10 installed in each building has a device priority information storage unit 18, but the priority of the equipment controller 4 set in the device priority information need not necessarily match in each building 1. Absent.

  FIG. 6 is a diagram showing a data configuration example of the functional module information stored in the functional module information storage unit 19 in the present embodiment. The functional module information storage unit 19 is provided as priority order information storage means, and stores at least priority order information of the additional function modules set for each equipment controller. The functional module information is generated for each equipment controller 4. As illustrated in FIG. 6, the functional module information includes a type, a function, a version, a size (after decompression), and a required capacity for each point in addition to the priority corresponding to the priority information for each functional module. Among these, “type” is set to indicate whether the function module is a basic function module or an additional function module. In “function”, a function name is set as information for identifying the function module. In “Priority”, the priority of the functional module is set. In this embodiment, since no priority order is set for the basic function module, “−” indicating no setting is indicated, but “1” indicating the highest priority is set for all basic function modules and added. Priorities after “2” may be set for the functional modules. In “Version”, the version of the function module is set. In the function module for which a plurality of versions are prepared such as “communication protocol conversion”, the following size (after decompression) and the required capacity for each point are set for each version. Each functional module is stored in the compressed module storage unit 17 in a compressed state, and “size (after decompression)” is set to a file size when the functional module of that version is decompressed.

  By the way, the equipment controller 4 connects one or several equipment, and performs each control and management. This connected equipment is also referred to as a “management point”. The facility controller 4 collects data from each facility device at a predetermined time interval such as periodically or in real time. For example, in the case of an air conditioner, information such as a set temperature, a measured temperature, and an operation type (cooling or heating) is periodically received from each air conditioner. The received data is temporarily stored in the memory, and the memory usage required for one facility device to hold the data is referred to as “required capacity for each point”. The “size (after decompression)” and “required capacity for each point” are used when calculating the memory usage when the functional module is loaded into the memory.

  Each component 11-15 in the integrated gateway 10 is implement | achieved by cooperation operation | movement of the program mounted on the computer mounted in the integrated gateway 10, and CPU21 mounted in the computer. The storage units 17 to 19 are realized by the HDD 24 of the integrated gateway 10.

  In addition, the program used in this embodiment is provided by connecting a management terminal, provided by communication means, or stored in a computer-readable recording medium such as a CD-ROM or DVD-ROM. It is also possible to do. In this case, an external disk device or the like is used. The program provided from the communication means or the recording medium is installed in the computer, and various processes are realized by the CPU of the computer sequentially executing the program.

  Next, the operation in this embodiment will be described. Here, the case where the integrated gateway 10 is newly installed in the building 1 will be described. Since the present embodiment has a feature in the processing for setting the environment of the integrated gateway 10, it is assumed that the hardware setting and the network connection shown in FIG. 1 have been completed.

  In the integrated gateway 10, it is necessary to prepare functional modules for realizing various processing functions in the latest version from the past, compress them, and store them in the compressed module storage unit 17 in advance. That is, various function modules are stored in the integrated gateway 10 so that it can respond to various equipment controllers 4 and equipment. However, if all the functional modules are stored, a huge disk capacity may be required. In this embodiment, the functional modules are stored in a compressed state.

  The worker connects the management terminal to be carried to the integrated gateway 10 and operates the management terminal to start the environment setting of the integrated gateway 10. In this environment setting, installation is performed by determining a functional module corresponding to the connection status of the equipment controller 4 and the equipment from the functional modules stored in advance in the compression module storage unit 17, and decompressing and loading it into the memory. Work is the main processing content. Here, the decompression module determination process for determining the functional module to be decompressed for loading into the memory will be described with reference to the flowchart shown in FIG.

  When the environment setting processing function in the integrated gateway 10 is activated according to the operation of the worker, the equipment related information acquisition unit 11 specifies the equipment controller 4 connected to the integrated gateway 10 (step 101). In this case, the equipment related information acquisition unit 11 may automatically detect the equipment controller 4 or may receive the identification information of the equipment controller 4 input by a worker. In the case of automatic detection, the facility-related information acquisition unit 11 may send a predetermined detection signal to the building network 5 and recognize the facility controller 4 that responds to this detection signal.

  Subsequently, the facility-related information acquisition unit 11 acquires the number of management points of each facility controller 4, that is, the number of facility devices connected to each facility controller 4, and the type of each facility device (step 102). This may be acquired by inquiring the equipment related information acquisition unit 11 to the equipment controller 4, or may receive the number of management points input by the worker. For automatic identification of the type of equipment, a method described in a patent application (Japanese Patent Application No. 2011-244546) by the same applicant as the present application may be used.

  Furthermore, the equipment related information acquisition unit 11 determines the version of each functional module to be installed in the integrated gateway 10 (step 103). In this case, the facility-related information acquisition unit 11 may automatically determine a version that can correspond to the type of facility device, or may accept a version input by a worker.

  In the present embodiment, the function module to be decompressed is selected from the function modules stored in advance in the compression module storage unit 17, but when a new version of the function module is created, etc. During the above process or prior to the decompression module determination process, the latest version of the function module may be registered in the compression module storage unit 17. At this time, the function module information set in the function module information storage unit 19 and the device priority information set in the device priority information storage unit 18 are updated together as necessary.

  When various information is acquired as described above, the decompression module determination unit 12 determines a functional module to be decompressed as follows.

  First, the memory capacity required for loading the functional module into the memory is calculated for each functional module. In the case of the equipment controller A illustrated in FIG. 6, the required memory capacity is calculated for each functional module such as communication protocol conversion, alarm output, and demand output (step 104). For example, when five equipment devices are connected to the equipment controller A, the memory capacity required for loading the functional module of the communication protocol conversion V1.1 of the equipment controller A is 640 KB and 5 of the functional module body. It is calculated to be 655.5 KB, which is a total of 5.5 KB (= 1.1 KB × 5 units) required capacity for each point of equipment equipment.

  When the memory capacity required for loading each functional module is calculated for all the facility controllers 4, it is determined whether or not loading is possible when all functional modules that are candidates for loading are loaded into the memory. That is, when the required memory capacity obtained by adding all the memory capacities necessary for loading the functional modules is less than or equal to the actual memory capacity (N in Step 105), it is determined that all the functional modules can be loaded, All the relevant functional modules are determined as decompression targets (step 106). Note that the actual memory capacity in the present embodiment is the size of the RAM 23. Strictly speaking, the memory capacity of the RAM 23 used by memory resident software such as the OS is subtracted from the memory capacity of the RAM 23. The storage capacity of the RAM 23 that can be used by the functional module. The actual memory capacity may be acquired from the current usage status of the RAM 23 or may be a memory capacity designated by an operator. Memory capacity and storage capacity are synonymous.

  On the other hand, if the required memory capacity exceeds the actual memory capacity (Y in step 105), all the function modules cannot be loaded. Therefore, the function module to be decompressed for loading from all the function modules as follows. Is selected. As will be apparent from the following description, the above-described steps 105 and 106 can determine a functional module to be decompressed in addition to this processing.

  First, basic function modules essential for remote management of equipment must be loaded into a memory and made available. Accordingly, the basic function module is extracted with reference to the function module information, and the memory capacity required for loading all the basic function modules is calculated (step 107). According to the function module information illustrated in FIG. 6, the necessary memory capacity is calculated by adding the memory capacity necessary to operate each of the communication protocol conversion function V1.1 and the alarm output function V1.0.

  If the required memory capacity exceeds the actual memory capacity (Y in step 108), even the basic function module essential for remote management cannot be loaded, so it is determined that an abnormality has occurred and predetermined error processing is executed (step 109). In the case of the present embodiment, when detecting the occurrence of an abnormality, the control unit 15 activates the error notification unit 14 and executes error processing such as displaying the fact on the management terminal.

  On the other hand, if the required memory capacity is less than or equal to the actual memory capacity (N in step 108), the decompression module determination unit 12 determines that the memory capacity is still sufficient and selects an additional function module to be loaded together with the basic function module. (Step 110). For this selection, the priority set in the device priority information and the functional module information is used.

  Here, it is assumed that only the equipment controller A and the equipment controller B are connected to the building 1. Referring to the device priority information illustrated in FIG. 5, it can be seen that the priority of the equipment controller A is higher than that of the equipment controller B. Therefore, the additional function module to be selected is preferentially selected from the equipment controller A. Subsequently, referring to the function module information illustrated in FIG. 6, it can be seen that the priority order of the demand output function is the highest among the additional function modules. Thereby, the decompression module determination unit 12 adds the memory capacity necessary for the demand output function to the memory capacity necessary for the basic function module calculated in Step 107, and calculates the memory capacity necessary at this time. If the calculated memory capacity is less than or equal to the actual memory capacity (Y in step 111), it is determined that the additional function module can be further loaded, and the process returns to step 110 to select a new additional function module to be loaded. As the additional function module having the next highest priority, the second highest priority additional function module in the equipment controller A may be selected, or in the second highest priority equipment controller B. An additional function module with the second highest priority may be selected. This selection rule may follow a predetermined rule, or may follow an instruction input by an operator.

  By repeating the processing in steps 110 and 111, the total memory capacity of the basic function module and the selected additional function module will eventually exceed the actual memory capacity. In this case (N in step 111), the last selection is made. Since the actual memory capacity has been exceeded by adding the added additional function modules, the last selected additional function module is excluded from the decompression candidates (step 112). In this manner, the decompression module determination unit 12 determines the basic function module and the selected additional function module as the decompression target (step 113).

  When the functional module to be decompressed and loaded into the memory is determined as described above, the environment setting unit 13 extracts the functional module to be decompressed from the compression module storage unit 17, decompresses it, and loads it into the memory. An image of the decompression and loading process is shown in FIG.

  In the above description, the case where the integrated gateway 10 is newly installed in the building 1 has been described. However, the environment setting for the installed integrated gateway 10 to be performed when the connection form such as increase / decrease of equipment is changed is described. What is necessary is just to carry out similarly to the above.

  According to the present embodiment, the used capacity of the HDD 24 mounted on the integrated gateway 10 is suppressed as much as possible by compressing and storing the functional modules. At the time of environment setting, the essential basic function module is decompressed and set to a usable state, and the additional function module is decompressed and loaded in accordance with the priority order in consideration of the memory capacity of the integrated gateway 10. did. As a result, remote management of facility equipment can be performed in the same manner as in the past even if a gateway is provided for each facility controller in the past, but the gateway is integrated into one integrated gateway 10 for each facility. Will be able to.

  In this embodiment, the management terminal is connected and the management terminal issues an environment setting instruction to the integrated gateway 10. For example, the integrated gateway 10 is provided with an environment setting start button and the like. The environment setting may be automatically performed by operating.

  In the present embodiment, the management terminal is mainly used as the user interface means of the integrated gateway 10. For example, software that implements the equipment related information acquisition unit 11, the decompression module determination unit 12, and the error notification unit 14 Further, each storage unit 18 and functional module information storage unit 19 may be provided on the management terminal side, and the integrated gateway 10 may be configured to decompress the functional module instructed from the management terminal and load it into the memory. Alternatively, the functional module itself to be decompressed may be received from the management terminal side.

  1 building, 2 network, 3 remote management center, 4 equipment controller, 5 in-building network, 10 integrated gateway, 11 equipment related information acquisition section, 12 decompression module determination section, 13 environment setting section, 14 error notification section, 15 control section , 17 Compression module storage unit, 18 Device priority order information storage unit, 19 Functional module information storage unit, 21 CPU, 22 ROM, 23 RAM, 24 Hard disk drive (HDD), 25 HDD controller, 26 Network controller, 27 Internal bus.

Claims (4)

A management center for remotely managing one or more equipment installed in each facility;
One or more equipment controllers that control one or more equipment installed and connected to each facility;
A gateway device that relays information that is installed in each facility and communicated via the network between the equipment and the management center;
Have
A basic function module that realizes a function essential for remote management in the management center and an additional function module that realizes an additional function, which constitute a function module prepared for each equipment controller, are stored in a compressed state. Compression module storage means for
Priority order information storage means for storing at least priority order information indicating the priority order of the additional function module set for each facility controller;
Equipment-related information acquisition means for acquiring equipment-related information related to equipment installed in the facility;
From the relationship between the memory capacity of the gateway device and the module size after decompression of each functional module corresponding to the equipment installed in the facility, the equipment installed in the facility according to the priority set in the priority information Decompression module determination means for determining an additional function module to be decompressed together with the basic function module corresponding to the device and loaded into the memory of the gateway device;
Environment setting means for setting the environment of the gateway device by decompressing the basic function module corresponding to the equipment controller and the additional function module determined by the decompression module determining means and loading it into the memory of the gateway device;
A remote management system comprising:   2. The remote management system according to claim 1, wherein the priority order information further includes setting information of priority order of the connected equipment controllers. The equipment-related information includes at least the number of the equipment that is controlled by the equipment controller.
The remote management system according to claim 1, wherein the decompression module determination unit calculates a module size after decompression of each functional module with reference to the number of the facility devices included in the facility device related information. . Information that is communicated via a network between one or a plurality of equipment controllers that control one or a plurality of equipment installed in a facility, and a management center that remotely manages the equipment and equipment In the gateway device that relays
A basic function module that realizes a function essential for remote management in the management center and an additional function module that realizes an additional function, which constitute a function module prepared for each equipment controller, are stored in a compressed state. Compression module storage means for
Priority order information storage means for storing at least priority order information indicating the priority order of the additional function module set for each facility controller;
Equipment-related information acquisition means for acquiring equipment-related information related to equipment installed in the facility;
From the relationship between the memory capacity of the gateway device and the module size after decompression of each functional module corresponding to the equipment installed in the facility, the equipment installed in the facility according to the priority set in the priority information When the additional function module to be decompressed together with the basic function module corresponding to the device and loaded into the memory of the gateway device is determined,
Environment setting means for setting the environment of the gateway device by decompressing the basic function module corresponding to the equipment controller and the additional function module determined by the decompression module determining means and loading it into the memory of the gateway device;
A gateway device comprising:

Images