WO2018056436A1 - Gas supply management system, gas supply management method, and information transmission device - Google Patents

Gas supply management system, gas supply management method, and information transmission device Download PDF

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Publication number
WO2018056436A1
WO2018056436A1 PCT/JP2017/034479 JP2017034479W WO2018056436A1 WO 2018056436 A1 WO2018056436 A1 WO 2018056436A1 JP 2017034479 W JP2017034479 W JP 2017034479W WO 2018056436 A1 WO2018056436 A1 WO 2018056436A1
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WO
WIPO (PCT)
Prior art keywords
gas
information
delivery
date
usage
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PCT/JP2017/034479
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French (fr)
Japanese (ja)
Inventor
近藤 敦
敬 永沼
高橋 潤
Original Assignee
株式会社ミツウロコクリエイティブソリューションズ
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Priority to JP2018503809A priority Critical patent/JP6364571B1/en
Publication of WO2018056436A1 publication Critical patent/WO2018056436A1/en

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    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06QINFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES; SYSTEMS OR METHODS SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES, NOT OTHERWISE PROVIDED FOR
    • G06Q10/00Administration; Management
    • G06Q10/08Logistics, e.g. warehousing, loading or distribution; Inventory or stock management
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06QINFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES; SYSTEMS OR METHODS SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES, NOT OTHERWISE PROVIDED FOR
    • G06Q50/00Information and communication technology [ICT] specially adapted for implementation of business processes of specific business sectors, e.g. utilities or tourism
    • G06Q50/06Energy or water supply
    • GPHYSICS
    • G08SIGNALLING
    • G08CTRANSMISSION SYSTEMS FOR MEASURED VALUES, CONTROL OR SIMILAR SIGNALS
    • G08C15/00Arrangements characterised by the use of multiplexing for the transmission of a plurality of signals over a common path
    • GPHYSICS
    • G08SIGNALLING
    • G08CTRANSMISSION SYSTEMS FOR MEASURED VALUES, CONTROL OR SIMILAR SIGNALS
    • G08C17/00Arrangements for transmitting signals characterised by the use of a wireless electrical link
    • G08C17/02Arrangements for transmitting signals characterised by the use of a wireless electrical link using a radio link
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y04INFORMATION OR COMMUNICATION TECHNOLOGIES HAVING AN IMPACT ON OTHER TECHNOLOGY AREAS
    • Y04SSYSTEMS INTEGRATING TECHNOLOGIES RELATED TO POWER NETWORK OPERATION, COMMUNICATION OR INFORMATION TECHNOLOGIES FOR IMPROVING THE ELECTRICAL POWER GENERATION, TRANSMISSION, DISTRIBUTION, MANAGEMENT OR USAGE, i.e. SMART GRIDS
    • Y04S10/00Systems supporting electrical power generation, transmission or distribution
    • Y04S10/50Systems or methods supporting the power network operation or management, involving a certain degree of interaction with the load-side end user applications

Definitions

  • the present invention relates to a gas supply system, a gas supply method, and an information transmission device for efficiently performing meter reading and delivery of liquefied petroleum (LP) gas.
  • LP liquefied petroleum
  • a communication transmission unit (NCU) is connected to a gas meter, and a communication line is connected.
  • NCU communication transmission unit
  • a system that detects a remaining amount of gas in an LP gas cylinder and collects a charge by connecting to a centralized management apparatus via the terminal (for example, see Patent Document 1).
  • a drive power source of a communication device for example, the above-mentioned transmission device or device such as a gas smart meter
  • a communication device for example, the above-mentioned transmission device or device such as a gas smart meter
  • Electrical work to ensure and connection work with the communication device or communication line is essential, and the cost is compared with the labor cost for periodic manual inspection (eg once a month). Can be expensive.
  • the labor cost is increased.
  • the LP gas meter does not have a power source for uploading information to the network.
  • the location of the LP gas meter is within a predetermined range (region) when viewed by each LP gas company. Even if there is, it is scattered without being crowded, and it is difficult to relate information between LP gas meters.
  • the owner of the LP gas meter (LP gas supplier) is in a predetermined range (region), for example. Even if it is a customer, there may be differences, and there is a problem such as the lack of an external infrastructure to realize communication for comprehensively acquiring information of a predetermined range (region) or all customers. It is not progressing.
  • the expiration date of the LP gas meter is 10 years from the date of manufacture, and it depends on the management resources and business scale of the LP gas company. In some cases, investment in LP gas meters is reluctant, and it is difficult to replace LP gas meters in a batch.
  • the present invention has been made in view of the above problems, and can efficiently perform operations such as meter reading, security, and delivery, and can reduce costs and labor related to introduction, a gas supply management system, and gas supply management It is an object to provide a method and an information transmission apparatus.
  • the present invention is a gas supply management system comprising an information transmission means, a collection means, and a management means, wherein the information transmission means is connected to gas meters corresponding to gas containers of a plurality of supply destination facilities, Information from the gas meter is acquired and transmitted to the collecting means, the collecting means collects the information transmitted from the information transmitting means, and the managing means includes a usage calculating means, a delivery predicting means, The information collected by the collection means is acquired via a network, and based on the information, the usage calculation means calculates and outputs the gas usage for each gas container, and the delivery prediction
  • the gas supply management system according to claim 1, wherein a scheduled delivery date of the gas container is predicted for each supply destination facility by means.
  • the present invention is also a gas supply management method using an information transmission means, a collection means, and a management means, wherein the gas meter is connected to a gas meter corresponding to a gas container of a plurality of supply destination facilities, respectively. Acquiring the information from the transmission means and transmitting the information to the collection means, and the management means obtains the information collected by the collection means via a network, and uses the gas for each gas container based on the information.
  • a gas supply management method comprising: calculating and outputting an amount; and predicting a next delivery date of the gas container for each supply destination facility based on the information. is there.
  • the present invention is a program characterized by causing a computer to execute the above gas supply management method.
  • the present invention provides a replaceable battery, a connection unit connected to each external terminal of a gas meter corresponding to a gas container of a plurality of supply destination facilities, an acquisition unit for acquiring information from the gas meter, and the information And a communication unit capable of transmitting to the collection device via the network.
  • a gas supply management system a gas supply management method, and information transmission that can efficiently perform operations such as meter reading, security, and delivery and can reduce costs and labor related to introduction can be reduced.
  • An apparatus can be provided.
  • FIG. 1 It is a schematic diagram showing typically the composition of the gas supply management system concerning one embodiment of the present invention.
  • BRIEF DESCRIPTION OF THE DRAWINGS It is a figure explaining the information transmitter which concerns on one Embodiment of this invention, (a) The schematic which shows typically the structure of an information transmitter, (b) The block diagram which shows the structure of an information transmitter, (c) It is a block diagram which shows the function of an information transmitter. It is a figure explaining the portable terminal which concerns on one Embodiment of this invention, (a) The block diagram which shows the structure of a portable terminal, (b) The block diagram which shows the function of a portable terminal.
  • FIG. 1 It is a figure which shows an example of the display of the geographic information display means which concerns on one Embodiment of this invention. It is a figure which shows an example of (a) usage-amount data which concerns on one Embodiment of this invention, (b) It is a figure which shows an example of delivery prediction data. It is a schematic diagram showing typically the composition of the gas supply management system concerning one embodiment of the present invention. It is a figure explaining the management apparatus which concerns on one Embodiment of this invention, (a) The schematic diagram which shows typically the structure of a management apparatus, (b) The block diagram which shows the function of a management apparatus. It is a schematic diagram which shows an example of the process in the delivery management means and portable terminal which concerns on one Embodiment of this invention.
  • FIG. 1 is a schematic diagram schematically illustrating the configuration of the gas supply management system 10 of the present embodiment
  • FIG. 2A is a schematic diagram schematically illustrating the configuration of the information transmission unit 11 of the present embodiment
  • FIG. 2B is a block diagram showing a configuration of the information transmission unit 11
  • FIG. 2C is a block diagram showing a function of the information transmission unit 11.
  • the gas supply management system 10 displays information from the LP gas meters 21 respectively provided in a plurality of liquefied petroleum (LP) gas supply destination facilities U at a frequency higher than monthly (for example, in one month). By collecting at a frequency that is higher (more frequent) than once a week or once a week, LP gas meter reading, security, delivery, etc. are performed efficiently.
  • Information transmitting means (information transmitting device) 11 that connects and acquires information from each LP gas meter 21, and a plurality of portable terminals 12 that are communicably connected to information transmitting device 11 via network (communication line) NW1
  • a management means (management device) 13 connected to the network NW1, and a provider server device 14 connected to the management device 13 via the network NW2.
  • the supply facility U is, for example, an LP gas installation facility provided in or near the site of a residential facility (a detached house, an apartment house, an office, etc.) of an LP gas contractor. This is where the gas is installed.
  • the network NW1 to which the portable terminal 12, the information transmission device 11, and the management device 13 are connected is, for example, a wireless mobile communication network (including a base station) or a wireless data communication network using a wireless LAN system such as WiFi (registered trademark).
  • a wireless data communication network based on a short-range wireless communication standard (a wireless PAN system such as Bluetooth (registered trademark)), a wireless MAN system such as WiMAX (registered trademark), a wireless data communication network based on a wireless WAN system, etc.
  • the network NW2 to which the device 13 and the server device for business 14 are connected is a communication line constructed by, for example, a LAN, the Internet, or a dedicated communication line (for example, a CATV (Community Antenna Television) line) and a gateway.
  • the network NW2 only needs to be a line that can communicate with each other, and the form of communication may be wired or wireless.
  • the information transmitting apparatus 11 is connected to LP gas meters 21 corresponding to the gas containers (gas cylinders) 20 arranged in a plurality of LP gas supply destination facilities U, It is a device that acquires information from the LP gas meter 21 (hereinafter referred to as gas meter information) and transmits it to the portable terminal 12.
  • the information transmission device 11 is attached to, for example, an LP gas supply pipe 25, and is connected to an external terminal 22 of each LP gas meter 21 via a wired connection means 23.
  • the “gas meter information” refers to a unique number (for example, a production number) that can identify each LP gas meter 21 (gas cylinder 20), a guideline value indicating the amount of gas used for each gas cylinder 20 in a predetermined period, and security information. (Information for monitoring the pressure of each gas cylinder 20 and detecting gas leakage and the like) and information including at least the acquisition date (meter reading date) of these pieces of information.
  • the information transmission device 11 uses a built-in battery (a rechargeable battery (such as a lithium ion battery) that can be exchanged together with the LP gas meter) 114 as a power source, and controls the entire information transmission device 11 stored in the memory 116 by the control unit 115. Processing for executing various software programs for realizing the operation, processing for transferring control signals and data, and the like are performed.
  • a built-in battery a rechargeable battery (such as a lithium ion battery) that can be exchanged together with the LP gas meter) 114 as a power source
  • the memory 116 stores a software program for performing an information transmission process, and the information transmission apparatus 11 executes the information transmission process by executing the program.
  • the information transmission apparatus 11 includes an information transmission request receiving unit 117 that receives an information transmission request from the portable terminal 12, and an individual information transmission unit 118 that transmits gas meter information for each LP gas meter to the portable terminal 12. (C) in FIG.
  • Information transmission request reception means (information transmission request reception processing) 117 receives information transmission requests from the mobile terminal 12 periodically (for example, once every 30 seconds) via the communication unit 113. That is, for example, in the information transmission apparatus 11, the standby mode in which the information transmission request reception unit 117 does not function and the reception mode in which the information transmission request reception unit 11 functions periodically switch automatically. That is, the information transmission request receiving unit 11 functions periodically. Further, the individual information transmission means (individual information transmission processing) 118 acquires the gas meter information from the LP gas meter 21 via the connection unit 111 when the information transmission request reception means 117 receives the information transmission request, or Gas meter information that is periodically acquired in advance and stored in the memory 116 or the like is transmitted (wireless transmission) to the mobile terminal 12 via the network NW.
  • FIG. 2A is a block diagram showing the configuration of the mobile terminal 12
  • FIG. 2B is a block diagram showing the function of the mobile terminal 12.
  • the portable terminal 12 is a terminal device carried by a meter reader (meter meter) of the LP gas meter 21, a deliverer of the gas cylinder 20, or a person in charge of the LP gas supply source, or the gas cylinder 20 Is a terminal device attached to a delivery vehicle or the like capable of mobile communication, receives and collects gas meter information transmitted from the information transmitting device 11, and transmits the gas meter information to the management device 13 via the network NW1. (Upload).
  • the mobile terminal 12 is preferably a conventionally known smartphone, tablet terminal, PDA (Personal Digital Assistant), etc., but can also be realized by a notebook computer, a handy terminal (dedicated terminal) capable of mobile communication, a mobile phone, etc. can do.
  • “supplier” of LP gas refers to LP gas contractors (consumers) such as LP gas companies, branches of each LP gas company, filling stations, distribution centers, retailers, etc. It is a general term for those who supply LP gas.
  • the portable terminal 12 includes a CPU (control unit) 120, a display unit (display unit, display) 121, an input unit 122, a memory 123, a communication unit 124, and the like.
  • the input means 122 is a general term for means for inputting information such as characters, images, and voices to the mobile terminal 12, and includes, for example, a keyboard (touch panel) for inputting characters, a camera that captures an object and inputs (stores) it as an image, A microphone for inputting (storing) audio.
  • the CPU 120 performs processing for executing various software programs (application programs), operating systems (OS), etc. for realizing the operation of the entire mobile terminal 13 stored in the memory 123, and data necessary for executing the programs. And processing for storing the file and the like in the memory 123 and the like.
  • application programs application programs
  • OS operating systems
  • the communication unit 124 communicates with the information transmission apparatus 11 and the management apparatus 13 via the network NW1.
  • the memory 123 stores a software program (application program) for performing information collection processing and the like, and the portable terminal 12 executes information collection processing by executing the program.
  • This information collection process includes a geographic information display process, an information transmission request process, and an information acceptance transmission process, whereby the portable terminal 12 can receive the geographic information display means 127, the information transmission request means 128, and the information acceptance transmission means.
  • the function as 129 or the like is realized ((b) in the figure).
  • the geographic information display means (geographic information display processing) 127 is an application program that implements a so-called mapping system that displays at least the position information of the gas cylinder 20 (and gas pipes) on the electronic map (processing executed thereby). It is. An electronic map within a predetermined range (distance) centered on the position of the mobile terminal 12 and the same supplier (for example, an LP gas company (or its branch or retailer) etc. are present by the geographical information display means 127. )) Possessed (consumer who has contracted with the same gas company), the position information of the gas cylinder 20 can be grasped.
  • the geographic information display means 127 causes a predetermined range (for example, a radius of about 200 m to 300 m centering on the information acquisition point) from the information acquisition point. And the position of the gas cylinder 20 (LP gas meter 21) as the metering target of the same supply source existing within the range can be displayed on the display means 121 of the portable terminal 12.
  • the information transmission request means (information transmission request processing) 128 is a period longer than a predetermined period (in this example, the reception cycle of the information transmission request reception means 117 (30 seconds in this example)) with respect to the information transmission apparatus 11 (for example, 1 )),
  • the information transmission request is transmitted, the gas meter information transmitted from the information transmission device 11 is received, and the location information of the gas cylinder 20 (supplier facility) is associated with the management device 13.
  • the gas meter information is transmitted.
  • the geographic information display unit 127 displays an electronic map within the predetermined range from the information acquisition point and the range within that range.
  • the position of the gas cylinder 20 (LP gas meter 21) that is the target of meter reading from the same supply source is displayed on the display means 121 of the portable terminal 12. Then, the information transmission device 11 connected to all the LP gas meters 21 displayed on the display unit 121 transmits the gas meter information to the portable terminal 12.
  • the portable terminal 12 links
  • the gas meter information of the same LP gas meter 21 is transmitted from the portable terminal 12 on the same day, the information of the management device 13 is overwritten (updated) with the latest gas meter information.
  • the geographic information display unit 127 is configured to be able to display on the display unit 121 whether or not the acquisition of the gas meter information for each target LP gas meter 21 is successful. Thereby, the carry person of the portable terminal 12 can grasp
  • the person carrying the portable terminal 12 transmits an information transmission request again by moving from the information acquisition point as necessary to reacquire the gas meter information. Try.
  • the information acceptance / transmission means 129 is an application program for accepting an input of gas meter information by a person (user) of the portable terminal 12 and transmitting the gas meter information to the management device 13.
  • the information reception / transmission means (information reception / transmission process) 129 displays, for example, the position information (a map, an address, etc.) of the LP gas meter 21 on which the gas meter information could not be acquired on the display means 121 of the portable terminal 12. Based on the position information, the user of the mobile terminal 12 goes to the location of the LP gas meter 21 where the gas meter information could not be acquired. For example, the user of the mobile terminal 12 photographs the LP gas meter 21 with the camera (input means 122) of the mobile terminal 12 The image data is input to the acceptance transmission means 129.
  • the position information a map, an address, etc.
  • the information reception / transmission means 129 character-recognizes the unique number of the LP gas meter 21, a guideline value indicating the amount of gas used, and security information from the input image data of the LP gas meter 21, and displays the character information and geographic information.
  • the position information acquired from the means 127 is linked and stored in the memory 123 of the portable terminal 12 as gas meter information together with the acquisition date (meter reading date) of the gas meter information.
  • the information reception / transmission unit 129 inputs character information such as a unique number of the LP gas meter 21, a guideline value indicating the amount of gas used, and security information by operating the touch panel (input unit 122) of the portable terminal 12 of the carry person.
  • the information reception / transmission means 129 associates the gas meter information with the position information of the LP gas meter 21 acquired from the geographical information display means 127, and together with the acquisition date (the meter reading date) of the gas meter information, the network NW1 (for example, a wireless mobile object)
  • NW1 for example, a wireless mobile object
  • the gas meter information cannot be acquired by the mobile terminal 12.
  • This problem also occurs in the smart meter.
  • the gas meter information is acquired by the auxiliary information reception / transmission means 129, and the management device 13 receives the gas meter information. Information can be sent.
  • the information reception / transmission means 129 is configured to acquire the gas meter information from the image data of the LP gas meter 21 photographed by the camera of the portable terminal 12, evidence of meter reading execution can be left.
  • the information transmission device 11 including the battery (rechargeable battery) 114 and including the communication unit 113 that performs wireless communication with the mobile terminal 12 to the existing LP gas meter 21
  • the gas meter information of the LP gas meter 21 can be transmitted to the mobile terminal 12 and transmitted from the mobile terminal 12 to the management device 13 in real time.
  • gas meter information can be automatically acquired when needed using the existing LP gas meter 11 which does not have a permanent communication power supply.
  • the mobile terminal 12 transmits an information transmission request for a predetermined period (for example, 1 minute) at an arbitrary timing, and the information transmission apparatus 11 performs an information transmission request process for receiving the information transmission request from the mobile terminal 12. By performing it periodically (for example, once every 30 seconds), power consumption of the information transmitting apparatus 11 can be minimized.
  • FIG. 2A is a block diagram showing the configuration of the management means 13
  • FIG. 2B is a block diagram showing the function of the management means 13
  • FIG. 2C is managed by the management apparatus 13.
  • FIG. It is a schematic diagram which shows an example of information (gas meter management information).
  • the management device 13 is connected to the mobile terminal 12 via a network NW1 such as a mobile communication line, and connects the operator server 14 to a network NW2 such as the Internet or a dedicated line.
  • a server device or a personal computer (PC) is connected via the CPU 130, ROM 131, RAM 132, storage means (storage device) 133, input means 134, display means 135, communication means 136, and the like.
  • the CPU 130 executes various software programs (application programs), operating systems (OS), and the like for realizing the operation of the entire management apparatus 13 stored in the ROM 131, the storage device 133, and the like, and executes the programs. Processing for storing necessary data, files, and the like in the RAM 132, the storage device 133, and the like is performed.
  • application programs application programs
  • OS operating systems
  • the storage device 133 stores an application program, an OS, a control program, a related program, and the like, and can be realized by, for example, a hard disk (HDD).
  • the input unit 134 can be realized by, for example, a keyboard, a pointing device (such as a mouse), a touch panel, or the like.
  • the display unit 135 displays, for example, a response output in response to an input from the input unit 134, and can be realized by, for example, a liquid crystal display device, a plasma display, or the like.
  • This gas supply management process includes a usage amount calculation process, a delivery prediction process, a geographic information display process, and the like, whereby the management apparatus 13 uses the usage amount calculation means 137, the delivery prediction means 138, and the geographic information display means.
  • the function 139 is realized ((b) in the figure).
  • the software program may be stored in a computer-readable information storage medium such as a DVD-ROM or CD-ROM. Further, a database is provided in the storage device 133, and the gas meter information and the positional information of the LP gas meter 21 are stored in association with each other.
  • the communication means 136 communicates with the portable terminal 12 via the network NW1, and also communicates with the business server device 14 via the network NW2.
  • the provider (supplier) server device 14 is a known server device, and has the same CPU, ROM, RAM, storage means, input means, display means, communication means (all not shown) and the like as the management device 13.
  • the storage means has information that can be accessed only by a specific operator (who has a specific authority) (for example, personal information of a contractor (consumer) of the LP gas meter 21 (LP gas), etc.) ) Is stored.
  • the gas meter management information is stored in the database of the management device 13.
  • the gas meter management information includes gas meter information (and positional information of the LP gas meter 21) as shown in FIG. 5C, while personal information of a contractor (consumer) of the LP gas meter 21 is included. Absent.
  • the personal information of the LP gas contractor (consumer) corresponds to the gas meter information of the management device 13 by acquiring it from the server device 14 for business operators as necessary (for example, by a delivery prediction means 138 described later). Attached.
  • the portable terminal 13 carried by the meter reader or the delivery person is configured so that personal information of the LP gas contractor cannot be held (stored or displayed).
  • the portable terminal 13 is configured so that the personal information of the LP gas contractor cannot be stored (stored or displayed), and is associated with the position information in the management device 13.
  • the personal information of the contractor (consumer) of the LP gas meter 21 may be held.
  • the portable terminal 12 cannot acquire the gas meter information (when it is necessary to acquire the gas meter information by the information reception / transmission means 129 of the portable terminal 12), only the target LP gas meter 21 has the contract.
  • the person name or the like may be acquired from the management apparatus 13 or may be acquired from the business server apparatus 14 via the management apparatus 13 and temporarily displayed.
  • the management device 13 manages only information related to a single supply source (for example, each LP gas company, a branch of each LP gas company, a filling station, a delivery center, a retailer, etc.) as the gas meter management information.
  • the information regarding a some supply source may be managed for every supply source.
  • a plurality of the management devices 13 shown in FIG. 1 may be provided for each supplier, One or a plurality of management devices 13 may manage information regarding a plurality of suppliers for each supplier.
  • the operator server device 14 is contracted by each operator (who has specific authority). One or more are provided so that only the information of the person can be accessed.
  • FIG. 4C is an example of gas meter management information held by one management apparatus 13 and shows an example in which information on a plurality of supply sources (for example, LP gas companies) is managed for each supply source.
  • FIG. 4C is an example of gas meter management information held by one management apparatus 13 and shows an example in which information on a plurality of supply sources (for example, LP gas companies) is managed for each supply source.
  • the management device 13 has a gas meter management information in which a unique number of LP gas held by each supply source is associated with each of a plurality of supply sources (for example, LP gas companies).
  • Database is held (information other than the unique number may be included).
  • Each supplier is identified by a supplier identification number.
  • the server 14 (14A, 14B, 14C%)
  • For the provider is provided, for example, for each LP gas company (or other supply source such as a branch). Holds personal information only for contractors contracted by business operators (only in-house contractors).
  • the management device 13 causes the LP gas unique number linked to the supplier identification number of the business to be downloaded. Thereby, each LP gas company can acquire the unique number of LP gas only for its own contractor. Then, each LP gas company acquires personal information corresponding to each unique number from its own company server device 14 based on the acquired unique number.
  • the management device 13 uses the supplier identification number “ID01” as a key.
  • the business server 14A is permitted to download the corresponding unique numbers (in this example, “0001” to “0004”) of a plurality of corresponding LP gases.
  • the LP gas company A can acquire the unique number of the LP gas only for its own contractor, and acquires personal information corresponding to each unique number from its own company server device 14A based on the unique number.
  • the unique numbers of the corresponding LP gases using the supplier identification number “ID02” as a key (In this example, “0005”, “0006”%) Is downloaded to the business server 14B, and the business server owned by the LP gas business C (supplier identification number “ID03”).
  • the provider server downloads the corresponding unique numbers (in this example, “00010”, “0011”%) Of a plurality of LP gases using the supplier identification number “ID03” as a key. Allow for 14C.
  • the LP gas company B acquires personal information corresponding to each unique number from its own company server device 14B, and the LP gas company C receives personal information corresponding to each unique number from its company server device 14C. To get.
  • Geographic information display means (geographic information display processing) 139 is the same (common) mapping system (process executed thereby) as the geographical information display means 127 of the mobile terminal 12.
  • the used amount calculating means (used amount calculating process) 137 is based on the gas used amount (guideline value) of the gas meter information received from the portable terminal 12 and the gas meter management information shown in FIG.
  • the amount of gas used (guideline value) and the remaining amount of gas in the gas cylinder 20 are calculated and stored in the storage means 133 for each LP gas meter 21.
  • An example of data managed (generated or used) by the usage calculation means (usage calculation processing) 137 will be described later (see FIG. 9).
  • the supplier notifies the output result (the meter reading result) to the consumer.
  • the meter reading of the LP gas meter is performed without visiting each supply destination facility (each household), it is difficult for the consumer to grasp the presence or absence of meter reading. Therefore, when the supplier has registered the e-mail address of the consumer in advance and the meter is read (when the gas meter information is received from the portable terminal 12 on the information reception date, or from the usage calculation means 137 of the management device 13). When the meter reading result is output), the execution of meter reading is notified by e-mail. In addition, a portal site for each consumer is prepared in the management device 13 and the like, and a meter reading result and a bill for the usage amount are presented on the portal site.
  • meter readers visit each supply facility (each household) and notify the meter reading results by posting, or centrally manage the meter reading results and mail the meter reading result and bills for the amount used.
  • the portal site by notifying the meter reading result and presenting the bill for the usage amount on the portal site for each consumer, it is possible to greatly reduce the costs associated with the meter reading result notification and the issuance of the bill.
  • a change in the past usage amount for each user or a future usage amount prediction based on the past usage amount may be performed.
  • a meter reading result notification and a bill for the amount used may be mailed to the applicant.
  • the delivery prediction means (delivery prediction processing) 138 is based on the usage amount of the gas cylinder 20 and the gas meter management information shown in FIG. 4C, and the supply source (LP gas operator, branch, filling station, delivery center, retailer, etc.) ) To predict the scheduled delivery date of the gas cylinder 20 and the optimal delivery route.
  • An example of data managed (generated or used) by the delivery prediction means (delivery prediction process) 138 will be described later (see FIG. 9).
  • FIG. 5 is a schematic diagram for explaining a method of predicting a scheduled delivery date by the delivery predicting means 138.
  • the delivery predicting means 138 receives an input of a delivery date (actual delivery date, previous delivery date) of the gas cylinder 20 for each supply destination facility U, and stores the delivery date (previous delivery date). 133 is stored (1). And, for example, based on the usage amount of the same month in the past for each supply destination facility U, the remaining amount of gas in the gas cylinder 20 is a predetermined amount (for example, when the total amount of the two gas cylinders 20 is 100%, (For example, a date two months after the previous delivery date) is set as a provisional next delivery date and stored in the storage means 133 (2).
  • This information reception date is the reception date of the gas meter information transmitted from the portable terminal 12, and from the portable terminal 12, the gas meter information (including the guide value of the gas usage amount) is transmitted to the management device 13 in real time after meter reading. Therefore, it is a meter reading date by the portable terminal 12.
  • the delivery prediction unit 138 sets a date after a predetermined period (for example, one week) from the previous delivery date as the first information reception date, and the predetermined period (for example, one week) has elapsed from the first information reception date.
  • the later date is set as the second information reception date.
  • the remaining amount of gas in the target gas cylinder 20 is calculated by the usage amount calculation unit 137, and the previous delivery Based on the amount of decrease from the remaining gas amount (100%) in the day, the predicted day when the remaining gas amount in the gas cylinder 20 becomes a predetermined amount (approximately 20% of the total gas amount) is predicted again (4) Then, the provisional next delivery date is reset to update the provisional next delivery date in the storage means 133 (5).
  • the remaining amount of gas in the target gas cylinder 20 is calculated by the usage amount calculating means 137, and the first In accordance with the amount of decrease from the remaining amount of gas on the information reception date, the predicted day when the remaining amount of gas in the gas cylinder 20 becomes a predetermined amount (approximately 20% of the remaining amount of gas) is predicted again (6) Then, the next delivery date is determined, and the provisional next delivery date stored in the storage means 133 is updated (7).
  • the determined next delivery date in FIG. 5 (7) may be referred to as “next delivery date (determined)”.
  • the next delivery date (determination) is not changed in principle, but may be changed (advanced or advanced) depending on circumstances (8), which will be described later.
  • the information reception date is set twice between the previous delivery date and the provisional next delivery date has been described as an example.
  • the information reception date may be set twice or more (for example, 2 to 5 times). Etc.).
  • the information reception date can be arbitrarily set, and the accuracy of prediction is higher when the period of the plurality of information reception dates is shorter (the information reception date is set more frequently).
  • the delivery prediction unit 138 accepts the input of unscheduled gas meter information at any time. Based on the latest received gas meter information, the provisional next delivery date is updated as needed.
  • the remaining gas amount calculated based on the gas meter information acquired on the first information reception date is already less than a predetermined amount (for example, about 20% or less of the whole). In such a case, for example, one week later is determined as the next delivery date, and the second and subsequent information reception dates are not processed.
  • the delivery predicting means 138 sets the same next delivery date as a first condition (grouping condition), and supplies a plurality of supply destinations. Facilities are grouped and an optimal delivery route is predicted for each group.
  • FIG. 6 is a schematic diagram showing an example of delivery route prediction by the delivery predicting means 138.
  • the delivery predicting means 138 performs a first grouping process to group a plurality of supply destination facilities based on the above-described grouping condition (the same next delivery date is set).
  • the next delivery date is, for example, the last date predicted after a predetermined amount (for example, 20% of the total) that does not become exhausted without remaining gas remaining in the gas cylinder 20 (after that) Is the delivery deadline date when there is a risk of a shortage of gas remaining.
  • a predetermined amount for example, 20% of the total
  • the delivery predicting means 138 uses a special situation as the second condition (grouping special condition) to change the group (second grouping process, group change process) for the supply destination facility U belonging to a certain group. )It can be performed.
  • the group is changed based on the first condition (grouping condition) by changing (updating) the next delivery date (the next delivery date in FIG. 5 (7)) that has already been determined. It can be changed by performing one grouping process.
  • the delivery predicting means 138 uses the next delivery date determined in FIG. 5 (7) for the supply destination facility U based on the special grouping condition (second grouping condition). The next delivery date is changed by advancing the date (carrying forward) (FIG. 5 (8)). Then, the delivery predicting means 138 performs the first grouping process to include the supply destination facility U in the group A, and determines the most efficient delivery route in the group A.
  • the supply destination facility U in the group A since there is a limit to the number of gas cylinders that can be loaded on one delivery vehicle, if there are many supply destination facilities U belonging to a certain group (for example, group A) delivered on the same day, supply with one delivery vehicle.
  • the original BC and the supply destination facility U in the group A are reciprocated several times or delivered to one group A by a plurality of delivery vehicles.
  • the most efficient delivery route in the case of making a round trip to and from the supply source BC with one delivery vehicle is determined.
  • the supply destination facility U in the group A the most efficient delivery route for each delivery vehicle when delivering by a plurality of delivery vehicles is determined.
  • the supply destination facility U grouped in the first grouping process is preferentially delivered.
  • the group A includes a supply destination facility Ud whose next delivery date is advanced, even if the delivery route becomes somewhat inefficient.
  • the delivery facilities Ua, Ub... Of the original group A are preferentially delivered, and when the gas cylinders 20 are left, they are delivered to the supply facility Ud brought forward.
  • the most efficient delivery route including the forwarded supply facility Ud may be determined, or the forwarded supply may be determined.
  • the most efficient delivery route is determined for the supply facility Ud without advancing the next delivery date. It may be.
  • the next delivery date (denoted as “K” in FIG. 6) is assigned to the group A on October 1 as the supply destination facilities Ua, Ub,.
  • Supply facility in group J on October 10 Assume that Ug, Uh... Are grouped.
  • the delivery prediction means 138 performs a second grouping process based on the second condition as necessary. That is, based on the second condition, for example, when it is desirable to include the supply destination facility Ud of the group B, the supply destination facility Ue of the group C, and the supply destination facility Ug of the group J in the group A, the supply destination facilities Ud, Ue , Ug's next delivery date (determination) is changed to October 1 which is the next delivery date (determination) of group A (FIG. 5 (8)), and the first grouping process is performed again. Accordingly, the supply destination facilities Ud, Ue, Ug belong to the group A, and the gas cylinder 20 is delivered on October 1. That is, if the second condition is met, even if the scheduled delivery date (decision) is the supply destination facility Ug on October 10, the gas cylinder 20 is delivered on October 1 by 9 days. .
  • the second grouping process is a process of changing the next delivery date (determination) based on the second condition (grouping special condition) and regrouping (first grouping process).
  • the process is not limited to this example as long as the determined group can be changed based on the second condition.
  • group information for each supply destination facility may be registered in a database or the like, and the information may be updated each time based on the second condition.
  • the first condition is “the next delivery date (determination) is the same”, but the second condition (grouping special condition) is for each supplier BC.
  • the second condition is for each supplier BC.
  • FIG. 6B shows that the second condition is “a short distance from the delivery destination facility to be delivered” and “determine the advance period of the next delivery date according to the distance (a maximum of 3 days)”. It is a schematic diagram which shows an example in the case of performing delivery prediction as.
  • the distance is classified into, for example, “near”, “medium”, and “far”, and the distance from the supply destination facility Ua belonging to a certain group is “near” but belongs to another group.
  • the next delivery date of the supply destination facility Ub is advanced up to three days in advance and can be delivered on the same day as the supply destination facility Ua (“Near / ⁇ 3” in FIG. 6B).
  • the next delivery date of the supply destination facility Ub is advanced up to two days in advance (in FIG.
  • FIG. 5B for convenience of explanation, “near” when a plurality of neighboring supply destination facilities U are connected by a single solid line (for example, supply destination facilities U1 and U2, supply destination facilities U1 and U4), “Medium” when two solid lines are connected (for example, supply facility U1 and U7), for example, “distant” when connected by three or more solid lines (for example, supply facility U1 and U10).
  • the distance is as long as “middle” or “far”, a broken line (for example, supply facilities U1 and U9) The distance is classified as “medium” or “far.” It should be noted that the distance means not the straight distance on the map, but the distance on the actual route that the delivery vehicle can travel.
  • FIG. 5B there is a supply destination facility U1 to U10 in which a certain supply BC is responsible for delivery of the gas cylinder 20, and the next delivery date (determination) of the supply destination facilities U1 to U4 is October 1.
  • the next delivery date (determination) of the supply destination facility U9 is October 2
  • the next delivery date (determination) of the supply destination facilities U5 and U10 is October 3
  • the next delivery date (determination) of the supply destination facility U8 is October.
  • the next delivery date (determination) of the supply destination facilities U6 and U7 is October 5.
  • the supply destination facilities U1 to U4 are the group A
  • the supply destination facility U9 is the group B
  • the supply destination facilities U5 and U10 are the group C
  • U8 is classified as group D
  • the supply destination facilities U6 and U7 are classified as group E.
  • the second grouping process is performed based on the second condition.
  • the distance to the neighboring supply destination facility is “medium” (broken line) according to the second condition
  • the next delivery date can be advanced two days before, so the delivery predicting means 138 will use the next time for the supply destination facility U9.
  • the delivery date (decision) is changed to October 1 and set to group A again.
  • the delivery predicting means 138 determines a route (a route that can be moved along the solid line (or broken line) without waste) that can deliver all of the supply destination facilities U belonging to the group A without waste.
  • the route of the delivery destination facility U9 is changed so that delivery is performed next to the supply destination facility U1 or U4.
  • the delivery destination facility U8 since the delivery destination facility U8 is also delivered only at one location on October 4, and is far from the supply source BC, it is less wasteful to deliver by changing to another group. Therefore, the second grouping process is performed based on the second condition.
  • the next delivery date of the supply destination facility U8 since the distance to the supply destination facility U5 via the supply destination facility U7 is “medium” (solid line 2 text), the next delivery date of the supply destination facility U8 is advanced by one day, and October 3 The date may be changed and delivered on the same day as the supply destination facility U5.
  • the distance from the supply destination facility U7 to the supply destination facility U8 is “near”, but the distance from the supply destination facility U6 to the supply destination facility U7 is “medium” (two solid lines or broken lines).
  • the next delivery date of the supply destination facility U7 may be advanced one day, changed to October 4, and delivered on the same day as the supply destination facility U8.
  • the delivery predicting means 138 determines a route (a route that can be moved along the solid line (or broken line) without waste) that can deliver all of the supply destination facilities U belonging to the group C or group E without waste.
  • the first The most efficient delivery route is determined after the supply destination facilities U grouped by the grouping process (the next delivery date is not advanced) are delivered preferentially (reliably).
  • the battery 114 of the information transmission device 11 can be appropriately replaced when the gas cylinder 20 is delivered.
  • the second grouping process is a process that is performed as necessary. If there is no problem in the efficiency of delivery, the group need not be changed. Further, when a special situation occurs until the next supply date (conditions are changed as necessary), the group change process (second grouping process) may be performed a plurality of times.
  • the delivery predicting means 138 of the present embodiment even if the next delivery date (decision) is different for the supply destination facility U whose delivery efficiency deteriorates only by grouping only by the next delivery date (decision),
  • the group can be changed, and the above example is merely an example for specifically explaining the group change. That is, the delivery predicting means 138 groups a plurality of supply destination facilities U according to the next delivery date (first condition), and according to special circumstances (second condition) that can be arbitrarily set for each supply source BC.
  • the configuration is not limited to the above example as long as the group can be changed.
  • FIG. 7 is a timing chart showing processing of the information transmission device 11, the portable terminal 12 and the management device 13 in the gas supply management system 10, and
  • FIG. 8 is an example of display by the geographic information display means 127 of the portable terminal 12.
  • the meter reader (meter meter) of the LP gas meter 21 carries the portable terminal 12 on a preset meter reading day and goes to a predetermined information acquisition point.
  • the person carrying the mobile terminal 12 may be a delivery person of the gas cylinder 20 or an LP gas company.
  • the meter reading date is the information acquisition date (in the above example, the first information reception date and the second information reception date) set by the delivery prediction unit 138 of the management device 13.
  • the information acquisition point is a gas cylinder 20 (LP gas meter 21) supplied by as many LP gas supply companies as possible within a predetermined range centered on the information acquisition point (for example, within a radius of 200 m to 300 m). It is a predetermined point so as to exist as a meter reading target (so that gas meter information can be acquired). Information on the information acquisition points is stored in the storage device 133 of the management device 13 for each predetermined area.
  • the meter reader operates the portable terminal 12 at the information acquisition point, and performs an information transmission request process. That is, an information transmission request is transmitted to the information transmission apparatus 11 at an arbitrary timing for a predetermined period (for example, 1 minute) (1).
  • the information transmission device 11 connected to the gas cylinder 20 (LP gas meter 21) to be metered performs information transmission processing.
  • the standby mode in which the information transmission request reception process is not performed and the reception mode in which the information transmission request reception process is performed are automatically switched periodically.
  • the information transmission request reception process is executed periodically (for example, once every 30 seconds) by the timer interruption of the control unit 115, and the portable terminal 12 transmits by the communication unit 136.
  • An information transmission request is received (2).
  • the information transmission device 11 determines whether or not an information transmission request has been received, and when an information transmission request is received, performs an individual information transmission process.
  • the acquisition unit 112 of the information transmission apparatus 11 acquires gas meter information from the LP gas meter 21 (3), stores it in a predetermined memory 116, and sends an information transmission request via the communication unit 113 and the network NW. Gas meter information is transmitted (wireless transmission) to the transmitted portable terminal 12 (4).
  • the individual information transmission process is not performed and the information transmission process is terminated.
  • the meter reader confirms whether or not the acquisition of all the gas meter information of the LP gas meter 21 in the target range is successful by the geographic information display means 127 (5).
  • the geographic information display means 127 is configured to be able to display on the display means 121 whether or not the gas meter information has been successfully acquired for each LP gas meter 21 as a target.
  • FIG. 8 (a) when the positions of the LP gas meters 21 are displayed as squares on the electronic map displayed by the display means 121, all the displayed LP gas meters 21 are displayed. Is the acquisition target of gas meter information.
  • the image of the mobile terminal 12 at the center of the circle is the information acquisition point.
  • an arrow from the LP gas meter 21 toward the information acquisition point is displayed.
  • no arrow is displayed from the LP gas meter 21.
  • the carry person of the portable terminal 12 can grasp
  • the meter reader associates the gas meter information, which has been successfully acquired, with the positional information of the LP gas meter 21 and manages it via the network NW (for example, a wireless mobile communication line). Transmit (upload) to the device 13 (6).
  • NW for example, a wireless mobile communication line
  • the meter reader acquires the gas meter information by the information reception / transmission means 129 of the portable terminal 12 (8).
  • the meter reader goes to the LP gas meter 21 that has failed to acquire the gas meter information, captures the gas meter information of the LP gas meter 21 with the camera of the portable terminal 12, and stores the image data (or stores the gas meter information of the portable terminal 12). Input from the input means 122).
  • the information reception / transmission means 129 character-recognizes the unique number of the LP gas meter 21, a guideline value indicating the amount of gas used, security information, and the like from the stored image data, and obtains the information from the character information and geographic information display means 127.
  • the position information is linked and stored in the acquisition unit 112 of the portable terminal 12 as gas meter information.
  • the information reception / transmission unit 129 inputs character information such as a unique number of the LP gas meter 21, a guideline value indicating the amount of gas used, and security information by operating the touch panel (input unit 122) of the portable terminal 12 of the carry person. Is associated with the position information acquired from the geographic information display means 127 and stored in the acquisition unit 112 of the portable terminal 12 as gas meter information. Then, the information reception / transmission means 129 associates the gas meter information with the position information of the LP gas meter 21 acquired from the geographical information display means 127, and manages the management apparatus 13 via the network NW (for example, a wireless mobile communication line). Send (upload) to (9)
  • NW for example, a wireless mobile communication line
  • the management device 13 associates the gas meter information transmitted from the mobile terminal 12 with the position information of the LP gas meter 21 and stores the information in the storage device (database) 133.
  • the gas meter information includes a unique number that can identify the LP gas meter 21, and the management device 13 uses the unique number as a key for each LP gas meter 21 to calculate a usage amount (10) or a delivery prediction process ( Various processes relating to gas supply such as 11) can be executed.
  • the gas usage amount (guideline value) of the gas meter information received from the mobile terminal 12 is accumulated for a predetermined period (for example, one month, two months, two years, three years, etc.)
  • the amount of gas used for each gas cylinder 20 and the remaining amount of gas in the gas cylinder 20 during the period are calculated and stored in the storage means 133 for each LP gas meter 21.
  • the management device 13 receives an input of a delivery date (actual delivery date, previous delivery date) of the gas cylinder 20 for each supply destination facility U.
  • the delivery date previously delivery date
  • the remaining amount of gas in the gas cylinder 20 is a predetermined amount (for example, when the total amount of the two gas cylinders 20 is 100%, the total 20 A date (for example, a date two months after the previous delivery date) predicted to become approximately% gas remaining) is set as a temporary next delivery date and stored in the storage means 133.
  • a plurality of (for example, twice) information reception dates are set between the previous delivery date and the provisional next delivery date.
  • the remaining gas amount in the target gas cylinder 20 is calculated by the usage amount calculation process. Based on the decrease from the remaining gas amount (100%) on the previous delivery date, the estimated date when the remaining gas amount in the gas cylinder 20 becomes a predetermined amount (approximately 20% of the total gas amount) The next delivery date is reset and the provisional next delivery date in the storage unit 133 is updated.
  • the target gas cylinder is processed by the usage amount calculation process.
  • the amount of gas remaining in the gas cylinder 20 is calculated according to the amount of decrease from the amount of gas remaining on the first information reception date, and the amount of gas remaining in the gas cylinder 20 is a predetermined amount (about 20% of the total amount of gas remaining).
  • the predicted delivery date is determined as the next delivery date, and the provisional next delivery date stored in the storage unit 133 is updated.
  • the geographical information display means 139 is used to determine a route that can be efficiently delivered in the shortest time for a plurality of supply destination facilities U that are set to have the same next delivery date.
  • the delivery person of the gas cylinder 20 goes to the target destination facility U on the next delivery date and replaces the gas cylinder 20 based on the delivery route determined in this way.
  • a unique gas supply management system that matches the supply form of the LP gas business can be provided at low cost.
  • Smart meters in the electricity business have a power supply, and the installation locations of smart meters are dense in a relatively small area, so information is relayed between smart meters by wireless communication, and information is transferred from the relay base to the network. Can be uploaded.
  • a method of uploading information to a network using an existing transmission line infrastructure called Power Line Communication (PLC) can also be adopted.
  • PLC Power Line Communication
  • LP gas meters in the LP gas business do not have a power source, and the installation locations of the LP gas meter are scattered within a predetermined range, so the same system as the smart meter in the electric business is introduced. Difficult to do.
  • LP gas companies also collect information from LPP gas meters via electric utility smart meters and upload them to the network or use a centralized monitoring system that has been used in the past.
  • a method of uploading to the network using the network infrastructure of the network is being studied.
  • development of a meter having a communication function (U bus) is also being conducted for LP gas meters.
  • the LP gas meter 21 is added to the existing LP gas meter 21 by adding the information transmission device 11 including the communication unit 113 that performs wireless communication with the battery 114. Since the gas meter information is transmitted to the portable terminal 12, the existing LP gas meter 21 can be used effectively, and construction costs and equipment installation / replacement costs can be suppressed.
  • a mobile communication network is used for communication between the information transmission apparatus 11, the portable terminal 12, and the management apparatus 13, a system can be constructed that does not depend on the communication infrastructure of another person such as a power company.
  • the gas meter information of the LP gas meters 21 of a plurality of supply destination facilities U can be acquired at the information acquisition point, meter reading work by individual visits of meter readers is not required, and labor costs can be greatly reduced.
  • the efficiency of meter reading can be improved, it is possible to increase the number of meter readings in a predetermined period, and the remaining gas can be increased by increasing the number of meter readings (for example, two to three times in January or 5 to 6 times in January).
  • the prediction accuracy of quantity and next delivery date can be improved.
  • the remaining amount of gas was delivered and exchanged at about 50% of the total gas cylinder 20 at one supply destination facility U. Accordingly, for example, delivery and replacement can be performed when the remaining gas amount is about 20% of the entire gas cylinder 20, so that the delivery efficiency can be greatly improved and the cost of delivery of the gas cylinder 20 can be reduced.
  • the efficiency of operations such as meter reading, security, and delivery can be reduced, and thus the supply and management costs can be reduced. As a result, it is possible to continuously provide cheap and safe energy to general consumers. .
  • the gas supply management system 10 is constructed by a single management device 13 is illustrated.
  • the present invention is not limited to this, and the functions of the management device 13 described above are provided in a plurality of ways. These functions may be realized by being distributed to apparatuses (server apparatus, PC, etc.).
  • FIG. 9 shows an example of data managed by the management apparatus 13 (delivery prediction means 138 and usage amount calculation means 137) according to the present embodiment.
  • FIG. 9A shows management (use and generation) by the usage amount calculation means 137.
  • FIG. 5B is an example of data managed (used or generated) by the delivery predicting means 138.
  • the usage amount calculating means (usage amount calculating process) 137 includes, for example, a unique number (meter No.) of the LP gas meter 21, a usage amount (guideline value) for each LP gas meter 21, and the LP gas meter 21.
  • Usage data including location information, date of acquisition (meter reading date), security information, and the like.
  • the delivery prediction means (delivery prediction process) 138 includes, for example, a unique number (meter No) of the LP gas meter 21, a usage amount (guideline value) for each LP gas meter 21, a customer code,
  • the delivery prediction data including the customer name, information on the gas cylinder 20 (installation container information), and delivery destination information (information including at least the next delivery date and the optimum delivery route (or position information) for each LP gas meter 21) are managed.
  • the usage amount calculation means (use amount calculation processing) 137 and the delivery prediction means (delivery prediction processing) 138 function independently, and the usage amount data shown in FIG.
  • the prediction data may be managed independently, or the distribution prediction means (delivery prediction processing) 138 and the usage amount calculation means (use amount calculation processing) 137 are distributed and functioned in a plurality of management devices 13 to deliver the data.
  • the prediction data and the usage amount data may be managed independently.
  • gas meter management information (data shown in FIG. 4C) of the management device 13 may be managed independently.
  • various types of data managed (generated and used) by the management device 13 for example, gas meter management information shown in FIG. 4C
  • the usage amount calculation means (usage amount calculation data generated (managed) by the usage amount calculation process) 137) may be used in a system using a smart meter such as gas or electricity.
  • the present invention is made using a power saving (low power) and wide area (long distance) wireless communication technology.
  • “Power-saving (low-power) and wide-area (long-distance) wireless communication technology” means low power consumption and communication over a wider area than WiFi (registered trademark), Bluetooth (registered trademark), etc. Wireless communication technology that enables long-distance communication).
  • Examples of the communication method (communication standard) include LPWA (Low Power Wide Area) and LPWAN (Low Power Wide Area Network).
  • LPWA Low Power Wide Area
  • LPWAN Low Power Wide Area Network
  • the gas supply management system 10 using LPWA is mainly used in acquiring (collecting) information (gas meter information) from the information transmission device 11 (as part or all of the network NW1 of the first embodiment), for example, LPWA.
  • a network (communication line) NW3 configured by technology, that is, an LPWA network is used.
  • the gas supply management system 10 of the second embodiment has the configuration and functions described below.
  • it may have the same configuration and function as the gas supply management system 10 described in the first embodiment, and may be configured to execute various processes in parallel or switching as appropriate.
  • FIG. 10 is a schematic diagram schematically showing a gas supply management system 10 using LPWA.
  • the gas supply management system 10 using LPWA includes an LP gas meter 21, an information transmission device 11, a management device 13, an information collection unit 31, a storage unit (storage device) 30,
  • the mobile terminal 12 includes networks NW1 and NW3 to which they are connected.
  • the information transmission device 11 (and the LP gas meter 21) has a configuration corresponding to the LPWA network (communication line) NW3. That is, the information transmission device 11 is connected to each LP gas meter 21 as in the first embodiment (see FIG. 2), or is incorporated in each LP gas meter 21 and acquires gas meter information from each LP gas meter 21.
  • the communication unit 113 of the information transmission device 11 can be connected to the network NW3, and is configured to transmit gas meter information to the collection unit 31 on the network NW3.
  • the network NW3 is, for example, an LPWA network that uses a communication band (920 MHz band) that does not require a license, thereby enabling low-cost, low power consumption, wide-area (long-distance) wireless communication.
  • a case where the network (communication line) NW3 is an LPWA network will be described as an example.
  • the network NW3 is a communication network (communication line) capable of at least wide-area (long-distance) wireless communication, It is not limited to the LPWA network.
  • the information transmitting apparatus 11 can be driven with low power consumption, and the battery 114 built in the information transmitting apparatus 11 can be used for several years, for example, with two dry batteries.
  • the network NW1 is a generic term for wired and / or wireless communication lines, and includes a network (LPWA network) NW3.
  • the collection means (collection apparatus) 31 is a means for connecting to the network NW3 and collecting gas meter information transmitted by the information transmission apparatus 11, for example, a radio base station compatible with LPWA communication, or the radio base station It is a fixed terminal connected by wire (or wireless).
  • the collection means 31 may be a wireless base station for LPWA communication and / or mobile communication, or may be a mobile communication terminal connected to the wireless base station.
  • the gas meter information transmitted by the information transmission device 11 is collected by the collection device 31 and transmitted to the storage device 30 via the network NW1 to which the collection device 31 is connected.
  • the storage device 30 is a device that is connected to the network NW1 and stores various information including gas meter information, application programs, and the like.
  • the storage device 30 is a server (cloud server) provided in a cloud environment.
  • the management device 13 is connected to the network NW1, and acquires gas meter information and the like stored in the storage device 30 via the network NW1.
  • at least a part of the functions of the management device 13 is stored in the storage device 30 as an application program, and is configured to be used in the management device 13 by the cloud computing system.
  • the management device 13 is connected to the provider server device 14 as in the first embodiment.
  • the management device 13 and the provider server device 14 may be connected via the network NW2 illustrated in FIG. 1 or may be connected via the network NW1 (NW3).
  • data such as personal information of the LP gas contractor and the function of the server device 14 for the business may be stored in the storage device 30 and used in the management device 13 by the cloud computing system.
  • the information transmission device 11 is externally attached to or built in the LP gas meter 21, acquires the gas meter information of the LP gas meter 21 at an arbitrary timing or a predetermined timing, and transmits it to the collection device 31 via the network NW3.
  • the collection device 31 stores and accumulates the acquired gas meter information in the storage device 30 via the network NW1.
  • the management device 13 acquires the gas meter information stored in the storage device 30 via the network NW1 at an arbitrary timing or a predetermined timing.
  • the management device 13 can automatically acquire the gas meter information transmitted by the device 11 remotely. Thereby, the management apparatus 13 can grasp
  • frequent means that the frequency is higher (higher) than monthly, for example, grasping at a frequency higher than the frequency such as once a month or once a week.
  • gas meter information can be acquired daily and the amount of gas used can be grasped.
  • the management device 13 utilizes the acquired gas meter information for monthly meter reading work in the LP gas sales business, and performs daily usage calculation processing and delivery prediction processing to improve the efficiency of LP gas delivery work. Take advantage of. Specifically, an optimal delivery date and an efficient (optimum) delivery route (delivery route) are predicted for delivering the gas cylinders 20, and the number of gas cylinders 20 loaded on a plurality of delivery vehicles is instructed. Perform the process automatically.
  • the mobile terminal 12 is a terminal capable of mobile communication, for example, as in the first embodiment (see FIG. 3), and the management device 13, the storage device 30 and information via the radio base station 31 of the network NW1 (NW3).
  • Information including gas meter information can be transmitted / received to / from the transmission device 11 and the like.
  • the display unit 121 is configured to display geographic information and the like.
  • the portable terminal 12 can be carried by a delivery person of the gas cylinder 20 or attached to a delivery vehicle of the gas cylinder 20, and information between at least the management device 13 and / or the storage device 30 can be obtained.
  • the gas meter information acquired by the information transmission device 11 is automatically stored in the storage device 30, and therefore the mobile terminal 12 may not be configured to be able to acquire and collect the gas meter information.
  • the gas meter information acquired by the information transmission device 11 may be appropriately acquired and collected by the mobile terminal 12.
  • Information relating to delivery predicted by the management device 13 (delivery destination (supply destination facility U, the same applies hereinafter), delivery route, or information relating to delivery status, etc.) is transmitted to the mobile terminal 12 and can be displayed on the display means 121. ing.
  • the mobile terminal 12 accepts registration (update) of the delivery schedule, delivery destination, delivery route, delivery status information, security check information, etc. of the delivery person, and these information is stored in the management device 13 and / or the storage device 30. Can be sent.
  • reading of characters and image information, barcode scanning, display (and output) of delivery slips, and the like are possible.
  • the delivery person of the gas cylinder 20 registers his / her attendance schedule or the like in the management device 13 in advance via the portable terminal 12, and registers / confirms / corrects (transmission / reception) information on the delivery destination, delivery route and delivery status. Etc.
  • FIG. 2A is a block diagram showing an outline of the configuration of the management apparatus 13
  • FIG. 2B is a block diagram showing an outline of functions of the management apparatus 13.
  • the management device 13 of the second embodiment has a configuration and functions described below.
  • the configuration / function described in the embodiment may be included, and may be configured to execute various processes in parallel or switching as appropriate.
  • the management device 13 is connected to a storage device (for example, a cloud server) 30 via a network NW1 such as the Internet, and is connected to the mobile terminal 12 and a network NW1 such as a mobile communication line.
  • NW3 for example, a server device (or personal computer (PC)) connected to the provider server device 14 via a network NW2 such as the Internet or a dedicated line, and includes a CPU 130, a ROM 131, A RAM 132, a storage unit (storage device) 133, an input unit 134, a display unit 135, a communication unit 136, and the like are included.
  • the communication unit 136 communicates with the mobile terminal 12 and the storage device 30 via the network NW1, and communicates with the business server device 14 via the network NW2, for example.
  • the configurations of the CPU 130, ROM 131, RAM 132, storage means (storage device) 133, input means 134, and display means 135 are the same as those in the first embodiment.
  • the management apparatus 13 includes a basic processing unit 55 and a delivery management unit 50.
  • the delivery management unit 50 includes, for example, a usage calculation unit 137, a delivery prediction unit 138, and a geographic information display unit. 139 and the like.
  • the management device 13 reads the software program stored in the ROM 131 or the like into the work area of the RAM 132 and executes the software program by the CPU 130, thereby executing the gas supply management process.
  • This gas supply management process includes a basic process and a usage calculation process, a delivery prediction process, a geographic information display process, and the like as a delivery management process.
  • the functions of (usage calculation unit 137, delivery prediction unit 138, geographic information display unit 139) are realized.
  • the basic processing means 55 and the delivery management means 50 are stored in the storage device 30 and used in the management device 13 by the cloud computing system.
  • the basic processing means 55 and the delivery management means 50 may be stored in the storage means of the management apparatus 13 (storage means connected to the management apparatus 13). .
  • Core processing means (main processing) 55 is mainly based on gas meter information, security management processing that reflects inspection information on a monthly basis (monthly), delivery management (inventory management) processing that reflects inventory, customer information, etc. It performs database update processing and other known core business processing.
  • the delivery management means (delivery management process) 50 obtains gas meter information at a high frequency (for example, once a month or higher than once a week), predicts the usage amount in the future date, and based on this The scheduled delivery date and the optimal delivery route of the gas cylinder 20 are predicted, the delivery route is displayed on the display unit 135 of the management device 13 together with the geographical information, and the delivery route is transmitted to the portable terminal 12.
  • the actual amount of gas used (guideline value) and the remaining amount of gas in the gas cylinder 20 are calculated and stored and stored in the storage unit 133 or the storage device 30 for each LP gas meter 21.
  • the delivery prediction means (delivery prediction processing) 138 is based on the gas meter information acquired from the storage device 30 (the usage amount of the gas cylinder 20) and the gas meter management information shown in FIG.
  • the estimated delivery date of the gas cylinder 20 and the optimal delivery route are predicted for each of the filling station, the delivery center, the retailer, and the like.
  • the delivery prediction means (delivery prediction processing) 138 calculates a daily predicted usage amount (daily predicted usage amount) in a future date. This daily predicted usage is calculated so as to increase or decrease as the number of days elapses, for example, by calculating the unit predicted usage change amount for each day based on the reference gas usage in the past predetermined period. .
  • the delivery predicting means (delivery prediction processing) 138 calculates a predicted value (gas remaining amount predicted value) of the daily gas remaining amount in the future date in the gas cylinder 20 based on the calculated daily predicted usage amount.
  • the estimated delivery date is determined by predicting the date when the gas remaining amount prediction value is reduced to a predetermined amount.
  • the delivery predicting means (delivery predicting process) 138 predicts an optimal delivery route based on the determined scheduled delivery date, displays the delivery route on the display means 135 of the management device 13, and delivers the gas cylinder 20. To the portable terminal 12 possessed by the person.
  • FIG. 1 is a block diagram showing an example of the flow of processing mainly in the delivery management means 50 in the management device 13 and the processing in the mobile terminal 12.
  • the delivery management means (delivery management process) 50 performs, for example, a usage / delivery prediction process and a delivery route determination process.
  • the usage / delivery prediction process includes, for example, a gas meter information acquisition process S01, a usage calculation process S02 (137), a delivery prediction process S03 (138), and a delivery information registration process S09.
  • a predicted usage calculation process S04, a prediction calculation process S05, a limit date calculation process S06, a delivery plan data creation process S07, a delivery target extraction process S08, and the like are performed.
  • the delivery route determination process includes, for example, a calendar registration process S21, a delivery information determination process S23 (daily vehicle dispatch rotation speed determination process S25, same day delivery target extraction process S27, and delivery vehicle specific delivery determination process S29), and a delivery route display. Processing S31 etc. are performed.
  • the mobile terminal 12 performs a shift registration process S11, a person-by-person delivery location extraction process S13, a delivery registration process S15, a delivery completion registration process S17, and the like.
  • the gas meter information acquisition process S01 of the delivery management means (delivery management process) 50 acquires the gas meter information stored in the storage device 30.
  • NW3 LPWA network
  • the management device 13 can automatically acquire the gas meter information from the information transmission device 11 at a frequency higher than a frequency such as once a week).
  • the management device 13 (delivery management means 50) is targeted at a frequency of once every two to three days, more preferably once a day, or a shorter frequency.
  • the gas meter information of each gas cylinder 20 can be acquired automatically. In the following description, as an example, a case will be described in which the management device 13 (delivery management means 50) acquires the gas meter information stored in the storage device 30 once a day (daily).
  • an LP gas contractor (hereinafter referred to as "daily information acquisition target person") from which gas meter information is acquired every day (daily) is extracted.
  • the supplier identification number and the LP gas unique number for example, LP gas meter manufacturing number
  • the personal information of each daily information acquisition target held in the business server device 14 is linked.
  • the supply source identification number, the LP gas unique number, the acquired gas meter information, the date, personal information, and the like are prepared as input data for each person who acquires the daily information.
  • the calendar registration process S21 of the delivery route confirmation process registration of the number of operating vehicles for each type of delivery vehicle by the person in charge (delivery manager) of the LP gas supply source is accepted.
  • the delivery manager registers in advance the number of vehicles that can be operated on a daily basis for each vehicle type of delivery vehicle with different loading capacity of the gas cylinders 20.
  • the portable terminal 12 is a terminal device capable of mobile communication that is carried (carried) by the delivery person of the gas cylinder 20.
  • the portable terminal 12 receives the shift registration of the delivery person and transmits the information to the management device 13 (the delivery management means 50).
  • the shift is information including, for example, the work schedule of the delivery person for the latest seven days, the available working hours, and the like.
  • the usage amount calculation process S02 (137) uses the LP gas unique number (which may include a supply source identification number; the same applies hereinafter) as a key for each management person 13 (or storage device 30) for each person who acquires the daily information. ), The previous gas meter information stored in the previous gas meter information and the gas usage (guideline value) included in the previous gasmeter information and the gas usage (guideline value) included in the gasmeter information acquired this time. The amount of gas used since the acquisition of the gas meter information, the amount of change in the amount of gas used, the remaining amount of gas in the gas cylinder 20 and the like are calculated.
  • gas meter information (guideline value) is acquired monthly or a cycle close to it, and there is a problem that the error is large.
  • gas meter information in a daily cycle for example, gas meter information in a daily cycle. Therefore, it is possible to grasp daily usage (change), not monthly usage (change), and to accurately predict delivery.
  • the delivery prediction process S03 (138) performs an estimated usage amount calculation process S04, a prediction calculation process S05, a limit date calculation process S06, and a delivery plan data creation process S07 based on the indicated rotational speed and the acquired gas meter information, and LP gas
  • the daily estimated usage amount for each contractor, the limit date on which delivery (exchange) can be suspended, delivery plan data, and the like are output.
  • the designated rotational speed is, for example, the rotational speed of delivery per day by a single delivery vehicle serving as a reference for each season.
  • a predetermined number (for example, twice or three times) is set in advance in the delivery prediction unit 138 according to the season or the like, and can be changed as appropriate.
  • the gas meter information includes gas meter information acquired by the meter reader at the time of meter reading and gas meter information at the time of delivery acquired by the delivery person in addition to the gas meter information automatically acquired from the storage device 30 by the management device 13 on a daily basis. It is.
  • the prediction calculation process S04 determines whether or not the remaining gas amount for each of the daily information acquisition targets obtained in the usage calculation process S02 has reached the prediction start threshold (prediction start residual gas rate) (below the prediction start threshold). Or not). Then, for a daily information acquisition target person who satisfies a predetermined condition in addition to being less than the prediction start threshold value, the prediction calculation process S05 is executed for each target person to calculate the daily predicted usage amount in the future date. Details of the daily predicted usage calculation process (prediction calculation process S05) will be described later.
  • a prediction start threshold (prediction start residual gas rate), a gas remaining amount threshold (residual gas rate), and a delivery limit threshold (limit rate) are set.
  • These threshold values are, for example, the ratio of the remaining gas amount to the total amount of the gas cylinder 20.
  • the prediction start threshold is a determination condition for starting the prediction calculation process S05, and the prediction calculation process S05 is started when the actual remaining gas amount in the gas cylinder 20 falls below the prediction start threshold.
  • the prediction start threshold is 15%.
  • the gas remaining amount threshold value (residual gas rate) is a threshold value for giving priority to the gas cylinders 20 to be exchanged when creating delivery plan data described later.
  • the predicted daily usage and gas remaining amount for the future date are predicted by the prediction calculation process S05, and when the predicted gas remaining amount (gas remaining amount predicted value) falls below the gas remaining amount threshold, To do.
  • the gas remaining amount threshold is 10%.
  • the delivery limit threshold (limit rate) is a threshold for determining a delivery limit date, which will be described later. Predicted daily usage and gas remaining amount in the future date is predicted by the prediction calculation process S05, and if the predicted remaining gas amount (remaining gas predicted value) falls below the delivery limit threshold, the date a few days before is delivered The limit date. In this example, the delivery limit threshold is 5%.
  • the gas cylinder 20 whose gas remaining amount prediction value is between the gas remaining amount threshold value and the delivery limit threshold value becomes the gas cylinder 20 to be delivered (replaced).
  • the gas remaining amount threshold value is appropriately increased (for example, 15%), and the number of gas cylinders 20 to be delivered is increased.
  • These thresholds are set (adjusted as appropriate) for each contractor according to the past usage situation of each LP gas contractor, regardless of whether or not the person is a daily information acquisition target. .
  • gas meter information about LP gas contractors other than the daily information acquisition target person is acquired separately.
  • NW3 LPWA network
  • meter reading work by a meter reader or a delivery person of the gas cylinder 20 etc. Therefore, gas meter information is appropriately acquired at the time of meter reading or at the time of delivery of the gas cylinder 20, and managed (for example, using another management system).
  • gas meter information is acquired (from another management system or the like) for LP gas contractors other than the daily information acquisition target person, and the gas usage included in the previous gas meter information is acquired. (Guideline value) and the amount of gas used (Guideline value) included in the gas meter information acquired this time, calculate the amount of gas used since the previous acquisition of gas meter information, the amount of change in gas usage, the remaining amount of gas, etc. . Then, the prediction calculation process S05 is executed for each LP gas contractor other than the daily information acquisition target person, and the daily predicted usage amount in the future date is calculated.
  • LP gas contractor when it is not necessary to distinguish between the daily information acquisition target person and the LP gas contractor other than the information acquisition target person, they will be collectively referred to as “LP gas contractor”.
  • the limit date calculation process S06 is based on the predicted daily usage amount in the future date calculated in the predicted usage amount calculation process S04, and the predicted value of the remaining gas amount in the future date (predicted residual gas value). And the date when the gas remaining amount prediction value reaches a predetermined delivery limit threshold is predicted.
  • the delivery limit threshold (limit rate) is, for example, a value lower (smaller) than the gas remaining amount threshold (see FIG. 13), and exceeds the limit for deferring delivery (the delivery / exchange must be performed immediately). Value.
  • a date that is a predetermined number of days (2 days to several days) ahead of the date that reaches the delivery limit threshold is calculated as the delivery limit date.
  • limit days the number of days to be advanced (2 to several days) is referred to as “limit days”.
  • the details of the limit date calculation process S06 will be described later.
  • the gas remaining amount threshold value, the delivery limit threshold value, and the limit days are set according to the LP gas contractor (supplier facility U, gas cylinder 20) according to the gas usage status and the like. ) Is set for each.
  • information for example, the gas cylinder 20 (supply destination facility U) regarding the supply destination facility U that satisfies the designated rotational speed and whose delivery limit date comes within a predetermined period (for example, within the last seven days) is reached.
  • Information including location information (geographical information, address, etc.), information including delivery date limit, unique number of gas cylinder 20, etc.), the designated rotational speed, and the location information of the delivery destination facility U that delivers the highest priority
  • the address, the location information of the supply destination facility U as a spare delivery destination, the address, the delivery priority for each supply destination facility U, the unique number of the gas cylinder 20 and the like are output as delivery plan data.
  • Priority is determined based on the remaining gas threshold and the prediction start threshold.
  • the supply destination facility U gas cylinder 20
  • the supply destination facility U gas cylinder 20
  • the supply destination facility U gas cylinder 20
  • the spare delivery destination has a lower priority than the highest-priority delivery destination, and is a delivery destination prepared as a spare to advance the delivery limit date for efficient delivery when an optimum delivery route is derived later.
  • the amount of gas used can be acquired in the daily cycle, and the daily predicted usage amount and the daily gas remaining amount prediction value can be calculated. Very close to the limit and can be predicted accurately.
  • the delivery limit date is calculated as a date two days before the estimated amount of gas remaining in the gas cylinder 20 is 5% or less of the total (the estimated amount of gas remaining in the gas cylinder 20 is within 2 days. It is possible to obtain a day that will be 5% or less. As a result, the delivery efficiency can be significantly improved as compared with the conventional case where the delivery (exchange) is performed by predicting the day when the remaining amount of gas is, for example, 50%.
  • the delivery target extraction process S08 is performed within a predetermined period (for example, based on the delivery limit date calculated in the limit date calculation process S06, the delivery plan data created in the delivery plan data creation process S07 (priorities included therein), and the like.
  • the gas cylinder 20 (supplier facility U) corresponding to the LP gas contractor for which the delivery limit date has arrived and the delivery operation has not been completed is extracted as a delivery target within the last seven days, and if necessary
  • a plurality of supply destination facilities U are grouped according to a predetermined condition such as a priority order or a limit date on the same day (or a date close to the same date).
  • the location information (delivery target location information) of the grouped supply destination facility U (supply destination facility group) and information on the supply destination facility group (for example, information including gas meter information and daily predicted usage amount) The data is transmitted to the delivery route determination process (delivery information determination process S23) as part of the delivery plan data.
  • the delivery information determination process S23 based on the delivery plan data, the number of revolutions that can be delivered on the current day, etc., the daily delivery speed determination process S25, the same day delivery object extraction process S27, the delivery decision process S29 for each delivery vehicle, and the like are performed.
  • the optimal delivery route, optimal load capacity, etc. are determined for each vehicle and output as a delivery instruction.
  • the daily vehicle rotation speed determination process S25 is executed as necessary, and accepts input (correction) such as a shift of the delivery person, the number of operation of the delivery car and the rotation speed, and the distribution target extracted in the delivery target extraction process S08.
  • Re-group including extraction
  • the destination facility group For example, the daily dispatch speed determination process S25 includes an information correction process S26, and when the delivery person suddenly takes a break or the working hours are changed, or the delivery car is operated according to the weather condition. If the number of units or the number of delivery revolutions (indicated revolutions) is unreasonable, various information such as the shift of the delivery person, the number of units in operation, and the deliverable number of revolutions as a revised value of the designated number of revolutions (re-registration) ). Based on the corrected information, the supply destination facility group extracted in the delivery target extraction process S08 is regrouped, and the delivery vehicle (operating number) for delivery and the rotation speed of delivery for each delivery vehicle are revised. (adjust.
  • the same day delivery target extraction process S27 includes information on the supply destination facility group included in the shift table and delivery plan data registered in the shift registration process S11, and information corrected in the daily vehicle delivery speed determination process S25 (delivery speed that can be delivered). Etc.), the supply destination facility group to be delivered extracted in the delivery object extraction processing S08, or the delivery destination facility group to be delivered (re-grouped (extracted) in the daily vehicle rotation speed determination processing S25) From this, a plurality of supply destination facilities U including the supply destination facilities U for which exchange (delivery) on the day is essential are extracted as a group to be delivered on that day (current day delivery supply destination facility group).
  • the supply destination facility U (the supply destination facility U distributed to the preliminary delivery destination) whose delivery limit date comes within a few days ahead (for example, within the last seven days) is included in the supply destination facility group on that day. Extraction is performed under conditions such as (conditions that can be changed according to the situation).
  • the delivery decision processing S29 for each delivery vehicle further groups (sorts) the delivery destination facilities U included in the delivery delivery destination facility group on the same day according to the loaded amount of delivery vehicles (trucks) in operation, and supplies each delivery vehicle.
  • the destination facility U, the optimum delivery route, the optimum loading capacity, etc. are determined and output as a delivery instruction.
  • Each delivery person completes delivery to the supply destination facility U to be delivered, and registers that fact from the mobile terminal 12 (delivery completion registration process S17 described later), and then becomes the next delivery target from the mobile terminal 12.
  • Information about the supply destination facility U can be acquired.
  • a delivery target acquisition button or the like is displayed on the display means 121 of the mobile terminal 12, for example.
  • the delivery destination facility U to be delivered on the day is further set for each delivery person.
  • the extracted information about the supply destination facility U to be delivered that day is transmitted from the management device 13 to the portable terminal 12 as list data.
  • the daily vehicle dispatch rotation speed determination process S25 can be executed. In this case, for some reason, the delivery person cannot go to the delivery destination facility U for delivery on the day that he / she is responsible for, but the delivery destination facility U for delivery on the day that remains after the delivery location extraction process S13 for each person in charge If they remain, grouping can be performed again based on the information on the remaining supply destination facilities U.
  • a predetermined condition is set based on the delivery plan data, and a combination of a delivery vehicle (vehicle type) and a delivery route is extracted for each load amount.
  • a business rule management system (Business Rule Management System) that manages and executes business rules by a predetermined engine for executing business rules is used for the extraction.
  • a rule for example, an area to be delivered in the same delivery time, a supply destination facility U (delivery person shift within the last few days (for example, 3 days) is considered, If the holiday continues or the delivery is not in time due to winter, etc., it will be put forward.), Priority within the area to be delivered to the same delivery times (delivery in close order, etc.), delivery time (maximum value) , Distance / capacity of gas cylinder (loading capacity), installation mode of gas cylinders for each supply facility U (for example, installation modes such as combinations of two gas cylinders 20 having different capacities, combinations of three of the same capacity, etc.) Set.
  • the delivery becomes inefficient.
  • the delivery destination facility U preliminary delivery destination
  • the optimum loading is performed. The combination of delivery vehicles (optimum loading capacity) by quantity and optimum delivery routes is extracted.
  • the rotation speed is reset, and the optimum loading capacity (delivery vehicle) and the optimum delivery route are extracted again.
  • the optimum delivery route is extracted by using an existing delivery plan system (optimum route extraction system) or the like that can derive an optimum route via each piece of location information by inputting a plurality of pieces of location information.
  • the optimum loading capacity (delivery vehicle) and the optimum delivery route extracted in the above process are possessed by the portable terminal 12 and / or the delivery manager possessed by each deliverer.
  • the data is transmitted to the mobile terminal 12 and displayed on the display unit 121 of the mobile terminal 12.
  • the management device 13 also holds information specific to each LP gas contractor (supply destination facility U) including the information, and displays information related to the delivery destination facility U to be delivered on the portable terminal 12 of the delivery person. Information specific to each LP gas contractor (supplier facility U) is also displayed.
  • the display of the optimum delivery route on the mobile terminal 12 is linked with a known navigation system.
  • the navigation system sequentially performs navigation to the next supply destination facility U according to the optimum delivery route.
  • the delivery person goes to the supply facility U and performs the replacement work of the gas cylinder 20 instructed. At that time, it is confirmed that the content displayed on the display means 121 of the portable terminal 12 matches the information of the supply destination facility U (LP gas contractor) at the exchange place, and the gas cylinder 20 to be collected and the gas cylinder 20 to be arranged are arranged. All the unique barcodes are read, the pointer value of the gas meter 21 is obtained visually, and input to the mobile terminal 12. In addition, when there is a new addition / change of specific information for each LP gas contractor (supplier facility U), information on the addition / change is input.
  • the input of the guideline value, the information specific to the collected gas cylinder 20 and the information specific to each LP gas contractor (supplier facility U) is received as delivery data, and the management device 13 to send. Further, the information regarding the supply destination facility U for which the delivery has been completed is deleted from the portable terminal 12. The delivery person repeats the above operation for all supply destination facilities U on that day.
  • the delivery data transmitted from each portable terminal 12 is acquired, and the information held in the management device 13 is updated for each supply destination facility U (LP gas contractor). Do.
  • the management apparatus 13 adjusts suitably according to the use condition of air conditioning, whether it is bulk storage tank supply, whether the supply destination facility U is a housing complex, whether or not a water heater is used, etc. Do.
  • the actual usage is different from the meter guideline, so the actual usage is calculated by setting the conversion rate.
  • the prediction calculation process S05 is performed, but the delivery is instructed to be delivered by a bulk vehicle.
  • the calculation value S05 is executed after adding the pointer values of the gas meters in the associated rooms.
  • LP gas contractors (supplier facilities U) where hot water heaters are installed can be extracted, and management is performed when the usage increases in winter.
  • the delivery management means 50 may be a conventionally known gas supply (delivery) such as a monthly process for gas supply (delivery) management, a management process for delivery results, a form issuing process, a security check information management process, etc. Various management processes are executed.
  • ⁇ Daily forecast usage calculation method> In the delivery prediction processing S03 (predicted usage calculation processing S04 (prediction calculation processing S05) and limit date calculation processing S06), daily prediction is performed based on the indicated rotational speed, the gas usage (guideline value) included in the gas meter information, and the like.
  • the usage amount, delivery limit date, and delivery plan data can be extracted.
  • the guideline value is not limited to the data automatically acquired from the storage device 30 by the management device 13, but also includes the guideline value actually acquired by the meter reader or the delivery person in the vicinity of the supply destination facility U or in the vicinity thereof.
  • the delivery prediction means 138 calculates a daily forecast usage amount in a future date. At this time, the delivery prediction means 138 calculates the daily predicted usage amount so as to increase or decrease with the passage of days. For example, in winter, the daily forecast usage is calculated so as to increase every day from the beginning of the month to the end of the month, and in summer, the daily forecast usage is calculated so as to decrease from the beginning of the month to the end of the month. Therefore, the delivery prediction means 138 calculates a unit predicted usage change amount (increase or decrease amount per day) for each day based on the reference gas usage amount in the past predetermined period, and based on the unit predicted usage change amount. To calculate the daily forecast usage.
  • the reference gas usage amount in this case is, for example, a reference value that is a set value based on the actual usage amount in a predetermined period in the past at the same time period as the prediction period or the trend of the gas usage in the annual period at the same time period as the prediction period.
  • the amount of gas used is individually set based on the usage trend of LP gas contractors.
  • the delivery prediction means 138 calculates the daily gas residual amount (gas residual amount predicted value) in the future date in the gas cylinder 20 based on the calculated daily predicted usage amount, The estimated date of delivery is determined by predicting the date when the gas remaining amount prediction value is reduced to a predetermined amount.
  • FIG. 14 is a table showing an example of a calculation formula used in the prediction calculation process.
  • a difference occurs between the gas usage amount (previous guide value) of the gas meter information acquired last time and the gas usage amount (current guide value) of the gas meter information acquired this time, and the current guide value This is performed for the gas cylinder 20 (supply destination facility U) in which the actual gas remaining amount based on is less than the prediction start threshold.
  • the daily predicted usage amount of the current month forecast date (M month X day) several days after the date (M month D day) when the gas meter information is acquired is calculated by the following method, for example.
  • the unit predicted usage change amount (increase or decrease amount from the previous day) per day is calculated from the difference (change amount) in the monthly usage amount (actual amount) in the same period of the previous year, and the prediction date is included
  • the number of days from the beginning of the month is integrated to calculate the predicted usage change amount (Equation 1) on the predicted date.
  • Predicted usage change amount on the forecast day (difference between the previous month's (current month) usage and the previous month's usage) / (sum of days from the first day of the current month to the last day) x number of days from the beginning of the month to the forecast date X (Equation 1 )
  • the average daily usage for the previous month is calculated from the base usage for the previous month.
  • the base usage for the previous month is the total usage for the previous month.
  • the average usage per day for the current month of the previous year (this is called “base usage forecast (average)”) is added to the forecasted usage change calculated in (Equation 1), based on the previous month. Calculate the usage forecast amount (formula 2) for the current month forecast day.
  • Daily forecasted usage of the current month's forecast date Forecasted usage of the current month's forecast date + Average value of the change in the previous month's usage and previous year's usage for the current month (Formula 4) (1-2) If you are a person who acquires daily information and the accumulated date of past gas meter information (guideline value) is more than 1 year and 2 months
  • the management device 13 acquires the gas meter information on a daily basis (automatically), the prediction calculation processing S05 is performed on a daily basis from the day when the gas meter information is acquired.
  • the daily estimated usage after X days of the date when the gas meter information was acquired (M month D, Y year) is calculated by the following method.
  • the sum of the usage from 30 days to 60 days before, starting from M / D on year Y is the previous usage of this year, and the usage from 30 to 60 days before the same month the same day of M / D in Y year
  • the sum of the amount is the previous year's use amount
  • the sum of the use amount from the same month the previous year of M / D in Y to 30 days ago is the previous year's use amount.
  • the previous year's usage this year is read as the previous month's usage
  • the previous year's previous usage is read as the previous year's usage
  • the previous year's current usage is read as the previous year's (this month) usage
  • Predicted change in usage on the predicted date (Difference between current usage in the previous year and previous usage in the previous year) / (sum of days from the first day of the current month to the last day) x number of days from the acquisition date of the gas meter to the prediction date X (formula 1)
  • Predicted usage amount for the current month forecast date previous usage amount for the previous year / 30 days + predicted usage change amount for the predicted date (Formula 2)
  • the daily estimated usage of the current month forecast date (M month X day) several days after the date (M month D day) when the gas meter information was acquired is calculated by the following method.
  • Forecast amount of change in forecast date (Difference between previous month's current month coefficient and previous year's previous month coefficient) / (sum of days from the first day of the current month to the last day) x number of days from the beginning of the month to the forecast date X (Formula 1)
  • Predicted amount of use on the predicted date of the current month previous month's previous month coefficient / number of days in the current month + predicted use change amount on the predicted date
  • the above (1) is given priority over the above (2), but the previous month's previous month's usage (previous year's previous usage, previous year's previous month coefficient) and previous year's this month usage (previous year's current usage, previous year's current month). When there is no coefficient, the above (2) is used.
  • the above-mentioned prediction calculation process S05 calculates the total predicted usage after the date when the gas meter information was most recently acquired based on the daily predicted usage after the date when the gas meter information was acquired most recently. .
  • the actual remaining gas amount (gas remaining amount) at the time of obtaining the gas meter information is calculated.
  • the remaining amount of gas is a value obtained by subtracting the total amount of gas used every month after delivery (exchange) from the gas capacity at delivery (exchange). Then, the total predicted usage amount is subtracted from the actual gas remaining amount for each day, and the gas remaining amount predicted value for each day after the date when the gas meter information was most recently acquired is calculated.
  • the most recent date when the gas remaining amount prediction value falls below the delivery limit threshold (limit rate) is specified, and the date before the limit number of days (for example, 3 days) is determined as the delivery limit date.
  • the delivery limit threshold and the limit number of days are values that are individually set in advance depending on the usage status of each LP gas contractor (supplier facility U). (Concrete example)
  • the prediction calculation process S05 is executed on November 15, 2017 (acquisition of gas meter information) will be specifically described.
  • it is an LP gas contractor other than the above-mentioned daily information acquisition target in (1-1), or the daily information acquisition target, and the accumulated date of the past gas meter information (guideline value) is The case of less than 1 year and 2 months will be explained.
  • FIG. 15 (a) is an example of actual usage (actual values) from September to November of the previous year (2016).
  • the base usage for each month is the total usage for the previous month.
  • FIG. 5B is a conceptual diagram of the predicted usage change amount and the daily predicted usage amount calculated by (Equation 1).
  • FIG. 11C is a daily forecast usage table for November 2017 calculated by the forecast calculation process S05.
  • FIG. 16A is a graph conceptually showing the daily predicted usage.
  • FIG. 16B is a limit date calculation table based on FIG.
  • the previous month's usage (October 2016) is 20 cubic meters
  • the previous month's usage (November 2016) is 29 cubic meters.
  • the previous month's usage (October 2017) is assumed to be 25 cubic meters.
  • the sum of the days from the first day of the current month (November 2017) to the last day (30th) is 465 days, and the number of days from the beginning of the predicted day) X is 15 days.
  • Equation 1 the difference (change) between the previous month's usage this month and the previous month's usage shown in dot hatching in the same figure (b) is the sum of the days from the first day to the last day of the current month. Is excluded.
  • the unit predicted usage change amount per day of the current month is calculated as indicated by hatched hatching in FIG.
  • the predicted use change amount on the prediction date June 15 is obtained.
  • the daily forecast usage table shown in (c) of the figure is created once a month (for example, the daily forecast for the next month at the end of the month). Create a usage table).
  • a daily predicted usage table for one month is created (updated) on a daily basis (daily).
  • the predicted usage amount of the current month calculated by (Equation 2) (the total usage amount of the previous month of the previous year is averaged by the number of days in the current month), Predicted usage change amount (Equation 1) calculated to increase or decrease every day, plus the average value per day of this month (Equation 3) of the previous month's previous month's usage and this month's previous month's usage Then, the daily forecast usage is calculated.
  • the broken line in FIG. 9A is a comparative example, and the average amount of change is obtained by dividing the past month's usage (actual amount) by the number of months, and the average value of the change is used as a reference. It is the result of the prediction method added to the base usage amount of the current month (forecast date).
  • the amount of gas used actually increases or decreases from day to day according to seasonal changes. That is, if the amount of change is averaged as shown by the broken line in FIG. 9A, for example, the estimated date of delivery is calculated at the end of the month, and the gas may be deficient before the gas cylinder 20 is replaced. Becomes higher.
  • the predicted usage change amount is calculated so as to increase or decrease from day to day (in the figure (a), increase), for example, when the scheduled delivery date is calculated at the end of the month. Even if it exists, it becomes easy to follow the actual situation, and it is possible to avoid the risk of gas shortage before replacing the gas cylinder 20.
  • the average change amount per day (previous year ⁇ change this year (average)) of the previous year's previous year's usage amount and this year's previous usage change amount is also added. Quantity prediction is possible.
  • a limit date calculation table is created based on the predicted usage change amount.
  • the values after that day (November 16, 2017 to November 30, 2017) are obtained.
  • the contents of the gas meter information (actual value) acquired on November 15, 2017 are as follows: the remaining amount of gas is 15 cubic meters, and the capacity of the gas cylinder 20 of the supply destination facility U is 100 cubic meters (50 kg ⁇ 2) in total. It is assumed that the delivery limit threshold is set to 5% and the limit days are set to 3 days.
  • the most recent date (November 24 in this example) where the ratio of the gas remaining amount prediction value to the total capacity of the gas cylinder 20 in the supply destination facility U falls below the delivery limit threshold (limit rate) is specified, and from that date Also, the date (November 21 in this example) before the limit number of days (3 days) is determined as the limit date of delivery.
  • the delivery prediction process has been described with a specific example, but the delivery prediction process of the present embodiment is not limited to the above example. That is, gas meter information is acquired more frequently than once a week (for example, daily), daily forecast usage is calculated so that it increases or decreases every day, and LP gas contractors are informed of gas shortages, etc. If it is possible to calculate the delivery limit date when the estimated amount of gas remaining is as low as possible without causing a risk, and predict the optimal delivery route for each person in charge of delivery (delivery person) and delivery vehicle Good.
  • the management device 13 can automatically acquire gas meter information remotely at an arbitrary timing.
  • the management apparatus 13 can grasp
  • an optimal delivery date and an efficient delivery route for delivering the gas cylinder 20 are predicted, and a process until the number of gas cylinders 20 loaded on a plurality of delivery vehicles is instructed automatically is performed.
  • the gas meter information may be collected by the portable terminal 12 in the same manner as in the first embodiment, in addition to automatic acquisition by the management device 13 (delivery management means 50).
  • the mobile terminal 12 receives and collects the gas meter information transmitted from the information transmission device 11, and transmits (uploads) the gas meter information to the management device 13 via the network NW1 (or network NW3). Good (see FIG. 1).
  • NW3 LPWA network
  • the meter reader has the portable terminal 12 as described in the first embodiment, goes to the area to be metered, and displays the gas meter information. Can be collected.
  • each device (hardware) constituting the gas supply management system 10 may be replaced with software that realizes a function equivalent to the device (hardware).
  • gas supply management system 10 and the like of the present invention are not limited to the above-described embodiments, and it is needless to say that various modifications can be made without departing from the gist of the present invention.
  • Gas Supply Management System 11 Information Transmitting Means (Information Transmitting Device) DESCRIPTION OF SYMBOLS 12 Mobile terminal 13 Management apparatus 14 Server apparatus 20 for business operators Gas cylinder 21 Gas meter 22 External terminal 23 Connection means 25 Gas supply pipe 50 Delivery management means 111 Connection part 112 Acquisition part 113 Communication part 114 Battery 115 Control part 116 Memory 117 Information transmission request Reception means 118 Individual information transmission means 121 Display means 122 Input means 123 Memory 124 Communication means 127 Geographic information display means 128 Information transmission request means 129 Information reception / transmission means 133 Storage means (storage device) 134 Input means 135 Output means 136 Communication means 137 Usage amount calculation means 138 Delivery prediction means 139 Geographic information display means NW Network NW1 Network NW2 Network NW3 Network

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Abstract

[Problem] To provide a gas supply management system, a gas supply management method, and an information transmission device with which tasks such as meter-reading/safety maintenance/delivery of LP gas can be efficiently performed, and the cost and labor related to installation can also be reduced. [Solution] The gas supply management system 10 is equipped with information transmission means 11, collection means 31, and a management means 13. The information transmission means 11 are respectively connected to gas meters 21 disposed on gas containers 20 in multiple supply-destination facilities U, acquire information from the gas meters 21, and transmit the information to the collection means 31. The collection means 31 collect the information transmitted from the information transmission means 11. The management means 13 calculates a gas consumption amount of each of the gas containers 20 on the basis of the information by using a consumption amount calculation means 137 and estimates a scheduled delivery date of the gas container 20 to each of the supply-destination facilities U by using a delivery estimation means 138.

Description

ガス供給管理システム、ガス供給管理方法、情報送信装置Gas supply management system, gas supply management method, information transmission device
 本発明は、液化石油(LP)ガスの検針や配送を効率よく行うためのガス供給システム、ガス供給方法および情報送信装置に関する。 The present invention relates to a gas supply system, a gas supply method, and an information transmission device for efficiently performing meter reading and delivery of liquefied petroleum (LP) gas.
 従来、複数の供給先施設に配置されるLPガスの使用量の検針や、ガス使用状態の監視などを集中して行う方法として、ガスメータに通信用の伝送装置(NCU)を接続し、通信回線を介して、集中管理装置に接続することで、LPガスボンベのガス残量を検知し、料金を徴収するシステムが知られている(例えば、特許文献1参照)。 Conventionally, as a method of concentrating the metering of the amount of LP gas used at multiple supply facilities and monitoring the gas usage state, a communication transmission unit (NCU) is connected to a gas meter, and a communication line is connected. There is known a system that detects a remaining amount of gas in an LP gas cylinder and collects a charge by connecting to a centralized management apparatus via the terminal (for example, see Patent Document 1).
 また、都市ガス事業者においては、高速でパケット通信が可能な新しい通信インターフェイス(Uバス)に接続可能なスマートメータを用いて、保安監視、遠隔遮断操作、自動検針を行うガススマートメータシステムの開発も行われている。 In addition, city gas companies will develop a gas smart meter system that performs safety monitoring, remote shut-off operation, and automatic meter reading using a smart meter that can be connected to a new communication interface (U-bus) capable of high-speed packet communication. Has also been done.
特開2008-117247号公報JP 2008-117247 A
 しかしながら、現状では上記システムには様々な問題があり、LPガスの使用量の検針や配送を効率よく行うガス供給システムとしての普及は進んでいない。その問題の一つとして、自動でLPガスメータからの情報を取得し、管理装置に当該情報を送信するための通信装置(例えば、上記の伝送装置や、ガススマートメータなどの装置)の駆動電源を確保するための電気工事、および当該通信装置や通信回線との接続工事が必須であり、そのコストが人手による定期的な(例えば、一月に一回など)の検針にかかる人件費と比較して、高額になることが挙げられる。また、現状ではLPガスの顧客(契約者)側の通信インフラに依存しなければならない場合も多く、通信技術の変化に合わせてその都度工事や設定が必要となり、それにかかるコストの増加や管理の手間が増えるといった問題もある。 However, at present, there are various problems with the above system, and it has not been widely used as a gas supply system for efficiently performing meter reading and delivery of LP gas usage. As one of the problems, a drive power source of a communication device (for example, the above-mentioned transmission device or device such as a gas smart meter) for automatically acquiring information from the LP gas meter and transmitting the information to the management device is used. Electrical work to ensure and connection work with the communication device or communication line is essential, and the cost is compared with the labor cost for periodic manual inspection (eg once a month). Can be expensive. In addition, at present, there are many cases where it is necessary to rely on the communication infrastructure on the LP gas customer (contractor) side, and construction and settings are required each time the communication technology changes. There is also a problem that the labor is increased.
 また、都市ガスにおいては開発が進んでいるガススマートメータシステムであっても、都市ガスメータとは異なるLPガスメータ特有の事情により、そのまま利用することは困難である。具体的には、(1)LPガスメータは、情報をネットワークへアップロードするための電源を持たなない、(2)LPガス事業者毎に見るとLPガスメータの所在が所定の範囲(地域)内であっても密集することなく点在しており、LPガスメータ間での情報のリレーションが困難である、(3)LPガスメータの所有者(LPガスの供給事業者)が例えば所定範囲(地域)の顧客であっても異なる場合があり、所定範囲(地域)のあるいは全ての顧客の情報を網羅的に取得するための通信を実現する外部インフラが整備されていない、などの問題があり、スマートメータ化が進んでいない。 In addition, even a gas smart meter system that has been developed for city gas is difficult to use as it is due to circumstances specific to LP gas meters that are different from city gas meters. Specifically, (1) The LP gas meter does not have a power source for uploading information to the network. (2) The location of the LP gas meter is within a predetermined range (region) when viewed by each LP gas company. Even if there is, it is scattered without being crowded, and it is difficult to relate information between LP gas meters. (3) The owner of the LP gas meter (LP gas supplier) is in a predetermined range (region), for example. Even if it is a customer, there may be differences, and there is a problem such as the lack of an external infrastructure to realize communication for comprehensively acquiring information of a predetermined range (region) or all customers. It is not progressing.
 さらに、LPガスの使用量の検針や配送を効率よく行うための上記のようなガス供給システムが普及しない要因としてLPガス事業者特有の事情もある。具体的には、LPガスの供給事業者が異なると、隣家であっても別の検針員による検針が必要となり、検針作業が非効率となる。また、検針は自動化できたとしても、ガス容器(ガスボンベ)の配送は必須であり、隣家であってもガス容器の配送者が異なると配送(交換)することはできない。その上、現状では月次でLPガスメータの検針(指針値の取得)を行っており、使用量の予測精度が低いため、消費者がLPガスを使用できない自体を避けるため、ガス容器内に十分なガスが存在している状態で交換を行わなければならない。このように、配送の観点においても非効率なものとなっている。また、例えスマートメータのような新規なLPガスメータが開発された場合であっても、LPガスメータの利用期限は製造から10年が目安となっており、LPガス事業者の経営資源や事業規模によってはLPガスメータへの投資が消極的な場合もあり、一括的なLPガスメータの交換は行いにくい状況にある。 Furthermore, there is a situation peculiar to LP gas companies as a factor that the above gas supply system for efficiently performing meter reading and delivery of LP gas is not widespread. Specifically, if the LP gas supplier is different, meter reading by another meter reader is required even if it is a neighbor, and meter reading work becomes inefficient. Even if the meter reading can be automated, delivery of the gas container (gas cylinder) is indispensable, and even if it is a neighbor, delivery (exchange) is not possible if the delivery person of the gas container is different. In addition, currently, the LP gas meter is read monthly (acquisition of the guideline value), and the usage accuracy is low, so that consumers cannot use LP gas. Exchange must be performed in the presence of a fresh gas. Thus, it is inefficient from the viewpoint of delivery. Even if a new LP gas meter such as a smart meter is developed, the expiration date of the LP gas meter is 10 years from the date of manufacture, and it depends on the management resources and business scale of the LP gas company. In some cases, investment in LP gas meters is reluctant, and it is difficult to replace LP gas meters in a batch.
 本発明は、上記課題に鑑みてなされ、検針・保安・配送などの業務を効率的に行うことが可能であるとともに、導入に関するコストや手間を抑えることができる、ガス供給管理システム、ガス供給管理方法および情報送信装置を提供することを目的とする。 The present invention has been made in view of the above problems, and can efficiently perform operations such as meter reading, security, and delivery, and can reduce costs and labor related to introduction, a gas supply management system, and gas supply management It is an object to provide a method and an information transmission apparatus.
 本発明は、情報送信手段と、収集手段と、管理手段とを備えたガス供給管理システムであって、前記情報送信手段は、複数の供給先施設のガス容器に対応したガスメータとそれぞれ接続し、該ガスメータからの情報を取得して前記収集手段に送信し、前記収集手段は、前記情報送信手段から送信された前記情報を収集し、前記管理手段は、使用量算出手段と、配送予測手段と、を有し、前記収集手段が収集した前記情報をネットワークを介して取得し、前記情報に基づき、前記使用量算出手段によって前記ガス容器ごとのガス使用量を算出して出力し、前記配送予測手段によって前記供給先施設ごとに前記ガス容器の配送の予定日を予測する、ことを特徴とするガス供給管理システムである。 The present invention is a gas supply management system comprising an information transmission means, a collection means, and a management means, wherein the information transmission means is connected to gas meters corresponding to gas containers of a plurality of supply destination facilities, Information from the gas meter is acquired and transmitted to the collecting means, the collecting means collects the information transmitted from the information transmitting means, and the managing means includes a usage calculating means, a delivery predicting means, The information collected by the collection means is acquired via a network, and based on the information, the usage calculation means calculates and outputs the gas usage for each gas container, and the delivery prediction The gas supply management system according to claim 1, wherein a scheduled delivery date of the gas container is predicted for each supply destination facility by means.
 また、本発明は、情報送信手段と、収集手段と、管理手段とを用いるガス供給管理方法であって、複数の供給先施設のガス容器に対応したガスメータとそれぞれ接続する情報送信手段によって前記ガスメータからの情報を取得して前記収集手段に送信するステップと、前記管理手段が、前記収集手段が収集した前記情報をネットワークを介して取得し、該情報に基づき、前記ガス容器ごとのガスの使用量を算出して出力するステップと、前記情報に基づき、前記供給先施設ごとに前記ガス容器の次回の配送の予定日を予測するステップと、を有する、ことを特徴とするガス供給管理方法である。 The present invention is also a gas supply management method using an information transmission means, a collection means, and a management means, wherein the gas meter is connected to a gas meter corresponding to a gas container of a plurality of supply destination facilities, respectively. Acquiring the information from the transmission means and transmitting the information to the collection means, and the management means obtains the information collected by the collection means via a network, and uses the gas for each gas container based on the information. A gas supply management method comprising: calculating and outputting an amount; and predicting a next delivery date of the gas container for each supply destination facility based on the information. is there.
 また、本発明は、上記のガス供給管理方法をコンピュータに実行させることを特徴とするプログラムである。 Further, the present invention is a program characterized by causing a computer to execute the above gas supply management method.
 また、本発明は、交換可能な電池と、複数の供給先施設のガス容器に対応したガスメータの外部端子にそれぞれ接続する接続部と、前記ガスメータからの情報を取得する取得部と、前記情報をネットワークを介して収集装置に送信可能な通信部と、を備えた情報送信装置である。 Further, the present invention provides a replaceable battery, a connection unit connected to each external terminal of a gas meter corresponding to a gas container of a plurality of supply destination facilities, an acquisition unit for acquiring information from the gas meter, and the information And a communication unit capable of transmitting to the collection device via the network.
 本発明によれば、検針・保安・配送などの業務を効率的に行うことが可能であるとともに、導入に関するコストや手間を少なく抑えることができる、ガス供給管理システム、ガス供給管理方法および情報送信装置を提供することができる。 According to the present invention, a gas supply management system, a gas supply management method, and information transmission that can efficiently perform operations such as meter reading, security, and delivery and can reduce costs and labor related to introduction can be reduced. An apparatus can be provided.
本発明の一実施形態に係るガス供給管理システムの構成を模式的に示す概要図である。It is a schematic diagram showing typically the composition of the gas supply management system concerning one embodiment of the present invention. 本発明の一実施形態に係る情報送信装置を説明する図であり、(a)情報送信装置の構成を模式的に示す概略図、(b)情報送信装置の構成を示すブロック図、(c)情報送信装置の機能を示すブロック図である。BRIEF DESCRIPTION OF THE DRAWINGS It is a figure explaining the information transmitter which concerns on one Embodiment of this invention, (a) The schematic which shows typically the structure of an information transmitter, (b) The block diagram which shows the structure of an information transmitter, (c) It is a block diagram which shows the function of an information transmitter. 本発明の一実施形態に係る携帯端末を説明する図であり、(a)携帯端末の構成を示すブロック図、(b)携帯端末の機能を示すブロック図である。It is a figure explaining the portable terminal which concerns on one Embodiment of this invention, (a) The block diagram which shows the structure of a portable terminal, (b) The block diagram which shows the function of a portable terminal. 本発明の一実施形態に係る管理装置を説明する図であり、(a)管理装置の構成を示すブロック図、(b)管理装置の機能を示すブロック図であり、(c)管理装置の情報の管理の一例を示す概要図である。。It is a figure explaining the management apparatus which concerns on one Embodiment of this invention, (a) The block diagram which shows the structure of a management apparatus, (b) The block diagram which shows the function of a management apparatus, (c) Information of management apparatus It is a schematic diagram which shows an example of management of. . 本発明の一実施形態に係る配送予測手段による配送予定日の予測方法について説明する概略図である。It is the schematic explaining the prediction method of the scheduled delivery date by the delivery prediction means which concerns on one Embodiment of this invention. 本発明の一実施形態に係る配送予測手段による配送経路の予測方法について説明する概略図である。It is the schematic explaining the prediction method of the delivery route by the delivery prediction means concerning one Embodiment of this invention. 本発明の一実施形態に係るガス供給管理システムにおける、情報送信装置、携帯端末および管理装置の処理を示すタイミングチャートである。It is a timing chart which shows processing of an information transmitter, a personal digital assistant, and a management device in a gas supply management system concerning one embodiment of the present invention. 本発明の一実施形態に係る地理情報表示手段の表示の一例を示す図である。It is a figure which shows an example of the display of the geographic information display means which concerns on one Embodiment of this invention. 本発明の一実施形態に係る(a)使用量データの一例を示す図であり、(b)配送予測データの一例を示す図である。It is a figure which shows an example of (a) usage-amount data which concerns on one Embodiment of this invention, (b) It is a figure which shows an example of delivery prediction data. 本発明の一実施形態に係るガス供給管理システムの構成を模式的に示す概要図である。It is a schematic diagram showing typically the composition of the gas supply management system concerning one embodiment of the present invention. 本発明の一実施形態に係る管理装置を説明する図であり、(a)管理装置の構成を模式的に示す概略図、(b)管理装置の機能を示すブロック図である。It is a figure explaining the management apparatus which concerns on one Embodiment of this invention, (a) The schematic diagram which shows typically the structure of a management apparatus, (b) The block diagram which shows the function of a management apparatus. 本発明の一実施形態に係る配送管理手段と携帯端末における処理の一例を示す概要図である。It is a schematic diagram which shows an example of the process in the delivery management means and portable terminal which concerns on one Embodiment of this invention. 本発明の一実施形態に係る閾値を説明する図である。It is a figure explaining the threshold value which concerns on one Embodiment of this invention. 本発明の一実施形態に係る予測計算処理で用いる計算式の一例を示す表である。It is a table | surface which shows an example of the calculation formula used with the prediction calculation process which concerns on one Embodiment of this invention. 本発明の一実施形態に係る予測計算処理を説明する図である。It is a figure explaining the prediction calculation process which concerns on one Embodiment of this invention. 本発明の一実施形態に係る予測計算処理を説明する図である。It is a figure explaining the prediction calculation process which concerns on one Embodiment of this invention.
 <第1実施形態>
 <全体構成>
 以下、図面を参照して本実施形態におけるガス供給管理システムについて説明する。図1は、本実施形態のガス供給管理システム10の構成を模式的に示す概要図であり、図2(a)は、本実施形態の情報送信手段11の構成を模式的に示す概略図であり、図2(b)は情報送信手段11の構成を示すブロック図であり、同図(c)は情報送信手段11の機能を示すブロック図である。
<First Embodiment>
<Overall configuration>
Hereinafter, the gas supply management system in the present embodiment will be described with reference to the drawings. FIG. 1 is a schematic diagram schematically illustrating the configuration of the gas supply management system 10 of the present embodiment, and FIG. 2A is a schematic diagram schematically illustrating the configuration of the information transmission unit 11 of the present embodiment. FIG. 2B is a block diagram showing a configuration of the information transmission unit 11, and FIG. 2C is a block diagram showing a function of the information transmission unit 11.
 図1に示すように、ガス供給管理システム10は、液化石油(LP)ガスの複数の供給先施設Uにそれぞれ備えられたLPガスメータ21からの情報を月次より高い頻度(例えば、1ヶ月に1度や1週間に1度などの頻度よりも高い(多い)頻度)で収集することにより、LPガスの検針・保安・配送などの業務を効率的に行うものであり、各LPガスメータ21と接続し、各LPガスメータ21からの情報を取得する情報送信手段(情報送信装置)11と、情報送信装置11とネットワーク(通信回線)NW1を介して通信可能に接続された複数の携帯端末12と、ネットワークNW1に接続する管理手段(管理装置)13と、管理装置13とネットワークNW2を介して接続する事業者用サーバ装置14と、を有する。ここで供給先施設Uは、例えばLPガスの契約者の居住施設(一般家庭の戸建住宅、集合住宅、事務所等)の敷地内またはその近隣に設けられたLPガス設置施設であり、LPガスの設置場所をいう。 As shown in FIG. 1, the gas supply management system 10 displays information from the LP gas meters 21 respectively provided in a plurality of liquefied petroleum (LP) gas supply destination facilities U at a frequency higher than monthly (for example, in one month). By collecting at a frequency that is higher (more frequent) than once a week or once a week, LP gas meter reading, security, delivery, etc. are performed efficiently. Information transmitting means (information transmitting device) 11 that connects and acquires information from each LP gas meter 21, and a plurality of portable terminals 12 that are communicably connected to information transmitting device 11 via network (communication line) NW1 And a management means (management device) 13 connected to the network NW1, and a provider server device 14 connected to the management device 13 via the network NW2. Here, the supply facility U is, for example, an LP gas installation facility provided in or near the site of a residential facility (a detached house, an apartment house, an office, etc.) of an LP gas contractor. This is where the gas is installed.
 携帯端末12と情報送信装置11および管理装置13が接続するネットワークNW1は例えば無線の移動体通信網(基地局等を含む)や、WiFi(登録商標)のような無線LAN方式による無線データ通信網、近距離無線通信規格(Bluetooth(登録商標)のような無線PAN方式)による無線データ通信網、WiMAX(登録商標)のような無線MAN方式、無線WAN方式などによる無線データ通信網であり、管理装置13と事業者用サーバ装置14とが接続するネットワークNW2は例えば、LAN、インターネット、または専用通信回線(例えば、CATV(Community Antenna Television)回線)、及びゲートウェイ等により構築される通信回線である。なお、ネットワークNW2は、各装置間で相互に通信可能な回線であればよく、また、通信の形態は有線/無線を問わない。 The network NW1 to which the portable terminal 12, the information transmission device 11, and the management device 13 are connected is, for example, a wireless mobile communication network (including a base station) or a wireless data communication network using a wireless LAN system such as WiFi (registered trademark). A wireless data communication network based on a short-range wireless communication standard (a wireless PAN system such as Bluetooth (registered trademark)), a wireless MAN system such as WiMAX (registered trademark), a wireless data communication network based on a wireless WAN system, etc. The network NW2 to which the device 13 and the server device for business 14 are connected is a communication line constructed by, for example, a LAN, the Internet, or a dedicated communication line (for example, a CATV (Community Antenna Television) line) and a gateway. The network NW2 only needs to be a line that can communicate with each other, and the form of communication may be wired or wireless.
 <情報送信手段>
 図1および図2(a)に示すように、情報送信装置11は、複数のLPガスの供給先施設Uに配置されるガス容器(ガスボンベ)20のそれぞれに対応したLPガスメータ21と接続し、LPガスメータ21からの情報(以下、ガスメータ情報という)を取得して携帯端末12に送信する装置である。
<Information transmission means>
As shown in FIG. 1 and FIG. 2 (a), the information transmitting apparatus 11 is connected to LP gas meters 21 corresponding to the gas containers (gas cylinders) 20 arranged in a plurality of LP gas supply destination facilities U, It is a device that acquires information from the LP gas meter 21 (hereinafter referred to as gas meter information) and transmits it to the portable terminal 12.
 図2(b)、同図(c)に示すように、情報送信装置11は、例えば、LPガス供給管25に取り付けられ、各LPガスメータ21の外部端子22と有線の接続手段23を介して接続する接続部111と、各LPガスメータ21のガスメータ情報を取得し記憶する取得部112と、携帯端末12との間でネットワークNWを介して無線通信を行うための通信部113と、電池114と、各種構成を制御する制御部115と、メモリ116等を備える。 As shown in FIG. 2B and FIG. 2C, the information transmission device 11 is attached to, for example, an LP gas supply pipe 25, and is connected to an external terminal 22 of each LP gas meter 21 via a wired connection means 23. A connection unit 111 to be connected, an acquisition unit 112 that acquires and stores gas meter information of each LP gas meter 21, a communication unit 113 for performing wireless communication with the portable terminal 12 via the network NW, and a battery 114 And a control unit 115 for controlling various components, a memory 116, and the like.
 ここで、「ガスメータ情報」とは、個々のLPガスメータ21(ガスボンベ20)を識別可能な固有番号(例えば、製造番号)と、ガスボンベ20ごとの所定期間におけるガス使用量を示す指針値および保安情報(個々のガスボンベ20の圧力を監視し、ガス漏れ等を検知するための情報)と、これらの情報の取得日(検針日)を少なくとも含む情報である。 Here, the “gas meter information” refers to a unique number (for example, a production number) that can identify each LP gas meter 21 (gas cylinder 20), a guideline value indicating the amount of gas used for each gas cylinder 20 in a predetermined period, and security information. (Information for monitoring the pressure of each gas cylinder 20 and detecting gas leakage and the like) and information including at least the acquisition date (meter reading date) of these pieces of information.
 情報送信装置11は、内蔵の電池(LPガスメータとともにあるいは単独で交換可能な充電池(リチウムイオンバッテリーなど))114を電源とし、制御部115によってメモリ116に記憶されている情報送信装置11全体の動作を実現するための各種のソフトウェアプログラム等を実行する処理や、制御信号やデータの転送処理を行う処理などを行う。 The information transmission device 11 uses a built-in battery (a rechargeable battery (such as a lithium ion battery) that can be exchanged together with the LP gas meter) 114 as a power source, and controls the entire information transmission device 11 stored in the memory 116 by the control unit 115. Processing for executing various software programs for realizing the operation, processing for transferring control signals and data, and the like are performed.
 メモリ116には、情報送信処理などを行うソフトウェアプログラムが格納され、当該プログラムが実行されることにより、情報送信装置11は、情報送信処理を実行する。この情報送信処理により、情報送信装置11は携帯端末12からの情報送信要求を受信する情報送信要求受信手段117および、LPガスメータごとのガスメータ情報を携帯端末12に送信する個別情報送信手段118などとしての機能を実現する(同図(c))。 The memory 116 stores a software program for performing an information transmission process, and the information transmission apparatus 11 executes the information transmission process by executing the program. As a result of this information transmission processing, the information transmission apparatus 11 includes an information transmission request receiving unit 117 that receives an information transmission request from the portable terminal 12, and an individual information transmission unit 118 that transmits gas meter information for each LP gas meter to the portable terminal 12. (C) in FIG.
 情報送信要求受信手段(情報送信要求受信処理)117は、通信部113を介して、周期的に(例えば、30秒に1回のタイミングで)携帯端末12からの情報送信要求を受信する。すなわち、例えば情報送信装置11は、情報送信要求受信手段117が機能しない待機モードと情報送信要求受信手段11が機能する受信モードとが周期的に自動で切り替わる。つまり、周期的に情報送信要求受信手段11が機能する。また、個別情報送信手段(個別情報送信処理)118は、情報送信要求受信手段117によって情報送信要求を受信した場合に、接続部111を介してLPガスメータ21からガスメータ情報を取得して、または、予め定期的に取得しメモリ116等に記憶してあるガスメータ情報を、ネットワークNWを介して携帯端末12に送信(無線送信)する。 Information transmission request reception means (information transmission request reception processing) 117 receives information transmission requests from the mobile terminal 12 periodically (for example, once every 30 seconds) via the communication unit 113. That is, for example, in the information transmission apparatus 11, the standby mode in which the information transmission request reception unit 117 does not function and the reception mode in which the information transmission request reception unit 11 functions periodically switch automatically. That is, the information transmission request receiving unit 11 functions periodically. Further, the individual information transmission means (individual information transmission processing) 118 acquires the gas meter information from the LP gas meter 21 via the connection unit 111 when the information transmission request reception means 117 receives the information transmission request, or Gas meter information that is periodically acquired in advance and stored in the memory 116 or the like is transmitted (wireless transmission) to the mobile terminal 12 via the network NW.
 <携帯端末>
 図3を参照して携帯端末12について説明する。同図(a)は、携帯端末12の構成を示すブロック図であり、同図(b)は、携帯端末12の機能を示すブロック図である。
<Mobile device>
The mobile terminal 12 will be described with reference to FIG. FIG. 2A is a block diagram showing the configuration of the mobile terminal 12, and FIG. 2B is a block diagram showing the function of the mobile terminal 12.
 同図(a)に示すように、携帯端末12は、LPガスメータ21の検針員(検針者)、ガスボンベ20の配送者、あるいはLPガスの供給元の担当者が携行する端末装置、またはガスボンベ20の配送車両等に取り付けられた移動体通信が可能な端末装置であり、情報送信装置11から送信されたガスメータ情報を受信・収集して、ネットワークNW1を介して管理装置13に当該ガスメータ情報を送信(アップロード)する。携帯端末12は、例えば従来公知のスマートフォン、タブレット型端末、PDA(Personal Digital Assistant)などが好適であるが、ノートパソコン、移動体通信が可能なハンディターミナル(専用端末)、携帯電話などによっても実現することができる。ここで、LPガスの「供給元」とは例えば、各LPガス事業者、各LPガス事業者の支店、充填所、配送センタ、小売事業者など、LPガスの契約者(消費者)に対して、LPガスを供給する者の総称である。 As shown in FIG. 2A, the portable terminal 12 is a terminal device carried by a meter reader (meter meter) of the LP gas meter 21, a deliverer of the gas cylinder 20, or a person in charge of the LP gas supply source, or the gas cylinder 20 Is a terminal device attached to a delivery vehicle or the like capable of mobile communication, receives and collects gas meter information transmitted from the information transmitting device 11, and transmits the gas meter information to the management device 13 via the network NW1. (Upload). The mobile terminal 12 is preferably a conventionally known smartphone, tablet terminal, PDA (Personal Digital Assistant), etc., but can also be realized by a notebook computer, a handy terminal (dedicated terminal) capable of mobile communication, a mobile phone, etc. can do. Here, “supplier” of LP gas refers to LP gas contractors (consumers) such as LP gas companies, branches of each LP gas company, filling stations, distribution centers, retailers, etc. It is a general term for those who supply LP gas.
 携帯端末12は、CPU(制御手段)120、表示手段(表示部、ディスプレイ)121、入力手段122、メモリ123、通信手段124などを有する。入力手段122は、携帯端末12に文字、画像、音声等の情報を入力する手段の総称であり、例えば、文字を入力するキーボード(タッチパネル)、対象を撮影し画像として入力(記憶)するカメラ、音声を入力(記憶)するマイクなどである。 The portable terminal 12 includes a CPU (control unit) 120, a display unit (display unit, display) 121, an input unit 122, a memory 123, a communication unit 124, and the like. The input means 122 is a general term for means for inputting information such as characters, images, and voices to the mobile terminal 12, and includes, for example, a keyboard (touch panel) for inputting characters, a camera that captures an object and inputs (stores) it as an image, A microphone for inputting (storing) audio.
 CPU120は、メモリ123に格納されている携帯端末13全体の動作を実現するための各種のソフトウェアプログラム(アプリケーションプログラム)やオペレーティングシステム(OS)等を実行する処理や、、プログラムの実行に必要なデータやファイル等をメモリ123等に記憶する処理などを行う。 The CPU 120 performs processing for executing various software programs (application programs), operating systems (OS), etc. for realizing the operation of the entire mobile terminal 13 stored in the memory 123, and data necessary for executing the programs. And processing for storing the file and the like in the memory 123 and the like.
 通信手段124は、情報送信装置11および管理装置13とネットワークNW1を介して通信を行う。 The communication unit 124 communicates with the information transmission apparatus 11 and the management apparatus 13 via the network NW1.
 メモリ123には、情報収集処理などを行うソフトウェアプログラム(アプリケーションプログラム)が格納され、当該プログラムが実行されることにより、携帯端末12は、情報収集処理を実行する。この情報収集処理には、地理情報表示処理、情報送信要求処理、および情報受付送信処理が含まれ、これにより携帯端末12は、地理情報表示手段127、情報送信要求手段128、および情報受付送信手段129などとしての機能を実現する(同図(b))。 The memory 123 stores a software program (application program) for performing information collection processing and the like, and the portable terminal 12 executes information collection processing by executing the program. This information collection process includes a geographic information display process, an information transmission request process, and an information acceptance transmission process, whereby the portable terminal 12 can receive the geographic information display means 127, the information transmission request means 128, and the information acceptance transmission means. The function as 129 or the like is realized ((b) in the figure).
 地理情報表示手段(地理情報表示処理)127は、電子地図上に少なくともガスボンベ20(およびガス管等)の位置情報を重ねて表示した所謂マッピングシステムを実現するアプリケーションプログラム(これにより実行される処理)である。地理情報表示手段127によって、携帯端末12の位置を中心とした所定範囲(距離)内の電子地図およびそこに存在する同一の供給元(例えば、LPガス事業者(またはその支店や小売事業者等))の保有する(同一ガス事業者と契約している消費者の)ガスボンベ20の位置情報を把握することができる。具体的には、携帯端末12がある情報取得ポイント(検針ポイント)に存在する場合、地理情報表示手段127によって、当該情報取得ポイントから所定範囲(例えば、情報取得ポイントを中心として半径200m~300m程度の範囲、距離)内の電子地図およびその範囲内に存在する同一の供給元の検針対象となるガスボンベ20(LPガスメータ21)の位置を、携帯端末12の表示手段121に表示させることができる。 The geographic information display means (geographic information display processing) 127 is an application program that implements a so-called mapping system that displays at least the position information of the gas cylinder 20 (and gas pipes) on the electronic map (processing executed thereby). It is. An electronic map within a predetermined range (distance) centered on the position of the mobile terminal 12 and the same supplier (for example, an LP gas company (or its branch or retailer) etc. are present by the geographical information display means 127. )) Possessed (consumer who has contracted with the same gas company), the position information of the gas cylinder 20 can be grasped. Specifically, when the mobile terminal 12 is present at a certain information acquisition point (meter reading point), the geographic information display means 127 causes a predetermined range (for example, a radius of about 200 m to 300 m centering on the information acquisition point) from the information acquisition point. And the position of the gas cylinder 20 (LP gas meter 21) as the metering target of the same supply source existing within the range can be displayed on the display means 121 of the portable terminal 12.
 情報送信要求手段(情報送信要求処理)128は、情報送信装置11に対して任意のタイミングで所定期間(情報送信要求受信手段117の受信周期(この例では30秒)より長い期間(例えば、1分間など))に亘り、情報送信要求を送信し、情報送信装置11から送信されたガスメータ情報を受信して、ガスボンベ20(供給先施設)の位置情報と紐付けて、管理装置13に対して当該ガスメータ情報を送信する。 The information transmission request means (information transmission request processing) 128 is a period longer than a predetermined period (in this example, the reception cycle of the information transmission request reception means 117 (30 seconds in this example)) with respect to the information transmission apparatus 11 (for example, 1 )), The information transmission request is transmitted, the gas meter information transmitted from the information transmission device 11 is received, and the location information of the gas cylinder 20 (supplier facility) is associated with the management device 13. The gas meter information is transmitted.
 つまり、携帯端末12の情報送信要求手段128がある情報取得ポイントにおいて情報送信装置11に情報送信要求を送信すると、地理情報表示手段127が当該情報取得ポイントから所定範囲内の電子地図およびその範囲内に存在する同一の供給元の検針対象となるガスボンベ20(LPガスメータ21)の位置を、携帯端末12の表示手段121に表示する。そして、表示手段121に表示されている全てのLPガスメータ21と接続する情報送信装置11は、ガスメータ情報を携帯端末12に送信する。そして、携帯端末12は、地理情報表示手段127によって対象となるLPガスメータ21の位置情報と、受信したガスメータ情報とを紐付けて、ネットワークNW1を介して、管理装置13に送信(アップロード)する。なお、携帯端末12から同日に同一のLPガスメータ21のガスメータ情報が送信された場合は、管理装置13の情報は、最新のガスメータ情報で上書き(更新)される。 That is, when an information transmission request is transmitted to the information transmitting apparatus 11 at an information acquisition point where the information transmission request unit 128 of the mobile terminal 12 is present, the geographic information display unit 127 displays an electronic map within the predetermined range from the information acquisition point and the range within that range. The position of the gas cylinder 20 (LP gas meter 21) that is the target of meter reading from the same supply source is displayed on the display means 121 of the portable terminal 12. Then, the information transmission device 11 connected to all the LP gas meters 21 displayed on the display unit 121 transmits the gas meter information to the portable terminal 12. And the portable terminal 12 links | relates the positional information on the LP gas meter 21 used as the object with the geographic information display means 127, and the received gas meter information, and transmits (uploads) it to the management apparatus 13 via the network NW1. In addition, when the gas meter information of the same LP gas meter 21 is transmitted from the portable terminal 12 on the same day, the information of the management device 13 is overwritten (updated) with the latest gas meter information.
 このとき、通信状況の悪化などにより携帯端末12が情報送信要求を送信したにもかかわらず、ガスメータ情報が受信できない場合もある。そこで、地理情報表示手段127は、対象となるLPガスメータ21ごとのガスメータ情報の取得の成否を、表示手段121に表示可能に構成されている。これにより、携帯端末12の携行者は、ガスメータ情報の取得が失敗したLPガスメータ21の位置を把握することができる。 At this time, there may be a case where the gas meter information cannot be received even though the mobile terminal 12 has transmitted the information transmission request due to deterioration of the communication status. Therefore, the geographic information display unit 127 is configured to be able to display on the display unit 121 whether or not the acquisition of the gas meter information for each target LP gas meter 21 is successful. Thereby, the carry person of the portable terminal 12 can grasp | ascertain the position of the LP gas meter 21 in which acquisition of gas meter information failed.
 ガスメータ情報の取得に失敗したLPガスメータ21が存在する場合、携帯端末12の携行者は必要に応じて情報取得ポイントから移動するなどして再度の情報送信要求を送信し、ガスメータ情報の再取得を試みる。 When there is an LP gas meter 21 in which acquisition of gas meter information has failed, the person carrying the portable terminal 12 transmits an information transmission request again by moving from the information acquisition point as necessary to reacquire the gas meter information. Try.
 情報送信要求に基づくガスメータ情報の取得が行えない場合、携帯端末12の携行者は、情報受付送信手段(情報受付送信処理)129によって、ガスメータ情報を取得する。情報受付送信手段129は、携帯端末12の携行者(使用者)によるガスメータ情報の入力を受け付け、管理装置13に当該ガスメータ情報を送信するためのアプリケーションプログラムである。 When the gas meter information cannot be acquired based on the information transmission request, the carry person of the mobile terminal 12 acquires the gas meter information by the information reception / transmission means (information reception / transmission process) 129. The information acceptance / transmission means 129 is an application program for accepting an input of gas meter information by a person (user) of the portable terminal 12 and transmitting the gas meter information to the management device 13.
 情報受付送信手段(情報受付送信処理)129は、例えば、ガスメータ情報の取得が行えなかったLPガスメータ21の位置情報(地図や住所など)を携帯端末12の表示手段121に表示する。携帯端末12の使用者は当該位置情報に基づき、ガスメータ情報の取得が行えなかったLPガスメータ21の所在地に赴き、例えば、携帯端末12のカメラ(入力手段122)によりLPガスメータ21を撮影し、情報受付送信手段129に当該画像データを入力する。情報受付送信手段129は、入力されたLPガスメータ21の画像データから、当該LPガスメータ21の固有番号、ガス使用量を示す指針値、および保安情報などを文字認識し、当該文字情報と地理情報表示手段127から取得した位置情報とを紐付けて、ガスメータ情報の取得日(検針日)とともにガスメータ情報として携帯端末12のメモリ123に記憶する。あるいは、情報受付送信手段129は、携行者の携帯端末12のタッチパネル(入力手段122)の操作による当該LPガスメータ21の固有番号、ガス使用量を示す指針値、および保安情報などの文字情報の入力を受付け、ガスメータ情報として携帯端末12のメモリ123に記憶する。そして、情報受付送信手段129は、ガスメータ情報と地理情報表示手段127から取得したLPガスメータ21の位置情報と紐付けて、ガスメータ情報の取得日(検針日)とともにネットワークNW1(例えば、無線の移動体通信回線や無線LANなど)を介して、管理装置13に送信(アップロード)する。 The information reception / transmission means (information reception / transmission process) 129 displays, for example, the position information (a map, an address, etc.) of the LP gas meter 21 on which the gas meter information could not be acquired on the display means 121 of the portable terminal 12. Based on the position information, the user of the mobile terminal 12 goes to the location of the LP gas meter 21 where the gas meter information could not be acquired. For example, the user of the mobile terminal 12 photographs the LP gas meter 21 with the camera (input means 122) of the mobile terminal 12 The image data is input to the acceptance transmission means 129. The information reception / transmission means 129 character-recognizes the unique number of the LP gas meter 21, a guideline value indicating the amount of gas used, and security information from the input image data of the LP gas meter 21, and displays the character information and geographic information. The position information acquired from the means 127 is linked and stored in the memory 123 of the portable terminal 12 as gas meter information together with the acquisition date (meter reading date) of the gas meter information. Alternatively, the information reception / transmission unit 129 inputs character information such as a unique number of the LP gas meter 21, a guideline value indicating the amount of gas used, and security information by operating the touch panel (input unit 122) of the portable terminal 12 of the carry person. Is stored in the memory 123 of the portable terminal 12 as gas meter information. Then, the information reception / transmission means 129 associates the gas meter information with the position information of the LP gas meter 21 acquired from the geographical information display means 127, and together with the acquisition date (the meter reading date) of the gas meter information, the network NW1 (for example, a wireless mobile object) The data is transmitted (uploaded) to the management apparatus 13 via a communication line or a wireless LAN.
 例えば、情報送信装置11の周囲に電波を遮蔽する部材が存在する場合などでは、携帯端末12においてガスメータ情報を取得することができない。なお、この問題はスマートメータにおいても同様に生じる。本実施形態では、携帯端末12が情報送信装置11との無線通信によってガスメータ情報を取得できない場合であっても、補助的な情報受付送信手段129によってガスメータ情報を取得し、管理装置13に当該ガスメータ情報を送信することができる。また、情報受付送信手段129が携帯端末12のカメラにより撮影したLPガスメータ21の画像データからガスメータ情報を取得する構成の場合は、検針実行の証拠を残すこともできる。 For example, when there is a member that shields radio waves around the information transmission device 11, the gas meter information cannot be acquired by the mobile terminal 12. This problem also occurs in the smart meter. In the present embodiment, even when the portable terminal 12 cannot acquire the gas meter information by wireless communication with the information transmission device 11, the gas meter information is acquired by the auxiliary information reception / transmission means 129, and the management device 13 receives the gas meter information. Information can be sent. Further, when the information reception / transmission means 129 is configured to acquire the gas meter information from the image data of the LP gas meter 21 photographed by the camera of the portable terminal 12, evidence of meter reading execution can be left.
 このように、本実施形態では、電池(充電池)114を内蔵し、携帯端末12と無線通信を行う通信部113を備えた情報送信装置11を既存のLPガスメータ21に有線接続することにより、LPガスメータ21のガスメータ情報を携帯端末12に送信し、携帯端末12からリアルタイムで管理装置13に送信することができる。このようにすることで、永続的な通信用の電源を有さない既存のLPガスメータ11を用いて、必要時に自動でガスメータ情報を取得することができる。また、携帯端末12は、任意のタイミングで所定期間(例えば、1分間)に亘り、情報送信要求を送信し、情報送信装置11では携帯端末12からの情報送信要求を受信する情報送信要求処理を周期的(例えば、30秒に1回)に行うようにすることで、情報送信装置11の電源消費を最小に抑えることができる。 As described above, in this embodiment, by connecting the information transmission device 11 including the battery (rechargeable battery) 114 and including the communication unit 113 that performs wireless communication with the mobile terminal 12 to the existing LP gas meter 21, The gas meter information of the LP gas meter 21 can be transmitted to the mobile terminal 12 and transmitted from the mobile terminal 12 to the management device 13 in real time. By doing in this way, gas meter information can be automatically acquired when needed using the existing LP gas meter 11 which does not have a permanent communication power supply. In addition, the mobile terminal 12 transmits an information transmission request for a predetermined period (for example, 1 minute) at an arbitrary timing, and the information transmission apparatus 11 performs an information transmission request process for receiving the information transmission request from the mobile terminal 12. By performing it periodically (for example, once every 30 seconds), power consumption of the information transmitting apparatus 11 can be minimized.
 <管理手段>
 図4を参照して管理手段13について説明する。同図(a)は、管理手段13の構成を示すブロック図であり、同図(b)は、管理手段13の機能を示すブロック図であり、同図(c)は管理装置13が管理する情報(ガスメータ管理情報)の一例を示す概要図である。
<Management means>
The management means 13 will be described with reference to FIG. 2A is a block diagram showing the configuration of the management means 13, FIG. 2B is a block diagram showing the function of the management means 13, and FIG. 2C is managed by the management apparatus 13. FIG. It is a schematic diagram which shows an example of information (gas meter management information).
 同図(a)に示すように、管理装置13は、携帯端末12と例えば移動体通信回線などのネットワークNW1を介して接続し、事業者用サーバ14と例えばインターネットや専用回線などのネットワークNW2を介して接続する例えばサーバ装置(またはパーソナルコンピュータ(PC))であり、CPU130、ROM131、RAM132、記憶手段(記憶装置)133、入力手段134、表示手段135、通信手段136などを有する。 As shown in FIG. 2A, the management device 13 is connected to the mobile terminal 12 via a network NW1 such as a mobile communication line, and connects the operator server 14 to a network NW2 such as the Internet or a dedicated line. For example, a server device (or a personal computer (PC)) is connected via the CPU 130, ROM 131, RAM 132, storage means (storage device) 133, input means 134, display means 135, communication means 136, and the like.
 CPU130は、ROM131や記憶装置133等に格納されている管理装置13全体の動作を実現するための各種のソフトウェアプログラム(アプリケーションプログラム)やオペレーティングシステム(OS)等を実行する処理や、プログラムの実行に必要なデータやファイル等をRAM132や記憶装置133等に記憶する処理などを行う。 The CPU 130 executes various software programs (application programs), operating systems (OS), and the like for realizing the operation of the entire management apparatus 13 stored in the ROM 131, the storage device 133, and the like, and executes the programs. Processing for storing necessary data, files, and the like in the RAM 132, the storage device 133, and the like is performed.
 記憶装置133は、アプリケーションプログラム、OS、制御プログラム、関連プログラム等を記憶するものであり、例えば、ハードディスク(HDD)等によって実現することができる。入力手段134は例えば、キーボード、ポインティングデバイス(マウス等)、タッチパネル等によって実現することができる。表示手段135は、例えば入力手段134からの入力に対する応答出力等を表示するものであり、例えば、液晶表示装置、プラズマディスプレイ等によって実現することができる。 The storage device 133 stores an application program, an OS, a control program, a related program, and the like, and can be realized by, for example, a hard disk (HDD). The input unit 134 can be realized by, for example, a keyboard, a pointing device (such as a mouse), a touch panel, or the like. The display unit 135 displays, for example, a response output in response to an input from the input unit 134, and can be realized by, for example, a liquid crystal display device, a plasma display, or the like.
 ROM131などに記憶されたソフトウェアプログラムがRAM132のワークエリアに読み出されてCPU130によって当該ソフトウェアプログラムが実行されることにより、管理装置13はガス供給管理処理を実行する。このガス供給管理処理には、使用量算出処理、配送予測処理および地理情報表示処理等が含まれ、これにより管理装置13は、使用量算出手段137と、配送予測手段138と、地理情報表示手段139の機能を実現する(同図(b))。なお、ソフトウェアプログラムは、DVD-ROMやCD-ROM等のコンピューター読み取り可能な情報記憶媒体に格納されていてもよい。また、記憶装置133内にはデータベースが設けられ、ガスメータ情報とLPガスメータ21の位置情報とが紐付けて記憶される。 When the software program stored in the ROM 131 or the like is read into the work area of the RAM 132 and executed by the CPU 130, the management device 13 executes a gas supply management process. This gas supply management process includes a usage amount calculation process, a delivery prediction process, a geographic information display process, and the like, whereby the management apparatus 13 uses the usage amount calculation means 137, the delivery prediction means 138, and the geographic information display means. The function 139 is realized ((b) in the figure). The software program may be stored in a computer-readable information storage medium such as a DVD-ROM or CD-ROM. Further, a database is provided in the storage device 133, and the gas meter information and the positional information of the LP gas meter 21 are stored in association with each other.
 通信手段136は、携帯端末12とネットワークNW1を介して通信を行うとともに、事業者用サーバ装置14とネットワークNW2を介して通信行う。 The communication means 136 communicates with the portable terminal 12 via the network NW1, and also communicates with the business server device 14 via the network NW2.
 事業者(供給者)用サーバ装置14は、既知のサーバ装置であり、管理装置13と同様のCPU、ROM、RAM、記憶手段、入力手段、表示手段、通信手段(いずれも不図示)などを有し、その記憶手段には、特定の事業者(の特定の権限を有する者)のみがアクセス可能な情報(例えば、当該LPガスメータ21(LPガス)の契約者(消費者)の個人情報など)が格納されている。 The provider (supplier) server device 14 is a known server device, and has the same CPU, ROM, RAM, storage means, input means, display means, communication means (all not shown) and the like as the management device 13. The storage means has information that can be accessed only by a specific operator (who has a specific authority) (for example, personal information of a contractor (consumer) of the LP gas meter 21 (LP gas), etc.) ) Is stored.
 つまり、本実施形態では、管理装置13のデータベースにガスメータ管理情報が格納されている。このガスメータ管理情報は一例として、同図(c)に示すように、ガスメータ情報(およびLPガスメータ21の位置情報)を含む一方、当該LPガスメータ21の契約者(消費者)の個人情報は含まれない。LPガスの契約者(消費者)の個人情報は、(例えば、後述する配送予測手段138などによって)必要に応じて事業者用サーバ装置14から取得することで、管理装置13のガスメータ情報と対応付けられる。すなわち、検針者や配送者が携行する携帯端末13においては、LPガスの契約者の個人情報を保持(記憶、表示)することはできないように構成されている。 That is, in this embodiment, the gas meter management information is stored in the database of the management device 13. As an example, the gas meter management information includes gas meter information (and positional information of the LP gas meter 21) as shown in FIG. 5C, while personal information of a contractor (consumer) of the LP gas meter 21 is included. Absent. The personal information of the LP gas contractor (consumer) corresponds to the gas meter information of the management device 13 by acquiring it from the server device 14 for business operators as necessary (for example, by a delivery prediction means 138 described later). Attached. In other words, the portable terminal 13 carried by the meter reader or the delivery person is configured so that personal information of the LP gas contractor cannot be held (stored or displayed).
 なお、本実施形態では携帯端末13において、LPガスの契約者の個人情報を保持(記憶、表示)することはできないように構成されていればよく、管理装置13において位置情報と紐付けて当該LPガスメータ21の契約者(消費者)の個人情報を保有してもよい。 In the present embodiment, it is sufficient that the portable terminal 13 is configured so that the personal information of the LP gas contractor cannot be stored (stored or displayed), and is associated with the position information in the management device 13. The personal information of the contractor (consumer) of the LP gas meter 21 may be held.
 また、携帯端末12がガスメータ情報の取得が行えない状態の場合(携帯端末12の情報受付送信手段129によって、ガスメータ情報を取得する必要がある場合)には、対象のLPガスメータ21のみ、その契約者名等を管理装置13から取得し、あるいは管理装置13を経由して事業者用サーバ装置14から取得して一時的に表示できるようにしてもよい。 Further, when the portable terminal 12 cannot acquire the gas meter information (when it is necessary to acquire the gas meter information by the information reception / transmission means 129 of the portable terminal 12), only the target LP gas meter 21 has the contract. The person name or the like may be acquired from the management apparatus 13 or may be acquired from the business server apparatus 14 via the management apparatus 13 and temporarily displayed.
 管理装置13は、ガスメータ管理情報として例えば、単一の供給元(例えば、各LPガス事業者、各LPガス事業者の支店、充填所、配送センタ、小売事業者など)に関する情報のみを管理するものであってもよいし、複数の供給元に関する情報を各供給元ごとに管理するものであってもよい。管理装置13が、複数の供給元に関する情報を各供給元ごとに管理するものである場合、図1に示した管理装置13は、各供給元ごとに複数設けられるものであってもよいし、1つまたは複数の管理装置13で、複数の供給元に関する情報を各供給元ごとに管理するものであってもよい。また、管理装置13が、複数の供給元に関する情報を各供給元ごとに管理するものである場合、事業者用サーバ装置14は、各事業者(の特定の権限を有する者)がそれぞれの契約者の情報のみにアクセス可能となるように、一つ又は複数設けられる。 The management device 13 manages only information related to a single supply source (for example, each LP gas company, a branch of each LP gas company, a filling station, a delivery center, a retailer, etc.) as the gas meter management information. The information regarding a some supply source may be managed for every supply source. When the management device 13 manages information on a plurality of suppliers for each supplier, a plurality of the management devices 13 shown in FIG. 1 may be provided for each supplier, One or a plurality of management devices 13 may manage information regarding a plurality of suppliers for each supplier. In addition, when the management device 13 manages information on a plurality of suppliers for each supplier, the operator server device 14 is contracted by each operator (who has specific authority). One or more are provided so that only the information of the person can be accessed.
 図4(c)は、1の管理装置13が保有するガスメータ管理情報の一例であり、複数の供給元(例えば、LPガス事業者)に関する情報を各供給元ごとに管理する場合の例を示す概要図である。 FIG. 4C is an example of gas meter management information held by one management apparatus 13 and shows an example in which information on a plurality of supply sources (for example, LP gas companies) is managed for each supply source. FIG.
 管理装置13は例えば、同図(c)に示すように、複数の供給元(例えば、LPガス事業者)毎に、それぞれの供給元が保有するLPガスの固有番号を紐付けたガスメータ管理情報(データベース)を保持している(固有番号以外の情報が含まれていてもよい)。各供給元は、供給元識別番号によって識別される。一方、事業者(供給者)用サーバ14(14A、14B、14C・・・)は、例えば、各LPガス事業者(あるいは、支店などその他の供給元)毎に設けられており、各LPガス事業者が契約する契約者のみ(自社の契約者のみ)の個人情報を保有する。 For example, as shown in FIG. 5C, the management device 13 has a gas meter management information in which a unique number of LP gas held by each supply source is associated with each of a plurality of supply sources (for example, LP gas companies). (Database) is held (information other than the unique number may be included). Each supplier is identified by a supplier identification number. On the other hand, the server 14 (14A, 14B, 14C...) For the provider (supplier) is provided, for example, for each LP gas company (or other supply source such as a branch). Holds personal information only for contractors contracted by business operators (only in-house contractors).
 管理装置13は、各事業者サーバ14(14A、14B、14C・・・)から要求があった場合、当該事業者の供給元識別番号に紐付けられたLPガスの固有番号をダウンロードさせる。これにより、各LPガス事業者は自社の契約者のみのLPガスの固有番号を取得できる。そして、各LPガス事業者は取得した固有番号に基づき、自社の事業者用サーバ装置14から各固有番号に対応した個人情報を取得する。 When there is a request from each business server 14 (14A, 14B, 14C,...), The management device 13 causes the LP gas unique number linked to the supplier identification number of the business to be downloaded. Thereby, each LP gas company can acquire the unique number of LP gas only for its own contractor. Then, each LP gas company acquires personal information corresponding to each unique number from its own company server device 14 based on the acquired unique number.
 具体的には、例えば、管理装置13は、LPガス事業者A(供給元識別番号「ID01」)の保有する事業者サーバ14Aから要求があった場合、供給元識別番号「ID01」をキーとして対応する複数のLPガスの固有番号(この例では、「0001」~「0004」)のダウンロードを事業者用サーバ14Aに対して許可する。LPガス事業者Aは自社の契約者のみのLPガスの固有番号を取得でき、当該固有番号に基づき、自社の事業者用サーバ装置14Aから各固有番号に対応した個人情報を取得する。 Specifically, for example, when there is a request from the operator server 14A owned by the LP gas operator A (supplier identification number “ID01”), the management device 13 uses the supplier identification number “ID01” as a key. The business server 14A is permitted to download the corresponding unique numbers (in this example, “0001” to “0004”) of a plurality of corresponding LP gases. The LP gas company A can acquire the unique number of the LP gas only for its own contractor, and acquires personal information corresponding to each unique number from its own company server device 14A based on the unique number.
 同様に、LPガス事業者B(供給元識別番号「ID02」)の保有する事業者サーバ14Bから要求があった場合、供給元識別番号「ID02」をキーとして対応する複数のLPガスの固有番号(この例では、「0005」、「0006」・・・)のダウンロードを事業者用サーバ14Bに対して許可し、LPガス事業者C(供給元識別番号「ID03」)の保有する事業者サーバ14Cから要求があった場合、供給元識別番号「ID03」をキーとして対応する複数のLPガスの固有番号(この例では、「00010」、「0011」・・・)のダウンロードを事業者用サーバ14Cに対して許可する。LPガス事業者Bは自社の事業者用サーバ装置14Bから各固有番号に対応した個人情報を取得し、LPガス事業者Cは自社の事業者用サーバ装置14Cから各固有番号に対応した個人情報を取得する。 Similarly, when there is a request from the operator server 14B held by the LP gas operator B (supplier identification number “ID02”), the unique numbers of the corresponding LP gases using the supplier identification number “ID02” as a key (In this example, “0005”, “0006”...) Is downloaded to the business server 14B, and the business server owned by the LP gas business C (supplier identification number “ID03”). When there is a request from 14C, the provider server downloads the corresponding unique numbers (in this example, “00010”, “0011”...) Of a plurality of LP gases using the supplier identification number “ID03” as a key. Allow for 14C. The LP gas company B acquires personal information corresponding to each unique number from its own company server device 14B, and the LP gas company C receives personal information corresponding to each unique number from its company server device 14C. To get.
 このようにすることで、複数の供給元の情報を管理装置13において一括に管理することができ、また一括に管理した場合であっても、契約者の個人情報については供給元ごとに管理することができる。 In this way, information of a plurality of suppliers can be managed in a lump in the management apparatus 13, and even when managed in a lump, the contractor's personal information is managed for each supplier. be able to.
 なお、この例では1つの管理装置13のみを示しているが、同図(c)に示す構成の供給元識別番号と固有番号の情報を複数の管理装置13で管理してもよい。 In this example, only one management device 13 is shown. However, the information of the supplier identification number and the unique number having the configuration shown in FIG.
 地理情報表示手段(地理情報表示処理)139は、携帯端末12の地理情報表示手段127と同様(共通)のマッピングシステム(これにより実行される処理)である。 Geographic information display means (geographic information display processing) 139 is the same (common) mapping system (process executed thereby) as the geographical information display means 127 of the mobile terminal 12.
 使用量算出手段(使用量算出処理)137は、携帯端末12から受信したガスメータ情報のガス使用量(指針値)や図4(c)に示すガスメータ管理情報に基づき、所定期間におけるガスボンベ20ごとのガス使用量(指針値)と、ガスボンベ20内のガス残量を算出し、LPガスメータ21ごとに記憶手段133に記憶する。使用量算出手段(使用量算出処理)137が管理する(生成し又は使用する)データの一例は後述する(図9参照)。供給元は、当該出力結果(検針結果)を消費者に通知する。 The used amount calculating means (used amount calculating process) 137 is based on the gas used amount (guideline value) of the gas meter information received from the portable terminal 12 and the gas meter management information shown in FIG. The amount of gas used (guideline value) and the remaining amount of gas in the gas cylinder 20 are calculated and stored in the storage means 133 for each LP gas meter 21. An example of data managed (generated or used) by the usage calculation means (usage calculation processing) 137 will be described later (see FIG. 9). The supplier notifies the output result (the meter reading result) to the consumer.
 具体的には、本実施形態では、各供給先施設(各家庭)を訪問することなくLPガスメータの検針を行うため、消費者にとっては検針の有無が把握しにくい。そこで、供給元では予め消費者のメールアドレスを登録してもらい、検針を実施した場合(情報受付日に携帯端末12からガスメータ情報を受け付けた場合、あるいは、管理装置13の使用量算出手段137から検針結果が出力された場合)には検針の実施をメールにて通知する。また、管理装置13などに消費者ごとのポータルサイトを準備し、当該ポータルサイトにおいて検針結果と使用量分の請求書の提示などを行う。従来では、検針員によって各供給先施設(各家庭)を訪問し、検針結果をポスティングによって通知したり、検針結果を集中管理して検針結果通知と使用量分の請求書を郵送するなどしていたが、消費者ごとのポータルサイトによる検針結果の通知と使用量分の請求書の提示を行うことで、検針結果通知および請求書の発行に伴うコストを大幅に低減することができる。また、ポータルサイトでは、使用者ごとの過去の使用量の変化や過去の使用量に基づく将来の使用量予測などを行うようにしてもよい。なお、希望者に対しては、検針結果通知と使用量分の請求書を郵送するようにしておよい。 Specifically, in this embodiment, since the meter reading of the LP gas meter is performed without visiting each supply destination facility (each household), it is difficult for the consumer to grasp the presence or absence of meter reading. Therefore, when the supplier has registered the e-mail address of the consumer in advance and the meter is read (when the gas meter information is received from the portable terminal 12 on the information reception date, or from the usage calculation means 137 of the management device 13). When the meter reading result is output), the execution of meter reading is notified by e-mail. In addition, a portal site for each consumer is prepared in the management device 13 and the like, and a meter reading result and a bill for the usage amount are presented on the portal site. Traditionally, meter readers visit each supply facility (each household) and notify the meter reading results by posting, or centrally manage the meter reading results and mail the meter reading result and bills for the amount used. However, by notifying the meter reading result and presenting the bill for the usage amount on the portal site for each consumer, it is possible to greatly reduce the costs associated with the meter reading result notification and the issuance of the bill. In the portal site, a change in the past usage amount for each user or a future usage amount prediction based on the past usage amount may be performed. In addition, a meter reading result notification and a bill for the amount used may be mailed to the applicant.
 配送予測手段(配送予測処理)138は、ガスボンベ20の使用量や図4(c)に示すガスメータ管理情報に基づき、供給元(LPガス事業者、支店、充填所、配送センタ、小売事業者など)ごとにガスボンベ20の配送の予定日と最適な配送経路を予測する。配送予測手段(配送予測処理)138が管理する(生成し又は使用する)データの一例は後述する(図9参照)。 The delivery prediction means (delivery prediction processing) 138 is based on the usage amount of the gas cylinder 20 and the gas meter management information shown in FIG. 4C, and the supply source (LP gas operator, branch, filling station, delivery center, retailer, etc.) ) To predict the scheduled delivery date of the gas cylinder 20 and the optimal delivery route. An example of data managed (generated or used) by the delivery prediction means (delivery prediction process) 138 will be described later (see FIG. 9).
 図5は、配送予測手段138による配送予定日の予測方法について説明する概略図である。配送予測手段138は、供給先施設Uごとのガスボンベ20の配送日(実際に配送された日、前回配送日)の入力を受け付けて、当該配送日(前回配送日)を記憶手段(記憶装置)133に記憶する(1)。そして、例えば、各供給先施設Uごとに過去の同月の使用量等に基づいて、ガスボンベ20内のガス残量が所定量(例えば、2本のガスボンベ20の全量で100%とした場合、全体の20%程度のガス残量)になると予測される日(例えば、前回配送日から2ヶ月後の日など)を仮の次回配送日として設定し、記憶手段133に記憶する(2)。その後、前回配送日から仮の次回配送日までの間で複数(例えば2回)の情報受付日を設定する(3)。この情報受付日は、携帯端末12から送信されるガスメータ情報の受付日であって、携帯端末12からは検針後にリアルタイムでガスメータ情報(ガス使用量の指針値を含む)が管理装置13に送信されるため、携帯端末12による検針日である。配送予測手段138は、前回配送日から所定期間(例えば、一週間)経過後の日付を第一の情報受付日として設定し、第一の情報受付日から当該所定期間(例えば、一週間)経過後の日付を第二の情報受付日として設定する。 FIG. 5 is a schematic diagram for explaining a method of predicting a scheduled delivery date by the delivery predicting means 138. The delivery predicting means 138 receives an input of a delivery date (actual delivery date, previous delivery date) of the gas cylinder 20 for each supply destination facility U, and stores the delivery date (previous delivery date). 133 is stored (1). And, for example, based on the usage amount of the same month in the past for each supply destination facility U, the remaining amount of gas in the gas cylinder 20 is a predetermined amount (for example, when the total amount of the two gas cylinders 20 is 100%, (For example, a date two months after the previous delivery date) is set as a provisional next delivery date and stored in the storage means 133 (2). Thereafter, a plurality of (for example, twice) information reception dates are set between the previous delivery date and the provisional next delivery date (3). This information reception date is the reception date of the gas meter information transmitted from the portable terminal 12, and from the portable terminal 12, the gas meter information (including the guide value of the gas usage amount) is transmitted to the management device 13 in real time after meter reading. Therefore, it is a meter reading date by the portable terminal 12. The delivery prediction unit 138 sets a date after a predetermined period (for example, one week) from the previous delivery date as the first information reception date, and the predetermined period (for example, one week) has elapsed from the first information reception date. The later date is set as the second information reception date.
 そして、第一の情報受付日に検針を行い、携帯端末12から送信されたガスメータ情報を受け付けた場合には、使用量算出手段137によって対象のガスボンベ20内のガス残量を算出し、前回配送日におけるガス残量(100%)からの減少量に基づき、ガスボンベ20内のガス残量が所定量(全体の20%程度のガス残量)となる予測される日を再度予測し(4)、仮の次回配送日に設定し直して、記憶手段133の仮の次回配送日を更新する(5)。 Then, when the meter reading is performed on the first information reception date and the gas meter information transmitted from the portable terminal 12 is received, the remaining amount of gas in the target gas cylinder 20 is calculated by the usage amount calculation unit 137, and the previous delivery Based on the amount of decrease from the remaining gas amount (100%) in the day, the predicted day when the remaining gas amount in the gas cylinder 20 becomes a predetermined amount (approximately 20% of the total gas amount) is predicted again (4) Then, the provisional next delivery date is reset to update the provisional next delivery date in the storage means 133 (5).
 また、第二の情報受付日に検針を行い、携帯端末12から送信されたガスメータ情報を受け付けた場合には、使用量算出手段137によって対象のガスボンベ20内のガス残量を算出し、第一の情報受付日におけるガス残量からの減少量に応じて、ガスボンベ20内のガス残量が所定量(全体の20%程度のガス残量)となる予測される日を再度予測し(6)、次回配送日として決定し、記憶手段133に記憶されている仮の次回配送日を更新する(7)。以下、この図5(7)の決定された次回配送日を以下、「次回配送日(決定)」と記載する場合がある。次回配送日(決定)は、原則として変更されないが、事情によっては変更(前倒し、繰り上げ)される場合があり(8)、これについては後述する。 If the meter reading is performed on the second information reception date and the gas meter information transmitted from the portable terminal 12 is received, the remaining amount of gas in the target gas cylinder 20 is calculated by the usage amount calculating means 137, and the first In accordance with the amount of decrease from the remaining amount of gas on the information reception date, the predicted day when the remaining amount of gas in the gas cylinder 20 becomes a predetermined amount (approximately 20% of the remaining amount of gas) is predicted again (6) Then, the next delivery date is determined, and the provisional next delivery date stored in the storage means 133 is updated (7). Hereinafter, the determined next delivery date in FIG. 5 (7) may be referred to as “next delivery date (determined)”. The next delivery date (determination) is not changed in principle, but may be changed (advanced or advanced) depending on circumstances (8), which will be described later.
 なお、この例では、前回配送日から仮の次回配送日の間で情報受付日を2回設定する場合を例に説明したが、1回でもよいし2回以上(例えば、2回~5回など)であってもよい。つまり、情報受付日は任意に設定でき、複数の情報受付日の期間が短い(情報受付日の設定が多い)方が予測の精度が高くなる。また、例えば設定された情報受付日以外でも、携帯端末12によって(予定外に)ガスメータ情報を取得した場合(例えば、他のLPガスメータ21の検針を行ったついでに当該予定外のLPガスメータ21のガスメータ情報も取得できた場合など)は、配送予測手段138は、随時、当該予定外のガスメータ情報の入力を受け付ける。そして、受け付けた最新のガスメータ情報に基づき、随時、仮の次回配送日を更新する。 In this example, the case where the information reception date is set twice between the previous delivery date and the provisional next delivery date has been described as an example. However, the information reception date may be set twice or more (for example, 2 to 5 times). Etc.). In other words, the information reception date can be arbitrarily set, and the accuracy of prediction is higher when the period of the plurality of information reception dates is shorter (the information reception date is set more frequently). Further, for example, when the gas meter information is acquired (unscheduled) by the portable terminal 12 on a date other than the set information reception date (for example, after the meter reading of another LP gas meter 21 is performed, the gas meter of the unscheduled LP gas meter 21) For example, when the information can also be acquired), the delivery prediction unit 138 accepts the input of unscheduled gas meter information at any time. Based on the latest received gas meter information, the provisional next delivery date is updated as needed.
 また、情報受付日を複数回設定した場合であっても、1回目の情報受付日に取得したガスメータ情報に基づいて算出したガス残量が既に所定量以下(例えば、全体の20%程度以下)である場合には、例えば1週間後などを次回配送日として決定し、2回目以降の情報受付日の処理は行わない。 Further, even when the information reception date is set a plurality of times, the remaining gas amount calculated based on the gas meter information acquired on the first information reception date is already less than a predetermined amount (for example, about 20% or less of the whole). In such a case, for example, one week later is determined as the next delivery date, and the second and subsequent information reception dates are not processed.
 このようにして各供給先施設Uごとに次回配送日が決定すると、配送予測手段138は、同じ次回配送日が設定されていることを第一の条件(グループ化条件)として、複数の供給先施設をグループ化し、当該グループごとに最適な配送経路を予測する。 When the next delivery date is determined for each supply destination facility U in this way, the delivery predicting means 138 sets the same next delivery date as a first condition (grouping condition), and supplies a plurality of supply destinations. Facilities are grouped and an optimal delivery route is predicted for each group.
 図6は、配送予測手段138による配送経路の予測の一例を示す概要図である。 FIG. 6 is a schematic diagram showing an example of delivery route prediction by the delivery predicting means 138.
 配送予測手段138は、上述のグループ化条件(同一の次回配送日が設定されていること)に基づき、第一のグループ化処理を行って複数の供給先施設をグループ化する。 The delivery predicting means 138 performs a first grouping process to group a plurality of supply destination facilities based on the above-described grouping condition (the same next delivery date is set).
 ここで、次回配送日は例えば、ガスボンベ20内のガス残量が不足することなく、且つ無駄になりすぎないような所定量(例えば、全体の20%)と予測される最終の日(それ以降ではガス残量が不足する恐れがある配送期限日)とする。 Here, the next delivery date is, for example, the last date predicted after a predetermined amount (for example, 20% of the total) that does not become exhausted without remaining gas remaining in the gas cylinder 20 (after that) Is the delivery deadline date when there is a risk of a shortage of gas remaining.
 また、配送予測手段138は、特別な事情を第二の条件(グループ化特別条件)として、あるグループに属する供給先施設Uについて、グループを変更する処理(第二のグループ化処理、グループ変更処理)を行うことができる。グループの変更は、例えば、既に決定している次回配送日(図5(7)の次回配送日)を変更(更新)する処理などを行い、第一の条件(グループ化条件)に基づいて第一のグループ化処理を行うことで変更することができる。 Further, the delivery predicting means 138 uses a special situation as the second condition (grouping special condition) to change the group (second grouping process, group change process) for the supply destination facility U belonging to a certain group. )It can be performed. For example, the group is changed based on the first condition (grouping condition) by changing (updating) the next delivery date (the next delivery date in FIG. 5 (7)) that has already been determined. It can be changed by performing one grouping process.
 例えば、次回配送日があるグループAの次回配送日よりも遅い日付であるために、同じグループAに属しない供給先施設Uであっても、例えば、配送効率やガス残量など(配送の優先度)の特別な事情(グループ化特別条件)を考慮すると、決定したグループAに含めた方が望ましい場合がある。このような場合は、配送予測手段138は、グループ化特別条件(第二のグループ化条件)に基づき、供給先施設Uについて、図5(7)で決定した次回配送日をグループAの次回配送日に前倒しして(繰り上げて)次回配送日を変更する(図5(8))。そして、配送予測手段138は第一のグループ化処理を行って供給先施設UをグループAに含め、そのグループA内で、最も効率的な配送経路を決定する。 For example, since the next delivery date is later than the next delivery date of group A, even for a supply destination facility U that does not belong to the same group A, for example, delivery efficiency, gas remaining amount, etc. (delivery priority) In consideration of special circumstances (grouping special conditions), it may be desirable to include them in the determined group A. In such a case, the delivery predicting means 138 uses the next delivery date determined in FIG. 5 (7) for the supply destination facility U based on the special grouping condition (second grouping condition). The next delivery date is changed by advancing the date (carrying forward) (FIG. 5 (8)). Then, the delivery predicting means 138 performs the first grouping process to include the supply destination facility U in the group A, and determines the most efficient delivery route in the group A.
 また、1台の配送車に積載できるガスボンベの数に制限があるため、同日に配送する或るグループ(例えば、グループA)に属する供給先施設Uが多い場合は、1台の配送車で供給元BCとグループA内の供給先施設Uとの間を複数回往復したり、複数台の配送車で1つのグループAに配送することになる。この場合は、グループA内の供給先施設Uについて、1台の配送車で供給元BCとの間で複数回往復する場合の最も効率的な配送経路を決定する。あるいは、グループA内の供給先施設Uについて、複数台の配送車で配送する場合の、配送車ごとの最も効率的な配送経路を決定する。なお、いずれの場合も、第一のグループ化処理でグループ分けされた供給先施設Uが優先して配送される。 In addition, since there is a limit to the number of gas cylinders that can be loaded on one delivery vehicle, if there are many supply destination facilities U belonging to a certain group (for example, group A) delivered on the same day, supply with one delivery vehicle. The original BC and the supply destination facility U in the group A are reciprocated several times or delivered to one group A by a plurality of delivery vehicles. In this case, for the supply destination facility U in the group A, the most efficient delivery route in the case of making a round trip to and from the supply source BC with one delivery vehicle is determined. Alternatively, for the supply destination facility U in the group A, the most efficient delivery route for each delivery vehicle when delivering by a plurality of delivery vehicles is determined. In any case, the supply destination facility U grouped in the first grouping process is preferentially delivered.
 つまり、グループ化特別条件(第二のグループ化条件)に基づき、例えば、グループAに、次回配送日が前倒しされた供給先施設Udが含まれる場合、配送経路が多少非効率となっても、当初のグループAの供給先施設Ua、Ub・・・を優先して配送し、ガスボンベ20が余った場合に前倒しされた供給施設Udに配送する。なお、配送前に積載できるガスボンベ20に余裕があることが確実な場合には、前倒しされた供給施設Udも含めて最も効率的な配送経路を決定するようにしてもよいし、前倒しされた供給施設Udが存在することによって、複数回(複数台)の配送が非効率になるような場合には、供給施設Udについて次回配送日の前倒しを行わずに最も効率的な配送経路を決定するようにしてもよい。 In other words, based on the special grouping condition (second grouping condition), for example, if the group A includes a supply destination facility Ud whose next delivery date is advanced, even if the delivery route becomes somewhat inefficient, The delivery facilities Ua, Ub... Of the original group A are preferentially delivered, and when the gas cylinders 20 are left, they are delivered to the supply facility Ud brought forward. When it is certain that there is room in the gas cylinder 20 that can be loaded before delivery, the most efficient delivery route including the forwarded supply facility Ud may be determined, or the forwarded supply may be determined. In the case where the delivery of a plurality of times (multiple units) becomes inefficient due to the existence of the facility Ud, the most efficient delivery route is determined for the supply facility Ud without advancing the next delivery date. It may be.
 図6(a)を参照して具体的に説明する。この例では、配送予測手段138の第一のグループ化処理によって、次回配送日(図6では「K」と表記する)が10月1日のグループAに供給先施設Ua、Ub・・・,10月2日のグループBに供給先施設Uc、Ud・・・、10月3日のグループCに供給先施設Ue、Uf・・・、・・・10月10日のグループJに供給先施設Ug、Uh・・・がグループ化されているとする。 Specific description will be given with reference to FIG. In this example, by the first grouping process of the delivery predicting means 138, the next delivery date (denoted as “K” in FIG. 6) is assigned to the group A on October 1 as the supply destination facilities Ua, Ub,. Supply facility Uc, Ud ... in group B on October 2 ... Supply facility Ue, Uf ... in group C on October 3 ... Supply facility in group J on October 10 Assume that Ug, Uh... Are grouped.
 そして配送予測手段138は、必要に応じて第二の条件に基づき、第二のグループ化処理を行う。すなわち、第二の条件に基づくと、例えばグループBの供給先施設Ud、グループCの供給先施設Ue、グループJの供給先施設UgをグループAに含めたほうが望ましい場合、供給先施設Ud、Ue、Ugの次回配送日(決定)を、グループAの次回配送日(決定)である10月1日に繰り上げる変更を行い(図5(8))、再度第一のグループ化処理を行う。これにより、供給先施設Ud、Ue、UgはグループAに属することとなり、10月1日にガスボンベ20が配送される。つまり、第二の条件に該当する場合には、例え配送予定日(決定)が10月10日の供給先施設Ugであっても、9日繰り上げて10月1日にガスボンベ20が配送される。 And the delivery prediction means 138 performs a second grouping process based on the second condition as necessary. That is, based on the second condition, for example, when it is desirable to include the supply destination facility Ud of the group B, the supply destination facility Ue of the group C, and the supply destination facility Ug of the group J in the group A, the supply destination facilities Ud, Ue , Ug's next delivery date (determination) is changed to October 1 which is the next delivery date (determination) of group A (FIG. 5 (8)), and the first grouping process is performed again. Accordingly, the supply destination facilities Ud, Ue, Ug belong to the group A, and the gas cylinder 20 is delivered on October 1. That is, if the second condition is met, even if the scheduled delivery date (decision) is the supply destination facility Ug on October 10, the gas cylinder 20 is delivered on October 1 by 9 days. .
 この例では、第二のグループ化処理は、第二の条件(グループ化特別条件)に基づき次回配送日(決定)を変更してグループ化(第一のグループ化処理)をし直す処理であるが、第二の条件に基づき、決定したグループが変更できる処理であればこの例に限らない。例えば、データベースなどに各供給先施設ごとのグループの情報を登録しておき、第二の条件に基づき当該情報を都度更新するようにしてもよい。 In this example, the second grouping process is a process of changing the next delivery date (determination) based on the second condition (grouping special condition) and regrouping (first grouping process). However, the process is not limited to this example as long as the determined group can be changed based on the second condition. For example, group information for each supply destination facility may be registered in a database or the like, and the information may be updated each time based on the second condition.
 また、本実施形態では、第一の条件(グループ化条件)は、「次回配送日(決定)が同一であること」としているが、第二の条件(グループ化特別条件)は供給元BCごとに任意に設定可能とする。例えば、ある所定の範囲に含まれる供給先施設Uの多少や、近隣の供給先施設U間までの(平均)距離、事業所と一般家庭の混在等、配送の優先度を変更する場合の条件に関しては供給元BCに事情が異なる場合が多い。そこで、第二の条件については、供給元BCごとに任意に設定でき、また事情の変更に伴い適宜変更可能とする。これにより、供給元BCの事情に即した配送予測が可能となる。 In the present embodiment, the first condition (grouping condition) is “the next delivery date (determination) is the same”, but the second condition (grouping special condition) is for each supplier BC. Can be set arbitrarily. For example, conditions for changing the priority of delivery, such as the number of supply destination facilities U included in a given range, the (average) distance between neighboring supply destination facilities U, the mixture of business establishments and general households, etc. In many cases, the situation differs depending on the supplier BC. Therefore, the second condition can be arbitrarily set for each supplier BC, and can be changed as appropriate according to changes in circumstances. Thereby, the delivery prediction according to the circumstances of the supplier BC becomes possible.
 図6(b)は第二の条件を「配送予定の供給先施設から近距離であること」および「次回配送日の前倒し期間を距離に応じて決定する(最大で3日とする)こと」として、配送予測を行う場合の一例を示す概要図である。 FIG. 6B shows that the second condition is “a short distance from the delivery destination facility to be delivered” and “determine the advance period of the next delivery date according to the distance (a maximum of 3 days)”. It is a schematic diagram which shows an example in the case of performing delivery prediction as.
 具体的には、距離を例えば「近」、「中」、「遠」の3段階に分類し、或るグループに属する供給先施設Uaからの距離が「近」であるが別のグループに属する供給先施設Ubがある場合、当該供給先施設Ubの次回配送日を、最大で3日前まで繰り上げて供給先施設Uaと同日に配送可能とする(図6(b)では「近/-3」と表記する)。同様に、供給先施設Uaからの距離が「中」である供給先施設Ubがある場合には当該供給先施設Ubの次回配送日を最大で2日前まで繰り上げ(図6(b)では「中/-2」と表記する)、供給先施設Uaからの距離が「遠」である供給先施設Ubがある場合には当該供給先施設Ubの次回配送日を最大で1日前まで繰り上げ(図6(b)では「遠/-1」と表記する)て、供給先施設Uaと同日に配送可能とするものである。すなわち、この例では近い場合には前倒しの最大日数も多くなり、配送効率をガス残量よりも優先させてグループ変更を可能とするものである。換言すれば「近/-3」、「中/-2」、「遠/-1」はグループ変更の可能性の強さを示しており、距離が近いほうがグループ変更の可能性が強くなる。 Specifically, the distance is classified into, for example, “near”, “medium”, and “far”, and the distance from the supply destination facility Ua belonging to a certain group is “near” but belongs to another group. When there is a supply destination facility Ub, the next delivery date of the supply destination facility Ub is advanced up to three days in advance and can be delivered on the same day as the supply destination facility Ua (“Near / −3” in FIG. 6B). ). Similarly, when there is a supply destination facility Ub whose distance from the supply destination facility Ua is “medium”, the next delivery date of the supply destination facility Ub is advanced up to two days in advance (in FIG. 6B, “medium” In the case where there is a supply destination facility Ub whose distance from the supply destination facility Ua is “far”, the next delivery date of the supply destination facility Ub is advanced up to one day in advance (FIG. 6). (B) is expressed as “far / −1”) and can be delivered on the same day as the supply destination facility Ua. That is, in this example, the maximum number of days ahead is increased in the near case, and the group can be changed by giving priority to the delivery efficiency over the remaining gas amount. In other words, “near / −3”, “medium / −2”, and “far / −1” indicate the strength of the possibility of group change, and the closer the distance, the stronger the possibility of group change.
 同図(b)では説明の便宜上、近隣の複数の供給先施設Uについて1本の実線で結ばれる場合(例えば、供給先施設U1とU2,供給先施設U1とU4など)に「近」、2本の実線で結ばれる場合(例えば、供給先施設U1とU7など)に「中」、3本以上の実線で結ばれる場合(例えば、(例えば、供給先施設U1とU10など)に「遠」であるとする。また、1本の実線で結ばれる場合であっても、「中」または「遠」と同程度に距離が長い場合には破線(例えば、供給先施設U1とU9など)で示し、「中」または「遠」に分類する。なお、距離については、当然ながら、地図上の直線距離ではなく、配送車が通行できる実際の経路上の距離を意味する。 In FIG. 5B, for convenience of explanation, “near” when a plurality of neighboring supply destination facilities U are connected by a single solid line (for example, supply destination facilities U1 and U2, supply destination facilities U1 and U4), “Medium” when two solid lines are connected (for example, supply facility U1 and U7), for example, “distant” when connected by three or more solid lines (for example, supply facility U1 and U10). In addition, even when the lines are connected by a single solid line, if the distance is as long as “middle” or “far”, a broken line (for example, supply facilities U1 and U9) The distance is classified as “medium” or “far.” It should be noted that the distance means not the straight distance on the map, but the distance on the actual route that the delivery vehicle can travel.
 同図(b)に示すように或る供給元BCがガスボンベ20の配送を担当する供給先施設U1~U10があり、供給先施設U1~U4の次回配送日(決定)が10月1日、供給先施設U9の次回配送日(決定)が10月2日、供給先施設U5、U10の次回配送日(決定)が10月3日、供給先施設U8の次回配送日(決定)が10月4日、供給先施設U6、U7の次回配送日(決定)が10月5日であるとする。 As shown in FIG. 5B, there is a supply destination facility U1 to U10 in which a certain supply BC is responsible for delivery of the gas cylinder 20, and the next delivery date (determination) of the supply destination facilities U1 to U4 is October 1. The next delivery date (determination) of the supply destination facility U9 is October 2, the next delivery date (determination) of the supply destination facilities U5 and U10 is October 3, and the next delivery date (determination) of the supply destination facility U8 is October. On the 4th, it is assumed that the next delivery date (determination) of the supply destination facilities U6 and U7 is October 5.
 この場合、第一のグループ化処理によって、一点差線で示すように、供給先施設U1~U4はグループA、供給先施設U9はグループB、供給先施設U5、U10はグループC、供給先施設U8はグループD、供給先施設U6、U7はグループEに分類される。 In this case, as shown by the one-dot chain line, the supply destination facilities U1 to U4 are the group A, the supply destination facility U9 is the group B, the supply destination facilities U5 and U10 are the group C, and the supply destination facility by the first grouping process. U8 is classified as group D, and the supply destination facilities U6 and U7 are classified as group E.
 ここで、供給先施設U9については、10月2日に1箇所のみの配送であり、供給元BCからも遠いため、他のグループに変更して配送する方が配送の無駄がなくなる。そこで、第二の条件に基づき第二のグループ化処理を行う。この例では第二の条件によって、近隣の供給先施設までの距離が「中」(破線)の場合は、2日前まで次回配送日を前倒しできるため、配送予測手段138によって供給先施設U9について次回配送日(決定)を10月1日に変更し、グループAに設定し直す。 Here, as for the supply destination facility U9, only one delivery is performed on October 2, and it is far from the supply source BC. Therefore, it is not wasteful to change and deliver to another group. Therefore, the second grouping process is performed based on the second condition. In this example, if the distance to the neighboring supply destination facility is “medium” (broken line) according to the second condition, the next delivery date can be advanced two days before, so the delivery predicting means 138 will use the next time for the supply destination facility U9. The delivery date (decision) is changed to October 1 and set to group A again.
 また配送予測手段138は、グループAに属する各供給先施設Uの全てを最短で無駄なく配送できる経路(実線(または破線)に沿って無駄なく移動できる経路)を決定する。配送先施設U9は、供給先施設U1またはU4の次に配送するようにルートが変更される。 Also, the delivery predicting means 138 determines a route (a route that can be moved along the solid line (or broken line) without waste) that can deliver all of the supply destination facilities U belonging to the group A without waste. The route of the delivery destination facility U9 is changed so that delivery is performed next to the supply destination facility U1 or U4.
 また、供給先施設U8についても、10月4日に1箇所のみの配送であり、供給元BCからも遠いため、他のグループに変更して配送する方が配送の無駄がなくなる。そこで、第二の条件に基づき第二のグループ化処理を行う。この場合、例えば、供給先施設U7を経由して供給先施設U5に至る距離は「中」(実線2本文)であるため、供給先施設U8の次回配送日を1日前倒しし、10月3日に変更して、供給先施設U5と同日に配送するようにしてもよい。あるいは、供給先施設U7から供給先施設U8までの距離は「近」であるが、供給先施設U6から供給先施設U7までの距離が「中」(実線2本分又は破線)であるため、供給先施設U7の次回配送日を1日前倒しし、10月4日に変更して、供給先施設U8と同日に配送するようにしてもよい。 In addition, since the delivery destination facility U8 is also delivered only at one location on October 4, and is far from the supply source BC, it is less wasteful to deliver by changing to another group. Therefore, the second grouping process is performed based on the second condition. In this case, for example, since the distance to the supply destination facility U5 via the supply destination facility U7 is “medium” (solid line 2 text), the next delivery date of the supply destination facility U8 is advanced by one day, and October 3 The date may be changed and delivered on the same day as the supply destination facility U5. Alternatively, the distance from the supply destination facility U7 to the supply destination facility U8 is “near”, but the distance from the supply destination facility U6 to the supply destination facility U7 is “medium” (two solid lines or broken lines). The next delivery date of the supply destination facility U7 may be advanced one day, changed to October 4, and delivered on the same day as the supply destination facility U8.
 また配送予測手段138は、グループCまたはグループEに属する各供給先施設Uの全てを最短で無駄なく配送できる経路(実線(または破線)に沿って無駄なく移動できる経路)を決定する。 Also, the delivery predicting means 138 determines a route (a route that can be moved along the solid line (or broken line) without waste) that can deliver all of the supply destination facilities U belonging to the group C or group E without waste.
 なお、各グループのガスボンベ20の総数が、1台の配送車に積載できるガスボンベ20の数を超えるため、複数回(複数台)の配送が必要な場合には、既述のとおり、第一のグループ化処理によってグループ分けされた(次回配送日が前倒しされない)供給先施設Uが優先的に(確実に)配送されるようにした上で、最も効率的な配送経路が決定される。 In addition, since the total number of gas cylinders 20 in each group exceeds the number of gas cylinders 20 that can be loaded on one delivery vehicle, if multiple (multiple) delivery is required, as described above, the first The most efficient delivery route is determined after the supply destination facilities U grouped by the grouping process (the next delivery date is not advanced) are delivered preferentially (reliably).
 このようにすることで、柔軟に効率的な配送経路の予測を立てることができる。また、情報送信装置11の電池114は、ガスボンベ20の配送時に適宜交換が可能である。 This makes it possible to flexibly and efficiently predict delivery routes. Further, the battery 114 of the information transmission device 11 can be appropriately replaced when the gas cylinder 20 is delivered.
 なお、第二のグループ化処理は必要に応じて行う処理であり、配送の効率上問題がなければ、必ずしもグループの変更を行わなくても良い。また、次回供給日までの間にさらに特別な事情が生じた場合には(必要に応じて条件を変更して)グループ変更の処理(第二のグループ化処理)を複数回行っても良い。 Note that the second grouping process is a process that is performed as necessary. If there is no problem in the efficiency of delivery, the group need not be changed. Further, when a special situation occurs until the next supply date (conditions are changed as necessary), the group change process (second grouping process) may be performed a plurality of times.
 また、本実施形態の配送予測手段138は、次回配送日(決定)のみでグループ化しただけでは配送効率が悪くなる供給先施設Uについて、次回配送日(決定)が異なる場合であっても、グループの変更を可能とするものであり、上記の例は、グループの変更を具体的に説明する一例に過ぎない。つまり、配送予測手段138は、次回配送日(第一の条件)によって複数の供給先施設Uをグループ化するとともに、供給元BCごとに任意に設定可能な特別な事情(第二の条件)によってグループの変更が可能な構成であれば、上記の例に限らない。 Further, the delivery predicting means 138 of the present embodiment, even if the next delivery date (decision) is different for the supply destination facility U whose delivery efficiency deteriorates only by grouping only by the next delivery date (decision), The group can be changed, and the above example is merely an example for specifically explaining the group change. That is, the delivery predicting means 138 groups a plurality of supply destination facilities U according to the next delivery date (first condition), and according to special circumstances (second condition) that can be arbitrarily set for each supply source BC. The configuration is not limited to the above example as long as the group can be changed.
 <ガス供給管理システムの流れ(ガス供給管理方法)>
 次に、図7および図8を参照して、本発明のガス供給管理システム10の流れ(ガス供給管理方法)について説明する。図7は、ガス供給管理システム10における、情報送信装置11、携帯端末12および管理装置13の処理を示すタイミングチャートであり、図8が、携帯端末12の地理情報表示手段127による表示の一例を示す図である。
<Flow of gas supply management system (gas supply management method)>
Next, the flow (gas supply management method) of the gas supply management system 10 of the present invention will be described with reference to FIGS. FIG. 7 is a timing chart showing processing of the information transmission device 11, the portable terminal 12 and the management device 13 in the gas supply management system 10, and FIG. 8 is an example of display by the geographic information display means 127 of the portable terminal 12. FIG.
 まず、LPガスメータ21の検針者(検針員)は、予め設定された検針日に携帯端末12を携行し、所定の情報取得ポイントに赴く。なお、携帯端末12の携行者はガスボンベ20の配送者、あるいはLPガス事業者などであってもよい。検針日は、管理装置13の配送予測手段138によって設定された情報取得日(上記の例では、第一の情報受付日および第二の情報受付日)である。また、情報取得ポイントは当該情報取得ポイントを中心とした所定範囲内(例えば、半径200m~300mの範囲内)においてできる限り多くの同一LPガス供給事業者が供給するガスボンベ20(LPガスメータ21)が検針対象として存在するように(ガスメータ情報を取得可能となるように)、予め定められたポイントである。情報取得ポイントの情報は、所定地域ごとに管理装置13の記憶装置133等に記憶されている。 First, the meter reader (meter meter) of the LP gas meter 21 carries the portable terminal 12 on a preset meter reading day and goes to a predetermined information acquisition point. The person carrying the mobile terminal 12 may be a delivery person of the gas cylinder 20 or an LP gas company. The meter reading date is the information acquisition date (in the above example, the first information reception date and the second information reception date) set by the delivery prediction unit 138 of the management device 13. Further, the information acquisition point is a gas cylinder 20 (LP gas meter 21) supplied by as many LP gas supply companies as possible within a predetermined range centered on the information acquisition point (for example, within a radius of 200 m to 300 m). It is a predetermined point so as to exist as a meter reading target (so that gas meter information can be acquired). Information on the information acquisition points is stored in the storage device 133 of the management device 13 for each predetermined area.
 検針者は、情報取得ポイントにおいて携帯端末12を操作し、情報送信要求処理を行う。すなわち、情報送信装置11に対して任意のタイミングで所定期間(例えば、1分間)に亘り、情報送信要求を送信する(1)。検針対象のガスボンベ20(LPガスメータ21)に接続されている情報送信装置11は、情報送信処理を行う。情報送信処理では、情報送信要求受信処理を行わない待機モードと情報送信要求受信処理を行う受信モードとが周期的に自動で切り替わる。つまり、情報送信要求受信処理では制御部115のタイマ割り込みによって周期的に(例えば、30秒に1回のタイミングで)、情報送信要求受信処理を実行し、通信手段136によって携帯端末12が送信する情報送信要求を受信する(2)。情報送信装置11は、情報送信要求を受信したか否かを判定し、情報送信要求を受信した場合は個別情報送信処理を行う。個別情報送信処理では、情報送信装置11の取得部112がLPガスメータ21からガスメータ情報を取得して(3)、所定のメモリ116に記憶し、通信部113およびネットワークNWを介して情報送信要求を送信した携帯端末12に対しガスメータ情報を送信(無線送信)する(4)。一方、情報送信要求を受信しなかった場合は、個別情報送信処理を行わず、情報送信処理を終了する。 The meter reader operates the portable terminal 12 at the information acquisition point, and performs an information transmission request process. That is, an information transmission request is transmitted to the information transmission apparatus 11 at an arbitrary timing for a predetermined period (for example, 1 minute) (1). The information transmission device 11 connected to the gas cylinder 20 (LP gas meter 21) to be metered performs information transmission processing. In the information transmission process, the standby mode in which the information transmission request reception process is not performed and the reception mode in which the information transmission request reception process is performed are automatically switched periodically. In other words, in the information transmission request reception process, the information transmission request reception process is executed periodically (for example, once every 30 seconds) by the timer interruption of the control unit 115, and the portable terminal 12 transmits by the communication unit 136. An information transmission request is received (2). The information transmission device 11 determines whether or not an information transmission request has been received, and when an information transmission request is received, performs an individual information transmission process. In the individual information transmission process, the acquisition unit 112 of the information transmission apparatus 11 acquires gas meter information from the LP gas meter 21 (3), stores it in a predetermined memory 116, and sends an information transmission request via the communication unit 113 and the network NW. Gas meter information is transmitted (wireless transmission) to the transmitted portable terminal 12 (4). On the other hand, when the information transmission request is not received, the individual information transmission process is not performed and the information transmission process is terminated.
 検針者は、情報送信要求処理の実行後に、地理情報表示手段127によって、対象範囲のLPガスメータ21の全てのガスメータ情報の取得に成功したか否かを確認する(5)。既述のとおり、地理情報表示手段127は、対象となるLPガスメータ21ごとのガスメータ情報の取得の成否を、表示手段121に表示可能に構成されている。 After the execution of the information transmission request process, the meter reader confirms whether or not the acquisition of all the gas meter information of the LP gas meter 21 in the target range is successful by the geographic information display means 127 (5). As described above, the geographic information display means 127 is configured to be able to display on the display means 121 whether or not the gas meter information has been successfully acquired for each LP gas meter 21 as a target.
 具体的には例えば、図8(a)に示すように、表示手段121で表示される電子地図上でLPガスメータ21の位置がそれぞれ四角で表示されている場合、表示された全てのLPガスメータ21がガスメータ情報の取得対象となる。なお、円の中心部の携帯端末12の画像が情報取得ポイントである。そして、携帯端末12から送信された情報送信要求に基づき、情報送信装置11からLPガスメータ21のガスメータ情報が送信され、携帯端末12で当該情報の受信に成功した場合は、例えば同図(b)で示すようにLPガスメータ21から情報取得ポイントに向かう矢印が表示される。一方、携帯端末12で当該情報の受信に失敗した場合は、そのLPガスメータ21から矢印が表示されない。これにより、携帯端末12の携行者は、ガスメータ情報の取得が失敗したLPガスメータ21の位置を把握することができる。 Specifically, for example, as shown in FIG. 8 (a), when the positions of the LP gas meters 21 are displayed as squares on the electronic map displayed by the display means 121, all the displayed LP gas meters 21 are displayed. Is the acquisition target of gas meter information. The image of the mobile terminal 12 at the center of the circle is the information acquisition point. Then, based on the information transmission request transmitted from the portable terminal 12, when the gas meter information of the LP gas meter 21 is transmitted from the information transmitting device 11 and the portable terminal 12 has successfully received the information, for example, FIG. As shown, an arrow from the LP gas meter 21 toward the information acquisition point is displayed. On the other hand, when the mobile terminal 12 fails to receive the information, no arrow is displayed from the LP gas meter 21. Thereby, the carry person of the portable terminal 12 can grasp | ascertain the position of the LP gas meter 21 in which acquisition of gas meter information failed.
 再び図7に戻って、検針者は、ガスメータ情報の取得に成功したガスメータ情報を、LPガスメータ21の位置情報に紐付けて、ネットワークNW(例えば、無線の移動体通信回線)を介して、管理装置13に送信(アップロード)する(6)。一方、ガスメータ情報の取得に失敗しているLガスメータ情報の取得に失敗しているLPガスメータ21が存在する場合、当該LPガスメータ21付近まで移動して再度、情報送信要求処理を行う(7)。その上でさらにガスメータ情報の取得に失敗する場合には、検針者は、携帯端末12の情報受付送信手段129によって、ガスメータ情報を取得する(8)。すなわち、検針者はガスメータ情報の取得に失敗しているLPガスメータ21に赴き、当該LPガスメータ21のガスメータ情報を携帯端末12のカメラで撮影し画像データを記憶する(またはガスメータ情報を携帯端末12の入力手段122から入力する)。情報受付送信手段129は記憶された画像データから、当該LPガスメータ21の固有番号、ガス使用量を示す指針値、および保安情報などを文字認識し、当該文字情報と地理情報表示手段127から取得した位置情報とを紐付けて、ガスメータ情報として携帯端末12の取得部112に記憶する。あるいは、情報受付送信手段129は、携行者の携帯端末12のタッチパネル(入力手段122)の操作による当該LPガスメータ21の固有番号、ガス使用量を示す指針値、および保安情報などの文字情報の入力を受付け、地理情報表示手段127から取得した位置情報と紐付けて、ガスメータ情報として携帯端末12の取得部112に記憶する。そして、情報受付送信手段129は、ガスメータ情報と地理情報表示手段127から取得したLPガスメータ21の位置情報と紐付けて、ネットワークNW(例えば、無線の移動体通信回線)を介して、管理装置13に送信(アップロード)する(9) Returning to FIG. 7 again, the meter reader associates the gas meter information, which has been successfully acquired, with the positional information of the LP gas meter 21 and manages it via the network NW (for example, a wireless mobile communication line). Transmit (upload) to the device 13 (6). On the other hand, when there is an LP gas meter 21 that has failed to acquire L gas meter information that has failed to acquire gas meter information, it moves to the vicinity of the LP gas meter 21 and performs information transmission request processing again (7). If the acquisition of the gas meter information further fails, the meter reader acquires the gas meter information by the information reception / transmission means 129 of the portable terminal 12 (8). That is, the meter reader goes to the LP gas meter 21 that has failed to acquire the gas meter information, captures the gas meter information of the LP gas meter 21 with the camera of the portable terminal 12, and stores the image data (or stores the gas meter information of the portable terminal 12). Input from the input means 122). The information reception / transmission means 129 character-recognizes the unique number of the LP gas meter 21, a guideline value indicating the amount of gas used, security information, and the like from the stored image data, and obtains the information from the character information and geographic information display means 127. The position information is linked and stored in the acquisition unit 112 of the portable terminal 12 as gas meter information. Alternatively, the information reception / transmission unit 129 inputs character information such as a unique number of the LP gas meter 21, a guideline value indicating the amount of gas used, and security information by operating the touch panel (input unit 122) of the portable terminal 12 of the carry person. Is associated with the position information acquired from the geographic information display means 127 and stored in the acquisition unit 112 of the portable terminal 12 as gas meter information. Then, the information reception / transmission means 129 associates the gas meter information with the position information of the LP gas meter 21 acquired from the geographical information display means 127, and manages the management apparatus 13 via the network NW (for example, a wireless mobile communication line). Send (upload) to (9)
 管理装置13は、携帯端末12から送信されたガスメータ情報とLPガスメータ21の位置情報とを紐付けて、記憶装置(データベース)133に記憶する。ガスメータ情報にはLPガスメータ21を識別可能な固有番号が含まれており、当該固有番号をキーとして管理装置13において、各LPガスメータ21ごとに、使用量算出処理(10)や、配送予測処理(11)などのガス供給に関する各種処理が実行可能となる。 The management device 13 associates the gas meter information transmitted from the mobile terminal 12 with the position information of the LP gas meter 21 and stores the information in the storage device (database) 133. The gas meter information includes a unique number that can identify the LP gas meter 21, and the management device 13 uses the unique number as a key for each LP gas meter 21 to calculate a usage amount (10) or a delivery prediction process ( Various processes relating to gas supply such as 11) can be executed.
 使用量算出処理では、携帯端末12から受信したガスメータ情報のガス使用量(指針値)を所定期間(例えば、1ヶ月分、2ヶ月分や、2年分、3年分など)蓄積し、所定期間におけるガスボンベ20ごとのガス使用量と、ガスボンベ20内のガス残量を算出し、LPガスメータ21ごとに記憶手段133に記憶する。 In the usage amount calculation process, the gas usage amount (guideline value) of the gas meter information received from the mobile terminal 12 is accumulated for a predetermined period (for example, one month, two months, two years, three years, etc.) The amount of gas used for each gas cylinder 20 and the remaining amount of gas in the gas cylinder 20 during the period are calculated and stored in the storage means 133 for each LP gas meter 21.
 管理装置13は、検針を実施した場合(情報受付日に携帯端末12からガスメータ情報を受け付けた場合、あるいは、管理装置13の使用量算出手段137から検針結果が出力された場合)には検針の実施をメールにて通知する。また、消費者ごとのポータルサイトにおいて検針結果と使用量分の請求書の提示などを行う。 When the meter reading is performed (when the meter reading is received from the portable terminal 12 on the information receiving date or when the meter reading result is output from the usage amount calculating means 137 of the managing device 13), Notify by email. In addition, the results of meter reading and invoices for the amount used are presented on the portal site for each consumer.
 配送予測処理では、図5に示すように例えば、供給先施設Uごとのガスボンベ20の配送日(実際に配送された日、前回配送日)の入力を管理装置13が受け付けた場合には、当該配送日(前回配送日)を記憶手段133に記憶する。そして、各供給先施設Uごとに過去の同月の使用量等に基づいて、ガスボンベ20内のガス残量が所定量(例えば、2本のガスボンベ20の全量で100%とした場合、全体の20%程度のガス残量)になると予測される日(例えば、前回配送日から2ヶ月後の日など)を仮の次回配送日として設定し、記憶手段133に記憶する。その後、前回配送日から仮の次回配送日までの間で複数(例えば2回)の情報受付日を設定する。 In the delivery prediction process, as shown in FIG. 5, for example, when the management device 13 receives an input of a delivery date (actual delivery date, previous delivery date) of the gas cylinder 20 for each supply destination facility U, The delivery date (previous delivery date) is stored in the storage means 133. Then, based on the amount of use in the same month for each supply destination facility U, the remaining amount of gas in the gas cylinder 20 is a predetermined amount (for example, when the total amount of the two gas cylinders 20 is 100%, the total 20 A date (for example, a date two months after the previous delivery date) predicted to become approximately% gas remaining) is set as a temporary next delivery date and stored in the storage means 133. Thereafter, a plurality of (for example, twice) information reception dates are set between the previous delivery date and the provisional next delivery date.
 また、配送予測処理では、第一の情報受付日に携帯端末12から送信されたガスメータ情報を管理装置13が受け付けた場合には、使用量算出処理によって対象のガスボンベ20内のガス残量を算出し、前回配送日におけるガス残量(100%)からの減少量に基づき、ガスボンベ20内のガス残量が所定量(全体の20%程度のガス残量)となる予測される日を仮の次回配送日に設定しなおして、記憶手段133の仮の次回配送日を更新する。 In the delivery prediction process, when the management device 13 receives the gas meter information transmitted from the portable terminal 12 on the first information reception day, the remaining gas amount in the target gas cylinder 20 is calculated by the usage amount calculation process. Based on the decrease from the remaining gas amount (100%) on the previous delivery date, the estimated date when the remaining gas amount in the gas cylinder 20 becomes a predetermined amount (approximately 20% of the total gas amount) The next delivery date is reset and the provisional next delivery date in the storage unit 133 is updated.
 また、配送予測処理では、例えば、第一の情報受付日に第二の情報受付日に携帯端末12から送信されたガスメータ情報を管理装置13受け付けた場合には、使用量算出処理によって対象のガスボンベ20内のガス残量を算出し、第一の情報受付日におけるガス残量からの減少量に応じて、ガスボンベ20内のガス残量が所定量(全体の20%程度のガス残量)となる予測される日を次回配送日として決定し、記憶手段133に記憶されている仮の次回配送日を更新する。 In the delivery prediction process, for example, when the management device 13 receives the gas meter information transmitted from the portable terminal 12 on the second information reception day on the first information reception day, the target gas cylinder is processed by the usage amount calculation process. The amount of gas remaining in the gas cylinder 20 is calculated according to the amount of decrease from the amount of gas remaining on the first information reception date, and the amount of gas remaining in the gas cylinder 20 is a predetermined amount (about 20% of the total amount of gas remaining). The predicted delivery date is determined as the next delivery date, and the provisional next delivery date stored in the storage unit 133 is updated.
 また、配送予測処理では、各供給先施設Uごとに次回配送日が決定すると、第一のグループ化処理(および必要に応じて第二のグループ化処理)を行い、或る範囲(地域)内に点在する同じ次回配送日が設定された複数の供給先施設Uについて、地理情報表示手段139を用いて最短で効率よく配送できる経路を決定する。 Further, in the delivery prediction process, when the next delivery date is determined for each supply destination facility U, the first grouping process (and the second grouping process if necessary) is performed, and within a certain range (region) The geographical information display means 139 is used to determine a route that can be efficiently delivered in the shortest time for a plurality of supply destination facilities U that are set to have the same next delivery date.
 ガスボンベ20の配送者は、このようにして決定された配送経路に基づき、次回配送日に対象となる供給先施設Uに赴き、ガスボンベ20を交換する。 The delivery person of the gas cylinder 20 goes to the target destination facility U on the next delivery date and replaces the gas cylinder 20 based on the delivery route determined in this way.
 以上説明したように、本発明によればLPガス事業の供給形態にマッチした独自のガス供給管理システムを、安価に提供することができる。 As described above, according to the present invention, a unique gas supply management system that matches the supply form of the LP gas business can be provided at low cost.
 現在、電気事業者においてはスマートメータを利用した効率的な管理システムの開発が進んでいる。電気事業におけるスマートメータは電源を有しており、またスマートメータの設置場所が、比較的狭い範囲において密集しているため、無線通信によってスマートメータ間で情報をリレーし、中継基地からネットワークへ情報をアップロードすることができる。あるいは、電力線搬送通信(Power Line Communication:PLC)という既存の送電線インフラを利用し、ネットワークへ情報をアップロードする方式も採用できる。 Currently, electric power companies are developing efficient management systems using smart meters. Smart meters in the electricity business have a power supply, and the installation locations of smart meters are dense in a relatively small area, so information is relayed between smart meters by wireless communication, and information is transferred from the relay base to the network. Can be uploaded. Alternatively, a method of uploading information to a network using an existing transmission line infrastructure called Power Line Communication (PLC) can also be adopted.
 これに対してLPガス事業におけるLPガスメータは電源を有しておらず、またLPガスメータの設置場所が所定範囲に集まらずに点在しているため、電気事業におけるスマートメータと同様なシステムを導入することが困難である。 In contrast, LP gas meters in the LP gas business do not have a power source, and the installation locations of the LP gas meter are scattered within a predetermined range, so the same system as the smart meter in the electric business is introduced. Difficult to do.
 このような状況において、LPガス事業者においても電気事業者のスマートメータ経由でLPPガスメータからの情報を収集し、ネットワークへアップロードしたり、従来から用いられている集中監視システムを利用し、利用者のネットワークインフラを利用してネットワークへアップロードするなどの方法が検討されている。また、LPガスメータにおいても通信機能(Uバス)を保持したメータの開発が行われている。 Under such circumstances, LP gas companies also collect information from LPP gas meters via electric utility smart meters and upload them to the network or use a centralized monitoring system that has been used in the past. A method of uploading to the network using the network infrastructure of the network is being studied. In addition, development of a meter having a communication function (U bus) is also being conducted for LP gas meters.
 しかしながら、LPガスメータの一括交換には膨大なコストがかかり、各LPガスメータ事業者においてはその投資に消極的である上、検針や保安情報の管理は自動化できたとしても、ガスボンベ20の交換・配送のための物流網は必須である。 However, lump sum replacement of LP gas meters is enormous, and each LP gas meter company is reluctant to invest in it, and even if the meter reading and security information management can be automated, replacement and delivery of the gas cylinder 20 A logistics network for is essential.
 本発明によれば、LPガス事業の供給形態の実情に合わせ、既存のLPガスメータ21に、電池114と無線通信を行う通信部113を内蔵した情報送信装置11を追加することで、LPガスメータ21のガスメータ情報を携帯端末12に対してガスメータ情報を送信する構成であるため、既存のLPガスメータ21を有効活用でき、工事費用や機器設置・入替費用を抑えることができる。 According to the present invention, in accordance with the actual situation of the supply form of the LP gas business, the LP gas meter 21 is added to the existing LP gas meter 21 by adding the information transmission device 11 including the communication unit 113 that performs wireless communication with the battery 114. Since the gas meter information is transmitted to the portable terminal 12, the existing LP gas meter 21 can be used effectively, and construction costs and equipment installation / replacement costs can be suppressed.
 また、情報送信装置11、携帯端末12および管理装置13の通信には移動体通信網を利用するため、例えば電力事業者など、他者の通信インフラに依存しないシステム構築が可能となる。 In addition, since a mobile communication network is used for communication between the information transmission apparatus 11, the portable terminal 12, and the management apparatus 13, a system can be constructed that does not depend on the communication infrastructure of another person such as a power company.
 また、原則として情報取得ポイントにおいて、複数の供給先施設UのLPガスメータ21のガスメータ情報を取得できるので、検針員の個別訪問による検針作業が不要となり、人件費を大幅に削減できる。また検針の効率化が図れるため、所定期間における検針回数を増やすことが可能となり、検針回数の増加(例えば、1月に2~3回、または1月に5~6回の検針)によってガス残量および次回配送日の予測精度を向上できる。例えば、従来では消費者にガスが供給できなくなる自体を回避するため、1箇所の供給先施設Uにおいてガス残量がガスボンベ20全体の50%程度で配送、交換をしていたところ、本発明によれば、例えば、ガス残量がガスボンベ20全体の20%程度での配送、交換が可能となるため、配送効率を大幅に向上でき、ガスボンベ20の配送のコストを削減できる。 In principle, since the gas meter information of the LP gas meters 21 of a plurality of supply destination facilities U can be acquired at the information acquisition point, meter reading work by individual visits of meter readers is not required, and labor costs can be greatly reduced. In addition, since the efficiency of meter reading can be improved, it is possible to increase the number of meter readings in a predetermined period, and the remaining gas can be increased by increasing the number of meter readings (for example, two to three times in January or 5 to 6 times in January). The prediction accuracy of quantity and next delivery date can be improved. For example, in the past, in order to avoid the fact that the gas could not be supplied to the consumer itself, the remaining amount of gas was delivered and exchanged at about 50% of the total gas cylinder 20 at one supply destination facility U. Accordingly, for example, delivery and replacement can be performed when the remaining gas amount is about 20% of the entire gas cylinder 20, so that the delivery efficiency can be greatly improved and the cost of delivery of the gas cylinder 20 can be reduced.
 このように、本発明によれば、検針、保安、配送などの業務の効率化によって、供給・管理のコスト削減が可能となり、ひいては一般消費者により安価で安全なエネルギー絶え間なく提供することができる。 As described above, according to the present invention, the efficiency of operations such as meter reading, security, and delivery can be reduced, and thus the supply and management costs can be reduced. As a result, it is possible to continuously provide cheap and safe energy to general consumers. .
 なお、上記の本実施形態では、一台の管理装置13によって、ガス供給管理システム10を構築する場合を例示したが、本発明はこれに限定されず、上述の管理装置13の機能を複数の装置(サーバ装置、PCなど)に分散させて、これらの機能を実現させるようにしても良い。 In the above-described embodiment, the case where the gas supply management system 10 is constructed by a single management device 13 is illustrated. However, the present invention is not limited to this, and the functions of the management device 13 described above are provided in a plurality of ways. These functions may be realized by being distributed to apparatuses (server apparatus, PC, etc.).
 図9は、本実施形態の管理装置13(配送予測手段138と使用量算出手段137が管理するデータの一例である。同図(a)は、使用量算出手段137が管理(使用、生成)するデータの一例であり、同図(b)は、配送予測手段138が管理(使用、生成)するデータの一例である。 9 shows an example of data managed by the management apparatus 13 (delivery prediction means 138 and usage amount calculation means 137) according to the present embodiment. FIG. 9A shows management (use and generation) by the usage amount calculation means 137. FIG. 5B is an example of data managed (used or generated) by the delivery predicting means 138.
 同図(a)に示すように、使用量算出手段(使用量算出処理)137は例えば、LPガスメータ21の固有番号(メータNo)、LPガスメータ21ごとの使用量(指針値)、LPガスメータ21の位置情報、当該情報の取得日(検針日)、保安情報等を含む使用量データを管理する。 As shown in FIG. 5A, the usage amount calculating means (usage amount calculating process) 137 includes, for example, a unique number (meter No.) of the LP gas meter 21, a usage amount (guideline value) for each LP gas meter 21, and the LP gas meter 21. Usage data including location information, date of acquisition (meter reading date), security information, and the like.
 また、同図(b)に示すように、配送予測手段(配送予測処理)138は例えば、LPガスメータ21の固有番号(メータNo)、LPガスメータ21ごとの使用量(指針値)、顧客コード、顧客名、ガスボンベ20の情報(設置容器情報)、配送先情報(LPガスメータ21ごとの次回配送日や最適な配送経路(または位置情報)を少なくとも含む情報)を含む配送予測データを管理する。 Further, as shown in FIG. 6B, the delivery prediction means (delivery prediction process) 138 includes, for example, a unique number (meter No) of the LP gas meter 21, a usage amount (guideline value) for each LP gas meter 21, a customer code, The delivery prediction data including the customer name, information on the gas cylinder 20 (installation container information), and delivery destination information (information including at least the next delivery date and the optimum delivery route (or position information) for each LP gas meter 21) are managed.
 なお、使用量算出手段(使用量算出処理)137と配送予測手段(配送予測処理)138とを独立して機能させ、同図(a)に示す使用量データと同図(b)に示す配送予測データとを独立して管理可能としてもよいし、配送予測手段(配送予測処理)138と使用量算出手段(使用量算出処理)137とを複数の管理装置13に分散して機能させ、配送予測データと使用量データを独立して管理可能としてもよい。 The usage amount calculation means (use amount calculation processing) 137 and the delivery prediction means (delivery prediction processing) 138 function independently, and the usage amount data shown in FIG. The prediction data may be managed independently, or the distribution prediction means (delivery prediction processing) 138 and the usage amount calculation means (use amount calculation processing) 137 are distributed and functioned in a plurality of management devices 13 to deliver the data. The prediction data and the usage amount data may be managed independently.
 また、管理装置13のガスメータ管理情報(図4(c)に示すデータ)を独立して管理可能としてもよい。 Further, the gas meter management information (data shown in FIG. 4C) of the management device 13 may be managed independently.
 さらには、管理装置13で管理(生成、使用)する各種データ(例えば、図4(c)に示すガスメータ管理情報や、配送予測手段(配送予測処理)138で生成(管理)される配送予測データ、使用量算出手段(使用量算出処理)137で生成(管理)される使用量算出データなど)をガスまたは電気などのスマートメータを用いるシステムにおいて使用するようにしてもよい。 Furthermore, various types of data managed (generated and used) by the management device 13 (for example, gas meter management information shown in FIG. 4C), and delivery prediction data generated (managed) by the delivery prediction means (delivery prediction processing) 138 The usage amount calculation means (usage amount calculation data generated (managed) by the usage amount calculation process) 137) may be used in a system using a smart meter such as gas or electricity.
 <第2実施形態>
 次に、図10~図16を参照して、本発明に係るガス供給管理システム10の他の実施形態として、省電力(低電力)かつ広域(遠距離)の無線通信技術を利用して本実施形態に係るガス供給管理システム10を実現する具体例について説明する。「省電力(低電力)かつ広域(遠距離)の無線通信技術」とは、消費電力が低く、WiFi(登録商標)やBluetooth(登録商標)などよりも広い領域を対象にした通信(キロメートル単位の遠距離通信)が可能となる無線通信技術をいう。また、その通信方式(通信規格)の一例としては、LPWA(Low Power Wide Area)や、LPWAN(Low Power Wide Area Network)などが挙げられる。以下では、省電力(低電力)かつ広域(遠距離)の無線通信技術として、LPWAを利用したガス供給管理システム10を例に説明する。
Second Embodiment
Next, referring to FIG. 10 to FIG. 16, as another embodiment of the gas supply management system 10 according to the present invention, the present invention is made using a power saving (low power) and wide area (long distance) wireless communication technology. A specific example of realizing the gas supply management system 10 according to the embodiment will be described. “Power-saving (low-power) and wide-area (long-distance) wireless communication technology” means low power consumption and communication over a wider area than WiFi (registered trademark), Bluetooth (registered trademark), etc. Wireless communication technology that enables long-distance communication). Examples of the communication method (communication standard) include LPWA (Low Power Wide Area) and LPWAN (Low Power Wide Area Network). Hereinafter, a gas supply management system 10 using LPWA will be described as an example as a power-saving (low-power) and wide-area (long-distance) wireless communication technology.
 LPWAを利用したガス供給管理システム10は、主に、情報送信装置11からの情報(ガスメータ情報)の取得(収集)において(第1実施形態のネットワークNW1の一部または全部として)、例えば、LPWA技術で構成されたネットワーク(通信回線)NW3、すなわち、LPWAネットワークを利用する。 The gas supply management system 10 using LPWA is mainly used in acquiring (collecting) information (gas meter information) from the information transmission device 11 (as part or all of the network NW1 of the first embodiment), for example, LPWA. A network (communication line) NW3 configured by technology, that is, an LPWA network is used.
 以下、第1実施形態と重複する構成については説明を省略し、第1実施形態と異なる部分について主に説明するが、第2実施形態のガス供給管理システム10は、以下で説明する構成・機能に加えて、第1実施形態で説明したガス供給管理システム10と同様の構成・機能を有し、適宜、並列してあるいは切り替えて各種処理を実行可能に構成されていてもよい。 Hereinafter, the description of the same configuration as that of the first embodiment will be omitted, and different parts from the first embodiment will be mainly described. However, the gas supply management system 10 of the second embodiment has the configuration and functions described below. In addition, it may have the same configuration and function as the gas supply management system 10 described in the first embodiment, and may be configured to execute various processes in parallel or switching as appropriate.
 図10は、LPWAを利用したガス供給管理システム10を模式的に示す概要図である。図10に示すように、LPWAを利用したガス供給管理システム10は、LPガスメータ21と、情報送信装置11と、管理装置13と、情報の収集手段31と、格納手段(格納装置)30と、携帯端末12と、これらが接続するネットワークNW1、NW3などを有する。 FIG. 10 is a schematic diagram schematically showing a gas supply management system 10 using LPWA. As shown in FIG. 10, the gas supply management system 10 using LPWA includes an LP gas meter 21, an information transmission device 11, a management device 13, an information collection unit 31, a storage unit (storage device) 30, The mobile terminal 12 includes networks NW1 and NW3 to which they are connected.
 情報送信装置11(およびLPガスメータ21)は、LPWA方式のネットワーク(通信回線)NW3に対応した構成となっている。すなわち、情報送信装置11は、第1実施形態(図2参照)と同様に各LPガスメータ21と接続し、あるいは各LPガスメータ21に内蔵されて各LPガスメータ21からのガスメータ情報を取得するが、情報送信装置11の例えば通信部113は、ネットワークNW3と接続可能であり、ネットワークNW3上の収集手段31に対してガスメータ情報の送信を行うように構成されている。 The information transmission device 11 (and the LP gas meter 21) has a configuration corresponding to the LPWA network (communication line) NW3. That is, the information transmission device 11 is connected to each LP gas meter 21 as in the first embodiment (see FIG. 2), or is incorporated in each LP gas meter 21 and acquires gas meter information from each LP gas meter 21. For example, the communication unit 113 of the information transmission device 11 can be connected to the network NW3, and is configured to transmit gas meter information to the collection unit 31 on the network NW3.
 ここで、ネットワークNW3は、例えば、免許が不要な通信帯域(920MHz帯域)を利用するLPWAネットワークであり、これにより低価格・低消費電力・広域(遠距離)の無線通信が可能となる。なお、ここでは、ネットワーク(通信回線)NW3がLPWAネットワークである場合を例に説明するが、ネットワークNW3は、少なくとも広域(遠距離)の無線通信が可能な通信網(通信回線)であれば、LPWAネットワークに限らない。LPWAを利用することにより、情報送信装置11は低消費電力での駆動が可能であり、情報送信装置11の内蔵の電池114は、例えば乾電池2本で数年間の使用が可能となる。 Here, the network NW3 is, for example, an LPWA network that uses a communication band (920 MHz band) that does not require a license, thereby enabling low-cost, low power consumption, wide-area (long-distance) wireless communication. Here, a case where the network (communication line) NW3 is an LPWA network will be described as an example. However, if the network NW3 is a communication network (communication line) capable of at least wide-area (long-distance) wireless communication, It is not limited to the LPWA network. By using LPWA, the information transmitting apparatus 11 can be driven with low power consumption, and the battery 114 built in the information transmitting apparatus 11 can be used for several years, for example, with two dry batteries.
 また、本実施形態では、ネットワークNW1は、有線および/または無線の通信回線の総称であり、ネットワーク(LPWAネットワーク)NW3も含むものとする。 In the present embodiment, the network NW1 is a generic term for wired and / or wireless communication lines, and includes a network (LPWA network) NW3.
 収集手段(収集装置)31は、ネットワークNW3に接続し、情報送信装置11が送信するガスメータ情報を収集する手段であり、例えばLPWA方式の通信に対応した無線基地局、あるいは、当該無線基地局と有線(又は無線)で接続する固定端末である。また、収集手段31は、LPWA方式の通信および/または移動体通信の無線基地局であってもよいし、当該無線基地局と接続する移動体通信端末であってもよい。 The collection means (collection apparatus) 31 is a means for connecting to the network NW3 and collecting gas meter information transmitted by the information transmission apparatus 11, for example, a radio base station compatible with LPWA communication, or the radio base station It is a fixed terminal connected by wire (or wireless). The collection means 31 may be a wireless base station for LPWA communication and / or mobile communication, or may be a mobile communication terminal connected to the wireless base station.
 情報送信装置11が送信したガスメータ情報は、収集装置31によって収集され、収集装置31が接続するネットワークNW1を介して、格納装置30に送信される。 The gas meter information transmitted by the information transmission device 11 is collected by the collection device 31 and transmitted to the storage device 30 via the network NW1 to which the collection device 31 is connected.
 格納装置30は、ネットワークNW1に接続し、ガスメータ情報を含む各種情報やアプリケーションプログラムなどが格納される装置であり、例えばクラウド環境に設けられたサーバ(クラウドサーバ)である。 The storage device 30 is a device that is connected to the network NW1 and stores various information including gas meter information, application programs, and the like. For example, the storage device 30 is a server (cloud server) provided in a cloud environment.
 管理装置13は、ネットワークNW1と接続し、ネットワークNW1を介して格納装置30に格納されたガスメータ情報等を取得する。また、この例では、管理装置13の少なくとも一部の機能は、アプリケーションプログラムとして格納装置30に格納され、クラウドコンピューティングシステムによって管理装置13において利用されるように構成されている。 The management device 13 is connected to the network NW1, and acquires gas meter information and the like stored in the storage device 30 via the network NW1. In this example, at least a part of the functions of the management device 13 is stored in the storage device 30 as an application program, and is configured to be used in the management device 13 by the cloud computing system.
 さらに、管理装置13は、第1実施形態と同様に事業者用サーバ装置14と接続する。管理装置13と事業者用サーバ装置14は、例えば、図1に示すネットワークNW2を介して接続する構成であってもよいし、ネットワークNW1(NW3)を介して接続する構成であってもよい。また、LPガスの契約者の個人情報などのデータや事業者用サーバ装置14の機能を格納装置30に格納し、クラウドコンピューティングシステムによって管理装置13において利用されるように構成してもよい。 Furthermore, the management device 13 is connected to the provider server device 14 as in the first embodiment. For example, the management device 13 and the provider server device 14 may be connected via the network NW2 illustrated in FIG. 1 or may be connected via the network NW1 (NW3). Further, data such as personal information of the LP gas contractor and the function of the server device 14 for the business may be stored in the storage device 30 and used in the management device 13 by the cloud computing system.
 情報送信装置11は、LPガスメータ21に外付け、あるいは内蔵されており、任意のタイミング、あるいは所定のタイミングでLPガスメータ21のガスメータ情報を取得し、ネットワークNW3を介して収集装置31に送信する。収集装置31は取得したガスメータ情報を、ネットワークNW1を介して格納装置30に格納・蓄積する。管理装置13は、任意のタイミング、あるいは所定のタイミングで、ネットワークNW1を介して格納装置30に格納されたガスメータ情報を取得する。 The information transmission device 11 is externally attached to or built in the LP gas meter 21, acquires the gas meter information of the LP gas meter 21 at an arbitrary timing or a predetermined timing, and transmits it to the collection device 31 via the network NW3. The collection device 31 stores and accumulates the acquired gas meter information in the storage device 30 via the network NW1. The management device 13 acquires the gas meter information stored in the storage device 30 via the network NW1 at an arbitrary timing or a predetermined timing.
 このように、本実施形態のLPWAを利用したガス供給管理システム10では、検針員の検針作業(例えば、第1実施形態の携帯端末12によるガスメータ情報の受信・収集処理)によらず、情報送信装置11が送信するガスメータ情報を管理装置13が遠隔で自動取得することができる。これにより、管理装置13はガス消費量を含むガスメータ情報を多頻度で把握することができる。ここで、多頻度とは、月次より多い(高い)頻度であることをいい、例えば、1ヶ月に1度や1週間に1度などの頻度よりも多い頻度で把握することをいう。具体的には、本実施形態では例えば、ガスメータ情報を日次で取得し、ガス使用量等を把握することができる。これにより、管理装置13は取得したガスメータ情報をLPガスの販売事業における月次検針業務に活用するとともに、日次で使用量算出処理および配送予測処理などを行い、LPガスの配送業務の効率化へ活用する。具体的には、ガスボンベ20を配送する上で最適な配送日と効率的な(最適な)配送経路(配送ルート)を予測し、複数の配送車に積載するガスボンベ20の本数を指示するまでのプロセスを自動的に行う。 As described above, in the gas supply management system 10 using the LPWA of the present embodiment, information transmission is performed regardless of the meter reading operation of the meter reader (for example, the reception / collection processing of the gas meter information by the portable terminal 12 of the first embodiment). The management device 13 can automatically acquire the gas meter information transmitted by the device 11 remotely. Thereby, the management apparatus 13 can grasp | ascertain the gas meter information containing gas consumption frequently. Here, frequent means that the frequency is higher (higher) than monthly, for example, grasping at a frequency higher than the frequency such as once a month or once a week. Specifically, in the present embodiment, for example, gas meter information can be acquired daily and the amount of gas used can be grasped. As a result, the management device 13 utilizes the acquired gas meter information for monthly meter reading work in the LP gas sales business, and performs daily usage calculation processing and delivery prediction processing to improve the efficiency of LP gas delivery work. Take advantage of. Specifically, an optimal delivery date and an efficient (optimum) delivery route (delivery route) are predicted for delivering the gas cylinders 20, and the number of gas cylinders 20 loaded on a plurality of delivery vehicles is instructed. Perform the process automatically.
 携帯端末12は、第1実施形態と同様(図3参照)の例えば移動体通信が可能な端末であり、ネットワークNW1(NW3)の無線基地局31を介して管理装置13、格納装置30や情報送信装置11などとガスメータ情報を含む情報の送受信が可能に構成されている。また、表示手段121によって地理情報等を表示可能に構成されている。 The mobile terminal 12 is a terminal capable of mobile communication, for example, as in the first embodiment (see FIG. 3), and the management device 13, the storage device 30 and information via the radio base station 31 of the network NW1 (NW3). Information including gas meter information can be transmitted / received to / from the transmission device 11 and the like. Further, the display unit 121 is configured to display geographic information and the like.
 携帯端末12は、第2実施形態では例えば、ガスボンベ20の配送者が携行したり、ガスボンベ20の配送車両等に取り付けられることができ、少なくとも管理装置13及び/または格納装置30との間で情報の送受信が可能であればよい。すなわち、第2実施形態では、情報送信装置11が取得したガスメータ情報は自動で格納装置30に格納されるため、携帯端末12がガスメータ情報を取得、収集可能に構成されていなくてもよい。しかしながら、第1実施形態と同様に、情報送信装置11が取得したガスメータ情報を適宜、携帯端末12によって取得、収集可能に構成されていてもよい。 In the second embodiment, for example, the portable terminal 12 can be carried by a delivery person of the gas cylinder 20 or attached to a delivery vehicle of the gas cylinder 20, and information between at least the management device 13 and / or the storage device 30 can be obtained. As long as it is possible to transmit and receive. That is, in the second embodiment, the gas meter information acquired by the information transmission device 11 is automatically stored in the storage device 30, and therefore the mobile terminal 12 may not be configured to be able to acquire and collect the gas meter information. However, similarly to the first embodiment, the gas meter information acquired by the information transmission device 11 may be appropriately acquired and collected by the mobile terminal 12.
 携帯端末12には、管理装置13が予測した配送に関する情報(配送先(供給先施設U、以下同様)、配送ルート、あるいは配送状況に関する情報等)が送信され、表示手段121に表示可能となっている。また、携帯端末12は、配送者の出勤予定や、配送先、配送ルート、配送状況に関する情報、保安点検情報等の登録(更新)を受付け、管理装置13および/または格納装置30にこれらの情報を送信可能に構成されている。また、文字や画像情報の読み込み、バーコードスキャン、配送伝票の表示(および出力)等が可能である。 Information relating to delivery predicted by the management device 13 (delivery destination (supply destination facility U, the same applies hereinafter), delivery route, or information relating to delivery status, etc.) is transmitted to the mobile terminal 12 and can be displayed on the display means 121. ing. The mobile terminal 12 accepts registration (update) of the delivery schedule, delivery destination, delivery route, delivery status information, security check information, etc. of the delivery person, and these information is stored in the management device 13 and / or the storage device 30. Can be sent. In addition, reading of characters and image information, barcode scanning, display (and output) of delivery slips, and the like are possible.
 例えば、ガスボンベ20の配送者は、携帯端末12を介して、管理装置13に自身の出勤予定等を予め登録したり、配送先、配送ルートや配送状況に関する情報の登録・確認・修正(送受信)等を行う。 For example, the delivery person of the gas cylinder 20 registers his / her attendance schedule or the like in the management device 13 in advance via the portable terminal 12, and registers / confirms / corrects (transmission / reception) information on the delivery destination, delivery route and delivery status. Etc.
 <管理装置>
 図11を参照して、第2実施形態に係る管理装置13の一例について説明する。同図(a)は、管理装置13の構成の概略を示すブロック図であり、同図(b)は、管理装置13の機能の概略を示すブロック図である。なお、第1実施形態と同様の構成・機能についてはその詳細な説明を省略するが、既に述べたように第2実施形態の管理装置13は、以下で説明する構成・機能に加えて、第1実施形態で説明した構成・機能を有し、適宜、並列してあるいは切り替えて各種処理を実行可能に構成されていてもよい。
<Management device>
An example of the management device 13 according to the second embodiment will be described with reference to FIG. 2A is a block diagram showing an outline of the configuration of the management apparatus 13, and FIG. 2B is a block diagram showing an outline of functions of the management apparatus 13. As shown in FIG. The detailed description of the same configurations and functions as those of the first embodiment is omitted, but as already described, the management device 13 of the second embodiment has a configuration and functions described below. The configuration / function described in the embodiment may be included, and may be configured to execute various processes in parallel or switching as appropriate.
 同図(a)に示すように、管理装置13は、格納装置(例えば、クラウドサーバ)30と、インターネットなどのネットワークNW1を介して接続し、携帯端末12と例えば移動体通信回線などのネットワークNW1(またはネットワークNW3)を介して接続し、事業者用サーバ装置14と例えばインターネットや専用回線などのネットワークNW2を介して接続する例えばサーバ装置(またはパーソナルコンピュータ(PC))であり、CPU130、ROM131、RAM132、記憶手段(記憶装置)133、入力手段134、表示手段135、通信手段136などを有する。 As shown in FIG. 3A, the management device 13 is connected to a storage device (for example, a cloud server) 30 via a network NW1 such as the Internet, and is connected to the mobile terminal 12 and a network NW1 such as a mobile communication line. (Or network NW3), for example, a server device (or personal computer (PC)) connected to the provider server device 14 via a network NW2 such as the Internet or a dedicated line, and includes a CPU 130, a ROM 131, A RAM 132, a storage unit (storage device) 133, an input unit 134, a display unit 135, a communication unit 136, and the like are included.
 通信手段136は、携帯端末12や格納装置30とネットワークNW1を介して通信を行い、事業者用サーバ装置14と、例えばネットワークNW2を介して通信行う。CPU130、ROM131、RAM132、記憶手段(記憶装置)133、入力手段134、表示手段135の構成は、第1実施形態と同様である。 The communication unit 136 communicates with the mobile terminal 12 and the storage device 30 via the network NW1, and communicates with the business server device 14 via the network NW2, for example. The configurations of the CPU 130, ROM 131, RAM 132, storage means (storage device) 133, input means 134, and display means 135 are the same as those in the first embodiment.
 管理装置13は、同図(b)に示すように、基幹処理手段55や配送管理手段50を備え、配送管理手段50は、例えば、使用量算出手段137、配送予測手段138や地理情報表示手段139などを有する。 As shown in FIG. 2B, the management apparatus 13 includes a basic processing unit 55 and a delivery management unit 50. The delivery management unit 50 includes, for example, a usage calculation unit 137, a delivery prediction unit 138, and a geographic information display unit. 139 and the like.
 管理装置13は、ROM131などに記憶されたソフトウェアプログラムがRAM132のワークエリアに読み出されてCPU130によって当該ソフトウェアプログラムが実行されることにより、ガス供給管理処理を実行する。このガス供給管理処理には、基幹処理や、配送管理処理として使用量算出処理、配送予測処理および地理情報表示処理等が含まれ、これにより管理装置13は、基幹処理手段55、配送管理手段50(使用量算出手段137、配送予測手段138、地理情報表示手段139)の機能を実現する。 The management device 13 reads the software program stored in the ROM 131 or the like into the work area of the RAM 132 and executes the software program by the CPU 130, thereby executing the gas supply management process. This gas supply management process includes a basic process and a usage calculation process, a delivery prediction process, a geographic information display process, and the like as a delivery management process. The functions of (usage calculation unit 137, delivery prediction unit 138, geographic information display unit 139) are realized.
 この例では、基幹処理手段55や、配送管理手段50(これらの機能を実現するアプリケーションプログラム)は格納装置30に格納され、クラウドコンピューティングシステムによって管理装置13において利用されるように構成されている。しかしこれに限らず、基幹処理手段55や配送管理手段50(これらの機能を実現するアプリケーションプログラム)は、管理装置13の記憶手段(管理装置13と接続する記憶手段)に格納されていても良い。 In this example, the basic processing means 55 and the delivery management means 50 (application programs for realizing these functions) are stored in the storage device 30 and used in the management device 13 by the cloud computing system. . However, the basic processing means 55 and the delivery management means 50 (application programs for realizing these functions) may be stored in the storage means of the management apparatus 13 (storage means connected to the management apparatus 13). .
 基幹処理手段(基幹処理)55は、主に、ガスメータ情報に基づき、月次で(月ごとに)点検情報を反映した保安管理処理、在庫を反映した配送管理(在庫管理)処理、顧客情報などデータベースの更新処理、その他既知の基幹業務処理などを行うものである。 Core processing means (main processing) 55 is mainly based on gas meter information, security management processing that reflects inspection information on a monthly basis (monthly), delivery management (inventory management) processing that reflects inventory, customer information, etc. It performs database update processing and other known core business processing.
 配送管理手段(配送管理処理)50は、高い頻度(例えば、月に1回あるいは週に1回よりも高い頻度)でガスメータ情報を取得し、将来の日付けにおける使用量を予測し、それに基づきガスボンベ20の配送の予定日と最適な配送ルートを予測し、地理情報と併せて配送ルートを管理装置13の表示手段135に表示し、携帯端末12に配送ルートを送信する。 The delivery management means (delivery management process) 50 obtains gas meter information at a high frequency (for example, once a month or higher than once a week), predicts the usage amount in the future date, and based on this The scheduled delivery date and the optimal delivery route of the gas cylinder 20 are predicted, the delivery route is displayed on the display unit 135 of the management device 13 together with the geographical information, and the delivery route is transmitted to the portable terminal 12.
 使用量算出手段(使用量算出処理)137は、格納装置30から取得したガスメータ情報のガス使用量(指針値)や図4(c)に示すガスメータ管理情報に基づき、所定期間におけるガスボンベ20ごとの実際のガス使用量(指針値)と、ガスボンベ20内のガス残量を算出し、LPガスメータ21ごとに記憶手段133あるいは格納装置30に記憶・蓄積する。 Based on the gas usage (guideline value) of the gas meter information acquired from the storage device 30 and the gas meter management information shown in FIG. The actual amount of gas used (guideline value) and the remaining amount of gas in the gas cylinder 20 are calculated and stored and stored in the storage unit 133 or the storage device 30 for each LP gas meter 21.
 配送予測手段(配送予測処理)138は、格納装置30から取得したガスメータ情報(ガスボンベ20の使用量等)や図4(c)に示すガスメータ管理情報に基づき、供給元(LPガス事業者、支店、充填所、配送センタ、小売事業者など)ごとにガスボンベ20の配送の予定日と最適な配送ルートを予測する。 The delivery prediction means (delivery prediction processing) 138 is based on the gas meter information acquired from the storage device 30 (the usage amount of the gas cylinder 20) and the gas meter management information shown in FIG. The estimated delivery date of the gas cylinder 20 and the optimal delivery route are predicted for each of the filling station, the delivery center, the retailer, and the like.
 詳細は後述するが、具体的には、配送予測手段(配送予測処理)138は、将来の日付けにおける日別の予測使用量(日別予測使用量)を算出する。この日別予測使用量は、例えば、過去の所定期間における基準ガス使用量に基づいて日毎の単位予測使用変化量を算出することによって、日数の経過に伴って増加又は減少するように算出される。 Although details will be described later, specifically, the delivery prediction means (delivery prediction processing) 138 calculates a daily predicted usage amount (daily predicted usage amount) in a future date. This daily predicted usage is calculated so as to increase or decrease as the number of days elapses, for example, by calculating the unit predicted usage change amount for each day based on the reference gas usage in the past predetermined period. .
 そして、配送予測手段(配送予測処理)138は、算出した日別予測使用量に基づいてガスボンベ20内の将来の日付けにおける日別のガス残量の予測値(ガス残量予測値)を算出し、ガス残量予測値が所定量に減量する日付けを予測して配送の予定日を決定する。 Then, the delivery predicting means (delivery prediction processing) 138 calculates a predicted value (gas remaining amount predicted value) of the daily gas remaining amount in the future date in the gas cylinder 20 based on the calculated daily predicted usage amount. The estimated delivery date is determined by predicting the date when the gas remaining amount prediction value is reduced to a predetermined amount.
 さらに、配送予測手段(配送予測処理)138は、決定した配送の予定日に基づき、最適な配送ルートを予測し、当該配送ルートを管理装置13の表示手段135に表示し、またガスボンベ20の配送者が所持する携帯端末12に送信する。 Further, the delivery predicting means (delivery predicting process) 138 predicts an optimal delivery route based on the determined scheduled delivery date, displays the delivery route on the display means 135 of the management device 13, and delivers the gas cylinder 20. To the portable terminal 12 possessed by the person.
 次に、図12を参照して、第2実施形態のガス供給管理システム10(ガス供給管理方法)における、配送管理手段50における処理(配送管理処理)について説明する。同図は、主に管理装置13における配送管理手段50における処理と、携帯端末12における処理の流れの一例を示すブロック図である。 Next, processing (delivery management processing) in the delivery management means 50 in the gas supply management system 10 (gas supply management method) of the second embodiment will be described with reference to FIG. This figure is a block diagram showing an example of the flow of processing mainly in the delivery management means 50 in the management device 13 and the processing in the mobile terminal 12.
 配送管理手段(配送管理処理)50では、例えば、使用量・配送予測処理や配送ルート確定処理を行う。使用量・配送予測処理は、例えば、ガスメータ情報取得処理S01、使用量算出処理S02(137)や、配送予測処理S03(138)や、配送情報登録処理S09などを行う。配送予測処理S03では例えば、予測使用量算出処理S04、予測計算処理S05、限界日算出処理S06、配送計画データ作成処理S07、配送対象抽出処理S08などを行う。 The delivery management means (delivery management process) 50 performs, for example, a usage / delivery prediction process and a delivery route determination process. The usage / delivery prediction process includes, for example, a gas meter information acquisition process S01, a usage calculation process S02 (137), a delivery prediction process S03 (138), and a delivery information registration process S09. In the delivery prediction process S03, for example, a predicted usage calculation process S04, a prediction calculation process S05, a limit date calculation process S06, a delivery plan data creation process S07, a delivery target extraction process S08, and the like are performed.
 また、配送ルート確定処理は例えば、カレンダー登録処理S21や、配送情報決定処理S23(日次配車回転数確定処理S25、当日配送対象抽出処理S27、配送車別配送決定処理S29)や、配送ルート表示処理S31などを行う。 Further, the delivery route determination process includes, for example, a calendar registration process S21, a delivery information determination process S23 (daily vehicle dispatch rotation speed determination process S25, same day delivery target extraction process S27, and delivery vehicle specific delivery determination process S29), and a delivery route display. Processing S31 etc. are performed.
 携帯端末12では、シフト登録処理S11、担当者別配送箇所抽出処理S13、配送登録処理S15、配送完了登録処理S17などを行う。 The mobile terminal 12 performs a shift registration process S11, a person-by-person delivery location extraction process S13, a delivery registration process S15, a delivery completion registration process S17, and the like.
 配送管理手段(配送管理処理)50のガスメータ情報取得処理S01は、格納装置30に格納されたガスメータ情報を取得する。本実施形態では、ネットワークNW3(LPWAネットワーク)を利用することで、検針員等による検針作業によることなく、従来よりも多頻度で(例えば、月次(1ヶ月に1度)や週次(1週間に1度)などの頻度よりも多い頻度で)、管理装置13が情報送信装置11からガスメータ情報を自動で取得することができる。具体的には、管理装置13(配送管理手段50)は、2~3日に1度のペース、より好適には1日に1度のペース、あるいはそれよりも短期間の頻度で、対象となる各ガスボンベ20のガスメータ情報を自動で取得することができる。以下の説明では、一例として、管理装置13(配送管理手段50)が、格納装置30に格納されたガスメータ情報を一日に一度のペースで(日次で)取得する場合について説明する。 The gas meter information acquisition process S01 of the delivery management means (delivery management process) 50 acquires the gas meter information stored in the storage device 30. In this embodiment, by using the network NW3 (LPWA network), it is more frequent than before (for example, monthly (once a month) or weekly (1 The management device 13 can automatically acquire the gas meter information from the information transmission device 11 at a frequency higher than a frequency such as once a week). Specifically, the management device 13 (delivery management means 50) is targeted at a frequency of once every two to three days, more preferably once a day, or a shorter frequency. The gas meter information of each gas cylinder 20 can be acquired automatically. In the following description, as an example, a case will be described in which the management device 13 (delivery management means 50) acquires the gas meter information stored in the storage device 30 once a day (daily).
 ガスメータ情報取得処理S01では、日ごとに(日次で)ガスメータ情報を取得する対象となるLPガスの契約者(以下、「日次情報取得対象者」という。)の抽出を行い、例えば、(供給元識別番号及び)LPガスの固有番号(例えば、LPガスメータの製造番号)をキーとして、事業者用サーバ装置14で保持する各日次情報取得対象者の個人情報に紐付けを行う。そして、日次情報取得対象者ごとに、供給元識別番号、LPガスの固有番号、取得したガスメータ情報、日付け及び個人情報等を入力データとして準備する。 In the gas meter information acquisition process S01, an LP gas contractor (hereinafter referred to as "daily information acquisition target person") from which gas meter information is acquired every day (daily) is extracted. Using the supplier identification number and the LP gas unique number (for example, LP gas meter manufacturing number) as a key, the personal information of each daily information acquisition target held in the business server device 14 is linked. Then, the supply source identification number, the LP gas unique number, the acquired gas meter information, the date, personal information, and the like are prepared as input data for each person who acquires the daily information.
 また、配送ルート確定処理のカレンダー登録処理S21では、LPガスの供給元の担当者(配送管理者)による、配送車の車輌種別毎の稼働台数の登録を受け付ける。配送管理者は、ガスボンベ20の積載量が異なる配送車の車輌種別毎に、日別で稼動が可能な台数を予め登録する。 In addition, in the calendar registration process S21 of the delivery route confirmation process, registration of the number of operating vehicles for each type of delivery vehicle by the person in charge (delivery manager) of the LP gas supply source is accepted. The delivery manager registers in advance the number of vehicles that can be operated on a daily basis for each vehicle type of delivery vehicle with different loading capacity of the gas cylinders 20.
 携帯端末12は、ここではガスボンベ20の配送者が所持(携行)する移動体通信が可能な端末装置である。シフト登録処理S11では、携帯端末12が、配送者のシフト登録を受付け、当該情報を管理装置13(の配送管理手段50)に送信する。シフトとは、例えば、配送者の直近7日間の出勤予定や、労働可能時間などを含む情報である。 Here, the portable terminal 12 is a terminal device capable of mobile communication that is carried (carried) by the delivery person of the gas cylinder 20. In the shift registration process S11, the portable terminal 12 receives the shift registration of the delivery person and transmits the information to the management device 13 (the delivery management means 50). The shift is information including, for example, the work schedule of the delivery person for the latest seven days, the available working hours, and the like.
 使用量算出処理S02(137)は、LPガスの固有番号(供給元識別番号を含む場合もある。以下同様)をキーとして、日次情報取得対象者ごとに、管理装置13(または格納装置30)に格納されている前回のガスメータ情報を取得し、前回のガスメータ情報に含まれるガス使用量(指針値)と、今回取得したガスメータ情報に含まれるガス使用量(指針値)とによって、前回のガスメータ情報の取得以降のガス使用量、ガス使用量の変化量、ガスボンベ20内のガス残量などを算出する。 The usage amount calculation process S02 (137) uses the LP gas unique number (which may include a supply source identification number; the same applies hereinafter) as a key for each management person 13 (or storage device 30) for each person who acquires the daily information. ), The previous gas meter information stored in the previous gas meter information and the gas usage (guideline value) included in the previous gasmeter information and the gas usage (guideline value) included in the gasmeter information acquired this time. The amount of gas used since the acquisition of the gas meter information, the amount of change in the amount of gas used, the remaining amount of gas in the gas cylinder 20 and the like are calculated.
 従来既知のLPガスの配送予測では、月次またはそれに近いサイクルでガスメータ情報(指針値)を取得しており、誤差が大きい問題があったが、本実施形態では、例えば日次サイクルでガスメータ情報の取得ができるため、月中の使用量(変化)ではなく日々の使用量(変化)を把握でき、正確な配送予測が可能となる。 In the conventional delivery prediction of LP gas, gas meter information (guideline value) is acquired monthly or a cycle close to it, and there is a problem that the error is large. However, in this embodiment, for example, gas meter information in a daily cycle. Therefore, it is possible to grasp daily usage (change), not monthly usage (change), and to accurately predict delivery.
 配送予測処理S03(138)は、指示回転数や、取得したガスメータ情報に基づき、予測使用量算出処理S04、予測計算処理S05、限界日算出処理S06、配送計画データ作成処理S07を行い、LPガスの契約者ごとの日別予測使用量や、配送(交換)が保留できる限界日、配送計画データなどを出力する。ここで指示回転数は、例えば季節ごとに基準となる1台の配送車による1日当りの配送の回転数である。例えば配送予測手段138には、季節等に応じて所定数(例えば、2回、3回)が予め設定されており、また適宜変更も可能となっている。またガスメータ情報には、管理装置13が日次で格納装置30から自動で取得するガスメータ情報に加え、検針員によって検針時に取得されるガスメータ情報や配送者によって取得される配送時のガスメータ情報も含まれる。 The delivery prediction process S03 (138) performs an estimated usage amount calculation process S04, a prediction calculation process S05, a limit date calculation process S06, and a delivery plan data creation process S07 based on the indicated rotational speed and the acquired gas meter information, and LP gas The daily estimated usage amount for each contractor, the limit date on which delivery (exchange) can be suspended, delivery plan data, and the like are output. Here, the designated rotational speed is, for example, the rotational speed of delivery per day by a single delivery vehicle serving as a reference for each season. For example, a predetermined number (for example, twice or three times) is set in advance in the delivery prediction unit 138 according to the season or the like, and can be changed as appropriate. The gas meter information includes gas meter information acquired by the meter reader at the time of meter reading and gas meter information at the time of delivery acquired by the delivery person in addition to the gas meter information automatically acquired from the storage device 30 by the management device 13 on a daily basis. It is.
 予測使用量算出処理S04は、使用量算出処理S02において得られた日次情報取得対象者のごとのガス残量が予測開始閾値(予測開始残ガス率)に達しているか(予測開始閾値を下回っているか否か)を判定する。そして、予測開始閾値を下回る他、所定の条件が成立する日次情報取得対象者について、当該対象者ごとに予測計算処理S05を実行し、将来の日付けにおける日別予測使用量を算出する。日別予測使用量の算出処理(予測計算処理S05)の詳細については、後述する。 In the predicted usage calculation process S04, whether or not the remaining gas amount for each of the daily information acquisition targets obtained in the usage calculation process S02 has reached the prediction start threshold (prediction start residual gas rate) (below the prediction start threshold). Or not). Then, for a daily information acquisition target person who satisfies a predetermined condition in addition to being less than the prediction start threshold value, the prediction calculation process S05 is executed for each target person to calculate the daily predicted usage amount in the future date. Details of the daily predicted usage calculation process (prediction calculation process S05) will be described later.
 ここで、図13を参照して本実施形態の配送予測処理S03で使用する閾値について説明する。配送予測処理S03では、例えば、予測開始閾値(予測開始残ガス率)、ガス残量閾値(残ガス率)、配送限界閾値(限界率)が設定されている。これらの閾値は、例えば、ガスボンベ20の全量に対するガス残量の割合である。 Here, the threshold used in the delivery prediction process S03 of the present embodiment will be described with reference to FIG. In the delivery prediction process S03, for example, a prediction start threshold (prediction start residual gas rate), a gas remaining amount threshold (residual gas rate), and a delivery limit threshold (limit rate) are set. These threshold values are, for example, the ratio of the remaining gas amount to the total amount of the gas cylinder 20.
 予測開始閾値は、予測計算処理S05の開始の判断条件であり、ガスボンベ20内の実際のガス残量が予測開始閾値を下回った場合に予測計算処理S05を開始する。この例では予測開始閾値は、15%である。 The prediction start threshold is a determination condition for starting the prediction calculation process S05, and the prediction calculation process S05 is started when the actual remaining gas amount in the gas cylinder 20 falls below the prediction start threshold. In this example, the prediction start threshold is 15%.
 ガス残量閾値(残ガス率)は、後述する配送計画データの作成に際し、交換対象とするガスボンベ20に優先順位を付すための閾値である。予測計算処理S05により将来の日付の日別予測使用量およびガス残量を予測し、予測したガス残量(ガス残量予測値)がガス残量閾値を下回った場合に最優先の交換対象とする。この例ではガス残量閾値は、10%である。 The gas remaining amount threshold value (residual gas rate) is a threshold value for giving priority to the gas cylinders 20 to be exchanged when creating delivery plan data described later. The predicted daily usage and gas remaining amount for the future date are predicted by the prediction calculation process S05, and when the predicted gas remaining amount (gas remaining amount predicted value) falls below the gas remaining amount threshold, To do. In this example, the gas remaining amount threshold is 10%.
 配送限界閾値(限界率)は、後述する配送の限界日を決定するための閾値である。予測計算処理S05により将来の日付の日別予測使用量およびガス残量を予測し、予測したガス残量(ガス残量予測値)が配送限界閾値を下回った場合、その数日前の日付を配送の限界日とする。この例では配送限界閾値は、5%である。 The delivery limit threshold (limit rate) is a threshold for determining a delivery limit date, which will be described later. Predicted daily usage and gas remaining amount in the future date is predicted by the prediction calculation process S05, and if the predicted remaining gas amount (remaining gas predicted value) falls below the delivery limit threshold, the date a few days before is delivered The limit date. In this example, the delivery limit threshold is 5%.
 これにより、ガス残量予測値が、ガス残量閾値と配送限界閾値の間に有るガスボンベ20が配送(交換)対象のガスボンベ20となる。例えば、配送対象のガスボンベ20の数が多い場合は問題がないが、配送対象のガスボンベ20の数が少ない場合、配送が非効率になる。このような場合は、適宜、ガス残量閾値を増加させ(例えば15%とし)、配送対象となるガスボンベ20の数を増加させる。 Thereby, the gas cylinder 20 whose gas remaining amount prediction value is between the gas remaining amount threshold value and the delivery limit threshold value becomes the gas cylinder 20 to be delivered (replaced). For example, there is no problem when the number of gas cylinders 20 to be delivered is large, but the delivery becomes inefficient when the number of gas cylinders 20 to be delivered is small. In such a case, the gas remaining amount threshold value is appropriately increased (for example, 15%), and the number of gas cylinders 20 to be delivered is increased.
 また、これらの閾値は、日次情報取得対象者であるか否かによらず、各LPガスの契約者の過去の利用状況等に応じてそれぞれの契約者毎に設定(適宜調整)される。 These thresholds are set (adjusted as appropriate) for each contractor according to the past usage situation of each LP gas contractor, regardless of whether or not the person is a daily information acquisition target. .
 再び図12を参照し、予測使用量算出処理S04では、日次情報取得対象者以外のLPガスの契約者についてのガスメータ情報を別途取得する。例えば、ネットワークNW3(LPWAネットワーク)を利用できない地域のLPガスの契約者などについては、例えば、第1実施形態の携帯端末12を用いた検針や、検針者あるいはガスボンベ20の配送者による検針作業などによって検針時あるいはガスボンベ20の配送時に適宜ガスメータ情報を取得し、(例えば別の管理システムなどを用いて)管理している。予測使用量算出処理S04では、このような日次情報取得対象者以外のLPガスの契約者についても(別の管理システム等から)ガスメータ情報を取得し、前回のガスメータ情報に含まれるガス使用量(指針値)と、今回取得したガスメータ情報に含まれるガス使用量(指針値)とによって、前回のガスメータ情報の取得からのガス使用量、ガス使用量の変化量、ガス残量などを算出する。そして、日次情報取得対象者以外のLPガスの契約者ごとに、予測計算処理S05を実行し、将来の日付けにおける日別予測使用量を算出する。 Referring to FIG. 12 again, in the predicted usage calculation processing S04, gas meter information about LP gas contractors other than the daily information acquisition target person is acquired separately. For example, for LP gas contractors in areas where the network NW3 (LPWA network) cannot be used, for example, meter reading using the portable terminal 12 of the first embodiment, meter reading work by a meter reader or a delivery person of the gas cylinder 20 etc. Therefore, gas meter information is appropriately acquired at the time of meter reading or at the time of delivery of the gas cylinder 20, and managed (for example, using another management system). In the predicted usage calculation process S04, gas meter information is acquired (from another management system or the like) for LP gas contractors other than the daily information acquisition target person, and the gas usage included in the previous gas meter information is acquired. (Guideline value) and the amount of gas used (Guideline value) included in the gas meter information acquired this time, calculate the amount of gas used since the previous acquisition of gas meter information, the amount of change in gas usage, the remaining amount of gas, etc. . Then, the prediction calculation process S05 is executed for each LP gas contractor other than the daily information acquisition target person, and the daily predicted usage amount in the future date is calculated.
 以下、日次情報取得対象者と情報取得対象者以外のLPガスの契約者の区別が不要な場合は、両者を含めて「LPガス契約者」と総称して説明する。 Hereafter, when it is not necessary to distinguish between the daily information acquisition target person and the LP gas contractor other than the information acquisition target person, they will be collectively referred to as “LP gas contractor”.
 限界日算出処理S06は、予測使用量算出処理S04で算出した将来の日付けにおける日別予測使用量に基づき、将来の日付けにおける日別のガス残量の予測値(ガス残量予測値)を算出し、ガス残量予測値が予め定められた配送限界閾値に到達する日付けを予想する。配送限界閾値(限界率)は、例えばガス残量閾値よりも低い(小さい)値であり(図13参照)、配送を保留する限界を越える(すぐに配送・交換を行わなければならない)限界の値である。そして、配送限界閾値に到達する日付けよりも所定日数(2日~数日)分前倒しした日付けを配送の限界日として算出する。以下、この前倒しする日数(2日~数日)を「限界日数」という。 The limit date calculation process S06 is based on the predicted daily usage amount in the future date calculated in the predicted usage amount calculation process S04, and the predicted value of the remaining gas amount in the future date (predicted residual gas value). And the date when the gas remaining amount prediction value reaches a predetermined delivery limit threshold is predicted. The delivery limit threshold (limit rate) is, for example, a value lower (smaller) than the gas remaining amount threshold (see FIG. 13), and exceeds the limit for deferring delivery (the delivery / exchange must be performed immediately). Value. Then, a date that is a predetermined number of days (2 days to several days) ahead of the date that reaches the delivery limit threshold is calculated as the delivery limit date. Hereinafter, the number of days to be advanced (2 to several days) is referred to as “limit days”.
 なお、限界日算出処理S06の詳細についても後述するが、ガス残量閾値や配送限界閾値、限界日数は、ガスの使用状況等に応じて、各LPガス契約者(供給先施設U、ガスボンベ20)ごとに設定されている。 The details of the limit date calculation process S06 will be described later. The gas remaining amount threshold value, the delivery limit threshold value, and the limit days are set according to the LP gas contractor (supplier facility U, gas cylinder 20) according to the gas usage status and the like. ) Is set for each.
 配送計画データ作成処理S07は、指示回転数を満たし、所定期間内(例えば、直近7日間以内)に配送の限界日が到来する供給先施設Uに関する情報(例えば、ガスボンベ20(供給先施設U)の位置情報(地理情報、住所等)を含む情報、配送の限界日等を含む情報、ガスボンベ20の固有番号等)を抽出し、指示回転数、最優先で配送する供給先施設Uの位置情報とその住所、予備の配送先となる供給先施設Uの位置情報とその住所、供給先施設Uごとの配送の優先順位、ガスボンベ20の固有番号等を配送計画データとして出力する。 In the delivery plan data creation process S07, information (for example, the gas cylinder 20 (supply destination facility U) regarding the supply destination facility U that satisfies the designated rotational speed and whose delivery limit date comes within a predetermined period (for example, within the last seven days) is reached. Information including location information (geographical information, address, etc.), information including delivery date limit, unique number of gas cylinder 20, etc.), the designated rotational speed, and the location information of the delivery destination facility U that delivers the highest priority And the address, the location information of the supply destination facility U as a spare delivery destination, the address, the delivery priority for each supply destination facility U, the unique number of the gas cylinder 20 and the like are output as delivery plan data.
 優先順位は、ガス残量閾値および予測開始閾値に基づき判定する。一例として、ガス残量予測値がガス残量閾値を下回った場合、その供給先施設U(ガスボンベ20)を最優先配送先の対象とする。また、ガス残量予測値が予測開始閾値を下回った場合、その供給先施設U(ガスボンベ20)を予備配送先の対象とする。予備配送先は最優先配送先よりも優先順位は低く、後に最適な配送ルートを導き出す際に、効率的な配送のために配送の限界日を前倒しするための予備として準備する配送先である。 Priority is determined based on the remaining gas threshold and the prediction start threshold. As an example, when the gas remaining amount prediction value falls below the gas remaining amount threshold value, the supply destination facility U (gas cylinder 20) is the target of the highest priority delivery destination. In addition, when the gas remaining amount prediction value falls below the prediction start threshold value, the supply destination facility U (gas cylinder 20) is set as the target of the preliminary delivery destination. The spare delivery destination has a lower priority than the highest-priority delivery destination, and is a delivery destination prepared as a spare to advance the delivery limit date for efficient delivery when an optimum delivery route is derived later.
 本実施形態では、日次サイクルでガスの使用量(変化量)を取得でき、日別予測使用量および、日別のガス残量予測値を計算できるので、配送の限界日を実際の配送の限界に極めて近く且つ正確に予測することができる。例えば、配送の限界日は、ガスボンベ20内のガス残量予測値が全体の5%以下になる2日前の日付けとして算出する(2日以内にガスボンベ20内のガス残量予測値が全体の5%以下になる日を取得する)ことが可能となる。これにより、ガス残量が例えば全体の50%になる日を予測して配送(交換)を行っていた従来と比較して、格段に配送効率を高めることができる。 In this embodiment, the amount of gas used (change amount) can be acquired in the daily cycle, and the daily predicted usage amount and the daily gas remaining amount prediction value can be calculated. Very close to the limit and can be predicted accurately. For example, the delivery limit date is calculated as a date two days before the estimated amount of gas remaining in the gas cylinder 20 is 5% or less of the total (the estimated amount of gas remaining in the gas cylinder 20 is within 2 days. It is possible to obtain a day that will be 5% or less. As a result, the delivery efficiency can be significantly improved as compared with the conventional case where the delivery (exchange) is performed by predicting the day when the remaining amount of gas is, for example, 50%.
 配送対象抽出処理S08は、限界日算出処理S06で算出した配送の限界日や、配送計画データ作成処理S07で作成した配送計画データ(これに含まれる優先順位)などに基づき、所定期間内(例えば、直近7日間以内)に、配送の限界日が到来し、且つ、配送作業が完了していないLPガス契約者に対応するガスボンベ20(供給先施設U)を配送対象として抽出し、必要に応じて、例えば、優先順位や、限界日が同日(または近い日付けである)などの所定の条件によって複数の供給先施設Uをグループ化する。そして、グループ化した供給先施設U(供給先施設グループ)の位置情報(配送対象位置情報)や、供給先施設グループに関する情報(例えば、ガスメータ情報や日別予測使用量などを含む情報)を、配送計画データの一部として配送ルート確定処理(配送情報決定処理S23)に送信する。 The delivery target extraction process S08 is performed within a predetermined period (for example, based on the delivery limit date calculated in the limit date calculation process S06, the delivery plan data created in the delivery plan data creation process S07 (priorities included therein), and the like. The gas cylinder 20 (supplier facility U) corresponding to the LP gas contractor for which the delivery limit date has arrived and the delivery operation has not been completed is extracted as a delivery target within the last seven days, and if necessary Thus, for example, a plurality of supply destination facilities U are grouped according to a predetermined condition such as a priority order or a limit date on the same day (or a date close to the same date). Then, the location information (delivery target location information) of the grouped supply destination facility U (supply destination facility group) and information on the supply destination facility group (for example, information including gas meter information and daily predicted usage amount) The data is transmitted to the delivery route determination process (delivery information determination process S23) as part of the delivery plan data.
 配送情報決定処理S23では、配送計画データや、当日の配送可能回転数などに基づき、日次配車回転数確定処理S25、当日配送対象抽出処理S27、配送車別配送決定処理S29などを行い、配送車毎に最適な配送ルート、最適な積載容量などを決定し、配送指示として出力する。 In the delivery information determination process S23, based on the delivery plan data, the number of revolutions that can be delivered on the current day, etc., the daily delivery speed determination process S25, the same day delivery object extraction process S27, the delivery decision process S29 for each delivery vehicle, and the like are performed. The optimal delivery route, optimal load capacity, etc. are determined for each vehicle and output as a delivery instruction.
 日次配車回転数確定処理S25は必要に応じて実行され、配送者のシフト、配送車の稼働台数や回転数などの入力(修正)を受付け、配送対象抽出処理S08で抽出された配送対象となる供給先施設グループの再グループ化(抽出も含む)を行う。例えば、日次配車回転数確定処理S25は、情報修正処理S26を有しており、配送者の急な休暇や勤務可能時間の変更があった場合、あるいは天候状況に応じて、配送車の稼働台数や配送の回転数(指示回転数)に無理が生じた場合などには、配送者のシフト、稼働台数、および指示回転数の修正値としての配達可能回転数など各種情報の修正(再登録)を受付ける。そして、修正された情報に基づき、配送対象抽出処理S08で抽出された供給先施設グループの再グループ化を行い、配送を行う配送車(稼働台数)および、配送車ごとの配送の回転数を修正(調整)する。 The daily vehicle rotation speed determination process S25 is executed as necessary, and accepts input (correction) such as a shift of the delivery person, the number of operation of the delivery car and the rotation speed, and the distribution target extracted in the delivery target extraction process S08. Re-group (including extraction) the destination facility group. For example, the daily dispatch speed determination process S25 includes an information correction process S26, and when the delivery person suddenly takes a break or the working hours are changed, or the delivery car is operated according to the weather condition. If the number of units or the number of delivery revolutions (indicated revolutions) is unreasonable, various information such as the shift of the delivery person, the number of units in operation, and the deliverable number of revolutions as a revised value of the designated number of revolutions (re-registration) ). Based on the corrected information, the supply destination facility group extracted in the delivery target extraction process S08 is regrouped, and the delivery vehicle (operating number) for delivery and the rotation speed of delivery for each delivery vehicle are revised. (adjust.
 当日配送対象抽出処理S27は、シフト登録処理S11で登録されたシフト表や配送計画データに含まれる供給先施設グループに関する情報、日次配車回転数確定処理S25で修正された情報(配達可能回転数等)等に基づき、配送対象抽出処理S08で抽出された配送対象となる供給先施設グループあるいは、日次配車回転数確定処理S25で再グループ化(抽出)された配送対象となる供給先施設グループから、当日の交換(配送)が必須の供給先施設Uを含む複数の供給先施設Uを、当日の配送対象とするグループ(当日配送供給先施設グループ)として抽出する。当日配送供給先施設グループには例えば、配送の限界日が当日である供給先施設Uと、これらを基準として効率よく配送が可能となる複数の供給先施設U(例えば、直近3日以内に配送の限界日が到来する供給先施設Uなど)が含まれる。なお、当日配送供給先施設グループに属する供給先施設Uの数が少なく、それだけでは配送が非効率になってしまう場合などには、当日の交換(配送)が必須の供給先施設Uでなくても、例えば更に数日先まで(例えば直近7日以内)に配送の限界日が到来する供給先施設U(予備配送先に振り分けられた供給先施設U)については、当日供給先施設グループに含めるなどの条件(状況に応じて変更可能な条件)で抽出を行う。 The same day delivery target extraction process S27 includes information on the supply destination facility group included in the shift table and delivery plan data registered in the shift registration process S11, and information corrected in the daily vehicle delivery speed determination process S25 (delivery speed that can be delivered). Etc.), the supply destination facility group to be delivered extracted in the delivery object extraction processing S08, or the delivery destination facility group to be delivered (re-grouped (extracted) in the daily vehicle rotation speed determination processing S25) From this, a plurality of supply destination facilities U including the supply destination facilities U for which exchange (delivery) on the day is essential are extracted as a group to be delivered on that day (current day delivery supply destination facility group). In the same day delivery supply destination facility group, for example, a supply destination facility U whose delivery limit date is that day, and a plurality of supply destination facilities U (for example, delivery within the last three days) that can be efficiently delivered based on these. Supply destination facilities U, etc. for which the limit date is reached. In addition, when the number of the supply destination facilities U belonging to the same day delivery supply destination facility group is small and the delivery becomes inefficient by itself, it is not the supply destination facility U for which exchange (delivery) on the day is indispensable. In addition, for example, the supply destination facility U (the supply destination facility U distributed to the preliminary delivery destination) whose delivery limit date comes within a few days ahead (for example, within the last seven days) is included in the supply destination facility group on that day. Extraction is performed under conditions such as (conditions that can be changed according to the situation).
 配送車別配送決定処理S29は、当日配送供給先施設グループに含まれる供給先施設Uについて、稼動する配送車(トラック)の積載量ごとにさらにグループ化(振り分け)を行い、配送車毎に供給先施設Uや最適な配送ルート、最適な積載容量などを決定し、配送指示として出力する。 The delivery decision processing S29 for each delivery vehicle further groups (sorts) the delivery destination facilities U included in the delivery delivery destination facility group on the same day according to the loaded amount of delivery vehicles (trucks) in operation, and supplies each delivery vehicle. The destination facility U, the optimum delivery route, the optimum loading capacity, etc. are determined and output as a delivery instruction.
 各配送者は、配送対象となる供給先施設Uへの配送が完了し、その旨を携帯端末12から登録する(後述の配送完了登録処理S17)と、携帯端末12から次回の配送対象となる供給先施設Uに関する情報を取得することができるようになる。各携帯端末12の担当者別配送箇所抽出処理S13では、例えば携帯端末12の表示手段121に例えば配送対象取得ボタンなどが表示される。そして、当該ボタン操作に応じて、当日配送供給先施設グループ(配送車(トラック)の積載量ごとにさらにグループ化されたもの)のうち、さらに配送者ごとに当日配送対象の供給先施設Uが抽出され、当該抽出された当日配送対象の供給先施設Uに関する情報がリストデータとして管理装置13から携帯端末12に送信される。 Each delivery person completes delivery to the supply destination facility U to be delivered, and registers that fact from the mobile terminal 12 (delivery completion registration process S17 described later), and then becomes the next delivery target from the mobile terminal 12. Information about the supply destination facility U can be acquired. In the person-by-person delivery location extraction process S13 of each mobile terminal 12, for example, a delivery target acquisition button or the like is displayed on the display means 121 of the mobile terminal 12, for example. Then, in response to the button operation, among the delivery destination facility groups on the day (further grouped according to the loading capacity of delivery vehicles (trucks)), the delivery destination facility U to be delivered on the day is further set for each delivery person. The extracted information about the supply destination facility U to be delivered that day is transmitted from the management device 13 to the portable terminal 12 as list data.
 また、担当者別配送箇所抽出処理S13の後であっても日次配車回転数確定処理S25は実行可能である。この場合、何らかの事情で配送者が自身が担当する当日配送対象の供給先施設Uに配送に行けず、担当者別配送箇所抽出処理S13の後に残存している当日配送対象の供給先施設Uが残存している場合、これらの残存している供給先施設Uに関する情報を元に、再度グループ化を行うことができる。 In addition, even after the person-in-charge delivery location extraction process S13, the daily vehicle dispatch rotation speed determination process S25 can be executed. In this case, for some reason, the delivery person cannot go to the delivery destination facility U for delivery on the day that he / she is responsible for, but the delivery destination facility U for delivery on the day that remains after the delivery location extraction process S13 for each person in charge If they remain, grouping can be performed again based on the information on the remaining supply destination facilities U.
 ここで、配送情報決定処理S23(日次配車回転数確定処理S25、当日配送対象抽出処理S27、配送車別配送決定処理S29)における最適な配送ルートと最適な積載容量の決定方法について、具体例を挙げて説明する。 Here, a specific example of an optimum delivery route and an optimum loading capacity determination method in the delivery information determination process S23 (daily vehicle delivery rotation speed determination process S25, same day delivery target extraction process S27, delivery vehicle specific delivery determination process S29) Will be described.
 まず、LPガスの供給元の担当者(配送管理者)が、情報修正処理S26において当日の配送可能回転数を入力(指示回転数の修正)する。例えば、5台の配送車で1日に1台につき3回の配送を条件とした場合、15(=5×3)回転が配送可能回転数となる。また必要に応じて配送者のシフト、稼働台数も修正する。 First, the person in charge (delivery manager) of the LP gas supply source inputs the number of revolutions that can be delivered on the day in the information modification process S26 (modification of the designated number of revolutions). For example, assuming that delivery is performed three times per day with five delivery vehicles, 15 (= 5 × 3) rotations are the deliverable rotation speeds. In addition, the shift of deliverers and the number of units in operation will be corrected as necessary.
 配送情報決定処理S23では、配送計画データに基づき、所定の条件を設定して、積載量別に配送車(車種)と配送ルートの組み合わせの抽出を行う。抽出には例えば、ビジネスルールを実行するための所定のエンジンによって、ビジネスルールを管理・実行するビジネスルールマネジメントシステム(Business Rule Management System)を利用する。この場合、ルール(ビジネスルール)として、例えば、同じ配送回に配送するエリア、直近数日(例えば、3日)以内に配送対象となる供給先施設U(配送者のシフトを考慮し、また、休日が続く場合や冬季などで配送が間に合わないような場合には、前倒しにする。)、同じ配送回に配送するエリア内の優先順位(近い順で配送するなど)、配送時間(最大値)、距離/ガスボンベの容量(積載容量)、供給先施設U毎のガスボンベの設置態様(例えば、ガスボンベ20の容量が異なる2本の組合せ、同容量の3本の組合せ、などの設置態様)などを設定する。また、例えば、直近数日(例えば、3日)以内に配送対象となる(配送の限界日が到来する)供給先施設U(最優先配送先)のみだと効率の悪い配送になってしまう場合には、さらに数日増やして(例えば、直近7日以内などとして)配送の限界日が到来する供給先施設U(予備配送先)も配送対象に含めるなどの条件の調整も行い、最適な積載量別の配送車(最適な積載容量)と最適な配送ルートの組み合わせの抽出を行う。 In the delivery information determination process S23, a predetermined condition is set based on the delivery plan data, and a combination of a delivery vehicle (vehicle type) and a delivery route is extracted for each load amount. For example, a business rule management system (Business Rule Management System) that manages and executes business rules by a predetermined engine for executing business rules is used for the extraction. In this case, as a rule (business rule), for example, an area to be delivered in the same delivery time, a supply destination facility U (delivery person shift within the last few days (for example, 3 days) is considered, If the holiday continues or the delivery is not in time due to winter, etc., it will be put forward.), Priority within the area to be delivered to the same delivery times (delivery in close order, etc.), delivery time (maximum value) , Distance / capacity of gas cylinder (loading capacity), installation mode of gas cylinders for each supply facility U (for example, installation modes such as combinations of two gas cylinders 20 having different capacities, combinations of three of the same capacity, etc.) Set. In addition, for example, when only the supply destination facility U (the highest priority delivery destination) that is to be delivered (the delivery limit date arrives) within the last few days (for example, 3 days), the delivery becomes inefficient. In addition, by adjusting the conditions such that the delivery destination facility U (preliminary delivery destination) whose delivery limit date is reached is further increased by several days (for example, within the last 7 days), the optimum loading is performed. The combination of delivery vehicles (optimum loading capacity) by quantity and optimum delivery routes is extracted.
 そして、抽出された組合せの配送について、当初設定した配送可能回転数を下回る場合はその下回った回転数で配送を行い、配送可能回転数を上回った場合は、他の状況も考慮して配送可能回転数を再設定し、再度、最適な積載容量(配送車)と最適な配送ルートの抽出を行う。最適な配送ルートは、複数の位置情報を入力することで各位置情報を経由する最適なルートを導き出すことができる、既存の配送計画システム(最適ルート抽出システム)等を使用して抽出する。 When the extracted combination is less than the initially settable delivery speed, delivery is performed at a lower speed, and when the delivery speed exceeds the delivery speed, delivery is possible taking into account other situations. The rotation speed is reset, and the optimum loading capacity (delivery vehicle) and the optimum delivery route are extracted again. The optimum delivery route is extracted by using an existing delivery plan system (optimum route extraction system) or the like that can derive an optimum route via each piece of location information by inputting a plurality of pieces of location information.
 そして、上記処理にて抽出された最適な積載容量(配送車)と最適な配送ルートを、配送ルート表示処理S31において、各配送者が所持する携帯端末12および/または、配送管理者の所持する携帯端末12に送信し、携帯端末12の表示手段121に表示させる。 Then, in the delivery route display process S31, the optimum loading capacity (delivery vehicle) and the optimum delivery route extracted in the above process are possessed by the portable terminal 12 and / or the delivery manager possessed by each deliverer. The data is transmitted to the mobile terminal 12 and displayed on the display unit 121 of the mobile terminal 12.
 なお、ガスボンベ20を配送・交換した際に発行する伝票の置き場所は、LPガス契約者(供給先施設U)ごとに異なる場合がある。従って、管理装置13は、当該情報を含むLPガス契約者(供給先施設U)ごとに特有の情報も保持し、配送者の携帯端末12に配送対象の供給先施設Uに関する情報を表示する際、これらのLPガス契約者(供給先施設U)ごとに特有の情報も表示する。 In addition, the place of the slip issued when the gas cylinder 20 is delivered / exchanged may be different for each LP gas contractor (supplier facility U). Accordingly, the management device 13 also holds information specific to each LP gas contractor (supply destination facility U) including the information, and displays information related to the delivery destination facility U to be delivered on the portable terminal 12 of the delivery person. Information specific to each LP gas contractor (supplier facility U) is also displayed.
 また、携帯端末12における最適な配送ルートの表示は、既知のナビゲーションシステムと連係させる。ナビゲーションシステムは、ある供給先施設Uへの配送が完了すると、最適な配送ルートに従って次の供給先施設Uへのナビゲーションを順次行う。 Also, the display of the optimum delivery route on the mobile terminal 12 is linked with a known navigation system. When the delivery to a certain supply destination facility U is completed, the navigation system sequentially performs navigation to the next supply destination facility U according to the optimum delivery route.
 配送者は、供給先施設Uに赴き、指示されたガスボンベ20の交換作業を行う。その際、携帯端末12の表示手段121に表示されている内容と、交換場所の供給先施設U(LPガス契約者)の情報との合致を確認し、回収するガスボンベ20と配置するガスボンベ20の全てについて固有のバーコードの読み取りを行い、ガスメータ21の指針値を目視で取得し、携帯端末12に入力する。また、新たにLPガス契約者(供給先施設U)ごとに特有の情報の追加・変更がある場合は、当該追加・変更の情報を入力する。携帯端末12の配送完了登録処理S17では、指針値や、回収されたガスボンベ20に固有の情報、LPガス契約者(供給先施設U)ごとに特有の情報の入力を配送データとして受付け、管理装置13に送信する。また、配送が完了した供給先施設Uに関する情報は、携帯端末12から消去される。配送者は、当日の全ての供給先施設Uについて、上記作業を繰り返して行う。 The delivery person goes to the supply facility U and performs the replacement work of the gas cylinder 20 instructed. At that time, it is confirmed that the content displayed on the display means 121 of the portable terminal 12 matches the information of the supply destination facility U (LP gas contractor) at the exchange place, and the gas cylinder 20 to be collected and the gas cylinder 20 to be arranged are arranged. All the unique barcodes are read, the pointer value of the gas meter 21 is obtained visually, and input to the mobile terminal 12. In addition, when there is a new addition / change of specific information for each LP gas contractor (supplier facility U), information on the addition / change is input. In the delivery completion registration process S17 of the portable terminal 12, the input of the guideline value, the information specific to the collected gas cylinder 20 and the information specific to each LP gas contractor (supplier facility U) is received as delivery data, and the management device 13 to send. Further, the information regarding the supply destination facility U for which the delivery has been completed is deleted from the portable terminal 12. The delivery person repeats the above operation for all supply destination facilities U on that day.
 管理装置13の配送情報登録処理S09では、各携帯端末12から送信される配送データを取得し、供給先施設U(LPガス契約者)毎に、管理装置13において保有している情報の更新を行う。 In the delivery information registration process S09 of the management device 13, the delivery data transmitted from each portable terminal 12 is acquired, and the information held in the management device 13 is updated for each supply destination facility U (LP gas contractor). Do.
 また、管理装置13では、例えば、空調の使用状況、バルク貯槽供給であるか否か、供給先施設Uが集合住宅であるか否か、給湯器の使用の有無等に応じて、適宜調整を行う。 Moreover, in the management apparatus 13, it adjusts suitably according to the use condition of air conditioning, whether it is bulk storage tank supply, whether the supply destination facility U is a housing complex, whether or not a water heater is used, etc. Do.
 例えば、空調の使用状況としては、夏季の冷房器具、冬季の暖房器具を使用することで急激に使用量が上がる傾向があるLPガス契約者(供給先施設U)を抽出可能とし、意図したタイミングで配送伝票を発行できるようにする。 For example, regarding the usage status of air conditioning, it is possible to extract LP gas contractors (supplier facilities U) whose usage tends to increase rapidly by using summer cooling equipment and winter heating equipment. To be able to issue a delivery slip.
 また、供給先施設Uが中圧供給の場合は、メータの指針と実際の使用量が異なるため、換算率を設定して実際の使用量を計算する。 Also, when the supply destination facility U is medium pressure supply, the actual usage is different from the meter guideline, so the actual usage is calculated by setting the conversion rate.
 また、バルク貯槽供給の場合、通常の配送車(トラック)で配送できないため、予測計算処理S05は行うが、配送のはバルク車での配送を指示する。 Also, in the case of bulk storage tank supply, since it cannot be delivered by a normal delivery vehicle (truck), the prediction calculation process S05 is performed, but the delivery is instructed to be delivered by a bulk vehicle.
 また、集合住宅の場合、ガスメータ情報として、全ての部屋で使用した指針値の合計を取得できる場合と、各部屋毎にガスメータが設けられるのみで、各部屋ごとにしか指針値が取得できない場合がある。後者の場合は、紐づく部屋のガスメータの指針値を合算した上で、予測計算処理S05を実行する。 In addition, in the case of apartments, there are cases where the total of the guideline values used in all rooms can be acquired as gas meter information, and there are cases where only a gas meter is provided for each room and the guideline values can be acquired only for each room. is there. In the latter case, the calculation value S05 is executed after adding the pointer values of the gas meters in the associated rooms.
 また、給湯器が設置されているLPガス契約者(供給先施設U)は抽出可能とし、冬季に使用量が増加した場合の管理を行なう。 In addition, LP gas contractors (supplier facilities U) where hot water heaters are installed can be extracted, and management is performed when the usage increases in winter.
 上記した以外にも、配送管理手段50は、例えば、ガス供給(配送)管理の月次処理、配送実績の管理処理、帳票発行処理、保安点検情報管理処理など、従来既知のガス供給(配送)管理における各種処理を実行する。 In addition to the above, the delivery management means 50 may be a conventionally known gas supply (delivery) such as a monthly process for gas supply (delivery) management, a management process for delivery results, a form issuing process, a security check information management process, etc. Various management processes are executed.
 <日別予測使用量の算出方法>
 配送予測処理S03(予測使用量算出処理S04(予測計算処理S05)および限界日算出処理S06)では、指示回転数や、ガスメータ情報に含まれるガス使用量(指針値)などに基づき、日別予測使用量、配送の限界日、配送計画データを抽出可能である。指針値は、管理装置13が自動で格納装置30から取得したデータに限らず、検針者や配送者が実際に供給先施設U、またその付近に赴いて取得した指針値も含まれる。
<Daily forecast usage calculation method>
In the delivery prediction processing S03 (predicted usage calculation processing S04 (prediction calculation processing S05) and limit date calculation processing S06), daily prediction is performed based on the indicated rotational speed, the gas usage (guideline value) included in the gas meter information, and the like. The usage amount, delivery limit date, and delivery plan data can be extracted. The guideline value is not limited to the data automatically acquired from the storage device 30 by the management device 13, but also includes the guideline value actually acquired by the meter reader or the delivery person in the vicinity of the supply destination facility U or in the vicinity thereof.
 具体的には、配送予測手段138(配送予測処理S03)は、将来の日付けにおける日別予測使用量を算出する。このとき、配送予測手段138は、日数の経過に伴って増加又は減少するように日別予測使用量を算出する。例えば冬期では月初から月末に向かって日ごとに増加するように日別予測使用量を算出し、夏期では月初から月末に向かって日ごとに減少するように日別予測使用量を算出する。このため、配送予測手段138は、過去の所定期間における基準ガス使用量に基づいて日毎に単位予測使用変化量(1日当りの増加量または減少量)を算出し、当該単位予測使用変化量に基づいて日別予測使用量を算出する。この場合の基準ガス使用量は、例えば、予測する期間と同時期の過去の所定期間における使用実績量または、予測する期間と同時期の例年のガス使用量の傾向に基づく設定値である、基準ガス使用量は、LPガス契約者の使用傾向に基づき、個別に設定される。 Specifically, the delivery prediction means 138 (delivery prediction processing S03) calculates a daily forecast usage amount in a future date. At this time, the delivery prediction means 138 calculates the daily predicted usage amount so as to increase or decrease with the passage of days. For example, in winter, the daily forecast usage is calculated so as to increase every day from the beginning of the month to the end of the month, and in summer, the daily forecast usage is calculated so as to decrease from the beginning of the month to the end of the month. Therefore, the delivery prediction means 138 calculates a unit predicted usage change amount (increase or decrease amount per day) for each day based on the reference gas usage amount in the past predetermined period, and based on the unit predicted usage change amount. To calculate the daily forecast usage. The reference gas usage amount in this case is, for example, a reference value that is a set value based on the actual usage amount in a predetermined period in the past at the same time period as the prediction period or the trend of the gas usage in the annual period at the same time period as the prediction period. The amount of gas used is individually set based on the usage trend of LP gas contractors.
 そして、配送予測手段138(配送予測処理S03)は、算出した日別予測使用量に基づいてガスボンベ20内の将来の日付けにおける日別のガス残量(ガス残量予測値)を算出し、ガス残量予測値が所定量に減量する日付けを予測して配送の予定日を決定する。 And the delivery prediction means 138 (delivery prediction process S03) calculates the daily gas residual amount (gas residual amount predicted value) in the future date in the gas cylinder 20 based on the calculated daily predicted usage amount, The estimated date of delivery is determined by predicting the date when the gas remaining amount prediction value is reduced to a predetermined amount.
 <予測計算処理の具体例>
 以下、図14を参照して、予測計算処理S05の一例について更に説明する。図14は、予測計算処理で用いる計算式の一例を示す表である。
<Specific example of prediction calculation processing>
Hereinafter, an example of the prediction calculation process S05 will be further described with reference to FIG. FIG. 14 is a table showing an example of a calculation formula used in the prediction calculation process.
 予測計算処理S05は、例えば、前回取得したガスメータ情報のガス使用量(前回指針値)と、今回取得したガスメータ情報のガス使用量(今回指針値)とに差異が発生し、且つ、今回指針値に基づく実際のガス残量が予測開始閾値を下回ったガスボンベ20(供給先施設U)に対して、行う。
(1)基準ガス使用量として、前年同時期のガス使用量(実績量)を用いる場合
(1-1)日次情報取得対象者以外のLPガスの契約者であるか、日次情報取得対象者であって、過去のガスメータ情報(指針値)の蓄積年月が1年2ヶ月未満の場合
In the prediction calculation process S05, for example, a difference occurs between the gas usage amount (previous guide value) of the gas meter information acquired last time and the gas usage amount (current guide value) of the gas meter information acquired this time, and the current guide value This is performed for the gas cylinder 20 (supply destination facility U) in which the actual gas remaining amount based on is less than the prediction start threshold.
(1) When using the gas consumption (actual amount) in the same period of the previous year as the reference gas usage (1-1) Whether you are a LP gas contractor other than the daily information acquisition target or the daily information acquisition target If the accumulated date of past gas meter information (guideline value) is less than 1 year and 2 months
 ガスメータ情報を取得した日(M月D日)の数日後の当月予測日(M月X日)の日別予測使用量は、例えば、以下の方法にて算出する。 The daily predicted usage amount of the current month forecast date (M month X day) several days after the date (M month D day) when the gas meter information is acquired is calculated by the following method, for example.
 まず、前年同時期の1ヶ月の使用量(実績量)の差(変化量)から、1日当りの単位予測使用変化量(前日からの増加量または減少量)を算出し、予測日が含まれる月の月初からの日数を積算して予測日の(予測日における)予測使用変化量(式1)を算出する。 First, the unit predicted usage change amount (increase or decrease amount from the previous day) per day is calculated from the difference (change amount) in the monthly usage amount (actual amount) in the same period of the previous year, and the prediction date is included The number of days from the beginning of the month is integrated to calculate the predicted usage change amount (Equation 1) on the predicted date.
   予測日の予測使用変化量=(前年今月(当月)使用量と前年前月使用量の差)/(当月の1日から末日までの日数の和)×月初から予測日までの日数X   (式1) Predicted usage change amount on the forecast day = (difference between the previous month's (current month) usage and the previous month's usage) / (sum of days from the first day of the current month to the last day) x number of days from the beginning of the month to the forecast date X (Equation 1 )
 次に、前年当月のベース使用量から、前年当月の1日当りの平均使用量を算出する。前年当月のベース使用量とは、前年前月における総使用量である。前年当月の1日当りの平均使用量(これを「ベース使用予測量(平均)」という。)に、(式1)で求めた予測日の予測使用変化量を合算して前年前月を基準とした当月予測日の使用予測量(式2)を算出する。 Next, the average daily usage for the previous month is calculated from the base usage for the previous month. The base usage for the previous month is the total usage for the previous month. The average usage per day for the current month of the previous year (this is called “base usage forecast (average)”) is added to the forecasted usage change calculated in (Equation 1), based on the previous month. Calculate the usage forecast amount (formula 2) for the current month forecast day.
   当月予測日の使用予測量=前年前月使用量(1ヶ月分)/今月の月日数+予測日の予測使用変化量   (式2) Predicted usage of the current month forecast date = previous month's previous month usage (1 month) / number of months in the current month + predicted usage change of the predicted date (Formula 2)
 更に、前年前月使用量と今年前月使用量の変化量(増加量または減少量)を今月の月日数で除算して前年前月使用量と今年前月使用量の変化量の今月1日当りの平均値(式3)を算出する。 Furthermore, by dividing the previous month's previous month's usage and this year's previous month's change (increase or decrease) by the number of months in this month, the average value of the previous year's previous month's usage and this year's previous month's usage per day this month ( Equation 3) is calculated.
   前年前月使用量と今年前月使用量の変化量の今月1日当りの平均値(前年→今年変化量(平均))=(前年前月使用量と今年前月使用量の変化量)/今月の月日数   (式3) Average value of the amount of change in the previous month's previous year's usage and this year's previous month's usage per day this month (previous year → this year's change (average)) = (previous year's previous month's usage and this year's previous month's change) / number of months in this month ( Formula 3)
 そして、(式2)で算出された当月予測日の使用予測量と(式3)で算出された前年前月使用量と今年前月使用量の変化量の今月1日当りの平均値(前年→今年変化量(平均)を合算して、当月予測日の日別予測使用量(式4)を算出する。 The average value of the current day's forecasted amount calculated by (Equation 2) and the previous month's previous month's usage calculated by (Equation 3) and the amount of change in this month's previous month's usage per day this month (previous year → this year's change) The amount (average) is added together to calculate the daily forecasted usage amount (Formula 4) of the current month forecast day.
   当月予測日の日別予測使用量=当月予測日の使用予測量+前年前月使用量と今年前月使用量の変化量の今月1日当りの平均値   (式4)
(1-2)日次情報取得対象者であって、過去のガスメータ情報(指針値)の蓄積年月が1年2ヶ月以上の場合
Daily forecasted usage of the current month's forecast date = Forecasted usage of the current month's forecast date + Average value of the change in the previous month's usage and previous year's usage for the current month (Formula 4)
(1-2) If you are a person who acquires daily information and the accumulated date of past gas meter information (guideline value) is more than 1 year and 2 months
 この場合、日次で(自動的に)管理装置13はガスメータ情報を取得するため、ガスメータ情報を取得した当日を起点として日次で予測計算処理S05が行なわれる。 In this case, since the management device 13 acquires the gas meter information on a daily basis (automatically), the prediction calculation processing S05 is performed on a daily basis from the day when the gas meter information is acquired.
 ガスメータ情報を取得した日(Y年M月D日)のX日後の日別予測使用量は、以下の方法にて算出する。 The daily estimated usage after X days of the date when the gas meter information was acquired (M month D, Y year) is calculated by the following method.
 まず、この場合、Y年M月D日から起算して30日前~60日前までの使用量の和を今年前回使用量、Y年M月D日の前年同月日30日前~60日前までの使用量の和を前年前回使用量、Y年M月D日の前年同月日~30日前までの使用量の和を前年今回使用量とする。そして、今年前回使用量を今年前月使用量、前年前回使用量を前年前月使用量、前年今回使用量を前年当月(今月)使用量と読み替えて、上記の(式1)から(式4)を用いて算出する。 First, in this case, the sum of the usage from 30 days to 60 days before, starting from M / D on year Y, is the previous usage of this year, and the usage from 30 to 60 days before the same month the same day of M / D in Y year The sum of the amount is the previous year's use amount, and the sum of the use amount from the same month the previous year of M / D in Y to 30 days ago is the previous year's use amount. Then, the previous year's usage this year is read as the previous month's usage, the previous year's previous usage is read as the previous year's usage, the previous year's current usage is read as the previous year's (this month) usage, and the above (Formula 1) to (Formula 4) Use to calculate.
   予測日の予測使用変化量=(前年今回使用量と前年前回使用量の差)/(当月の1日から末日までの日数の和)×ガスメータ情報の取得日から予測日までの日数X   (式1) Predicted change in usage on the predicted date = (Difference between current usage in the previous year and previous usage in the previous year) / (sum of days from the first day of the current month to the last day) x number of days from the acquisition date of the gas meter to the prediction date X (formula 1)
   当月予測日の使用予測量=前年前回使用量/30日間+予測日の予測使用変化量   (式2) Predicted usage amount for the current month forecast date = previous usage amount for the previous year / 30 days + predicted usage change amount for the predicted date (Formula 2)
   前年前回使用量と今年前回使用量の変化量の1日当りの平均値(前年→今年変化量(平均))=(前年前回使用量と今年前回使用量の変化量)/30日間   (式3) Average value of the amount of change between the previous year's previous usage and this year's previous usage (the previous year → this year's change (average)) = (previous year's previous usage and this year's previous usage) / 30 days (Formula 3)
   当月予測日の日別予測使用量=当月予測日の使用予測量+前年前回使用量と今年前回使用量の変化量の1日当りの平均値   (式4)
(2)基準ガス使用量として、月ごとに予め登録された例年のガス使用量の傾向を示す係数(使用量または基準月からの使用量変化割合)を用いる場合
Daily forecasted usage of the current month forecasted date = Forecasted usage of the current month forecasted date + Average value per day of the previous year's usage and the previous year's usage change (Equation 4)
(2) When using a coefficient (usage or rate of change from the reference month) indicating the tendency of gas usage in each year registered in advance as the reference gas usage per month
 ガスメータ情報を取得した日(M月D日)の数日後の当月予測日(M月X日)の日別予測使用量は、以下の方法にて算出する。 The daily estimated usage of the current month forecast date (M month X day) several days after the date (M month D day) when the gas meter information was acquired is calculated by the following method.
 この場合、前年前回使用量を前年前月係数、前年今回使用量を前年今月(当月)係数と読み替えて、上記の(式1)から(式4)を用いて算出する。 In this case, replace the previous year's previous usage with the previous month's coefficient and the previous year's current usage with the previous month's (current month) coefficient, and calculate using the above (Equation 1) to (Equation 4).
   予測日の予測使用変化量=(前年今月係数と前年前月係数の差)/(当月の1日から末日までの日数の和)×月初から予測日までの日数X   (式1) Forecast amount of change in forecast date = (Difference between previous month's current month coefficient and previous year's previous month coefficient) / (sum of days from the first day of the current month to the last day) x number of days from the beginning of the month to the forecast date X (Formula 1)
   当月予測日の使用予測量=前年前月係数/今月の月日数+予測日の予測使用変化量   (式2) Predicted amount of use on the predicted date of the current month = previous month's previous month coefficient / number of days in the current month + predicted use change amount on the predicted date
   前年前月係数と今年前月使用量の変化量の1日当りの平均値(前年→今年変化量(平均))=(前年前月係数と今年前回使用量の変化量)/30日間   (式3) Average value per day of change in the previous month's previous month coefficient and this month's previous month's usage (previous year → this year's change (average)) = (previous year's previous month's coefficient and previous year's change in usage) / 30 days (Formula 3)
   当月予測日の日別予測使用量=当月予測日の使用予測量+前年前月係数と今年前月使用量の変化量の1日当りの平均値   (式4) Daily forecasted usage for the current month forecast date = predicted usage for the current month forecast date + previous year's previous month coefficient and average amount of change in usage for the previous month this year (Equation 4)
 予測計算処理S05では、上記(1)を上記(2)よりも優先して行うが、前年前月使用量(前年前回使用量、前年前月係数)および前年今月使用量(前年今回使用量、前年今月係数)が存在しない場合、上記(2)を用いる。 In the prediction calculation process S05, the above (1) is given priority over the above (2), but the previous month's previous month's usage (previous year's previous usage, previous year's previous month coefficient) and previous year's this month usage (previous year's current usage, previous year's current month). When there is no coefficient, the above (2) is used.
 <限界日算出処理> <Limit date calculation processing>
 次に、限界日算出処理S06について、説明する。 Next, the limit date calculation process S06 will be described.
 限界日算出処理S06では、上記の予測計算処理S05によって,直近でガスメータ情報を取得した日以降の日別予測使用量に基づき、直近でガスメータ情報を取得した日以降の合計予測使用量を算出する。 In the limit date calculation process S06, the above-mentioned prediction calculation process S05 calculates the total predicted usage after the date when the gas meter information was most recently acquired based on the daily predicted usage after the date when the gas meter information was acquired most recently. .
 また、ガスメータ情報の指針値に基づき、ガスメータ情報取得時の実際のガスの残量(ガス残量)を算出する。ガス残量は、配送(交換)時のガス容量から配送(交換)時以降の毎月のガス使用量の合計値を減算した値である。そして、実際のガス残量から日毎に合計予測使用量を減算し、直近でガスメータ情報を取得した日以降の各日のガス残量予測値を算出する。 Also, based on the guide value of the gas meter information, the actual remaining gas amount (gas remaining amount) at the time of obtaining the gas meter information is calculated. The remaining amount of gas is a value obtained by subtracting the total amount of gas used every month after delivery (exchange) from the gas capacity at delivery (exchange). Then, the total predicted usage amount is subtracted from the actual gas remaining amount for each day, and the gas remaining amount predicted value for each day after the date when the gas meter information was most recently acquired is calculated.
 そして、ガス残量予測値が、配送限界閾値(限界率)を下回る直近の日付を特定し、その日よりも限界日数(例えば3日)前の日付を配送の限界日として決定する。 Then, the most recent date when the gas remaining amount prediction value falls below the delivery limit threshold (limit rate) is specified, and the date before the limit number of days (for example, 3 days) is determined as the delivery limit date.
 配送限界閾値および限界日数は、LPガス契約者(供給先施設U)毎の使用状況により個別に予め設定してある値である。
(具体例)
The delivery limit threshold and the limit number of days are values that are individually set in advance depending on the usage status of each LP gas contractor (supplier facility U).
(Concrete example)
 図15および図16を参照して、例えば、2017年11月15日に(ガスメータ情報を取得し)、予測計算処理S05を実行する場合を例により具体的に説明する。以下では、上記(1-1)の日次情報取得対象者以外のLPガスの契約者であるか、日次情報取得対象者であって、過去のガスメータ情報(指針値)の蓄積年月が1年2ヶ月未満の場合について説明するが、上記(1-2)日次情報取得対象者であって、過去のガスメータ情報(指針値)の蓄積年月が1年2ヶ月以上の場合や、上記(2)基準ガス使用量として、月ごとに予め登録された例年のガス使用量の傾向を示す係数(使用量または基準月からの使用量変化割合)を用いる場合、であっても同様である。 Referring to FIG. 15 and FIG. 16, for example, a case where the prediction calculation process S05 is executed on November 15, 2017 (acquisition of gas meter information) will be specifically described. In the following, it is an LP gas contractor other than the above-mentioned daily information acquisition target in (1-1), or the daily information acquisition target, and the accumulated date of the past gas meter information (guideline value) is The case of less than 1 year and 2 months will be explained. However, in the case of (1-2) daily information acquisition target and the accumulated date of past gas meter information (guideline value) is more than 1 year and 2 months, Even if the coefficient (usage or change rate of usage from the reference month) indicating the tendency of gas usage in each year registered in advance as the above (2) is used as the reference gas usage, the same applies. is there.
 図15(a)は、前年(2016年)の9月~11月の実際の使用量(実績値)の一例である。各月のベース使用量は、それらの前月の総使用量である。同図(b)は、(式1)で算出される予測日の予測使用変化量、および日別予測使用量の概念図である。同図(c)は、予測計算処理S05によって算出した、2017年11月の日別予測使用量テーブルである。図16(a)は、日別予測使用量を概念的に示すグラフである。図16(b)は、図15(c)に基づく、限界日算出テーブルである。 FIG. 15 (a) is an example of actual usage (actual values) from September to November of the previous year (2016). The base usage for each month is the total usage for the previous month. FIG. 5B is a conceptual diagram of the predicted usage change amount and the daily predicted usage amount calculated by (Equation 1). FIG. 11C is a daily forecast usage table for November 2017 calculated by the forecast calculation process S05. FIG. 16A is a graph conceptually showing the daily predicted usage. FIG. 16B is a limit date calculation table based on FIG.
 図15(a)に示すように、前年前月使用量(2016年10月)は20立方m、前年今月使用量(2016年11月)は29立方mである。また、今年前月使用量(2017年10月)は、25立方mであるとする。当月(2017年11月)の1日から末日(30日)までの日数の和は、465日であり、予測日の月初からの日数)Xは、15日である。 As shown in FIG. 15 (a), the previous month's usage (October 2016) is 20 cubic meters, and the previous month's usage (November 2016) is 29 cubic meters. The previous month's usage (October 2017) is assumed to be 25 cubic meters. The sum of the days from the first day of the current month (November 2017) to the last day (30th) is 465 days, and the number of days from the beginning of the predicted day) X is 15 days.
 この場合、予測日の予測使用変化量は、(式1)により0.29立方m(=(29立方m-20立方m)/465日×15日)である。 In this case, the predicted usage change amount on the prediction day is 0.29 cubic m (= (29 cubic m−20 cubic m) / 465 days × 15 days) according to (Equation 1).
 ここで、(式1)においては、同図(b)にドットのハッチングで示す前年今月使用量と前年前月使用量の差(変化量)を、当月の1日から末日までの日数の和で除している。これにより、同図(b)に斜線のハッチングで示すように、当月の1日あたりの単位予測使用変化量が算出される。この単位予測使用変化量を、月初からの日数分(例えば15日分)合算することで、予測日(11月15日)の予測使用変化量が求められる。 Here, in (Equation 1), the difference (change) between the previous month's usage this month and the previous month's usage shown in dot hatching in the same figure (b) is the sum of the days from the first day to the last day of the current month. Is excluded. As a result, the unit predicted usage change amount per day of the current month is calculated as indicated by hatched hatching in FIG. By adding the unit predicted use change amount for the number of days from the beginning of the month (for example, 15 days), the predicted use change amount on the prediction date (November 15) is obtained.
 そして同図(c)の11月15日欄に示すように、この場合の当月予測日の使用予測量は、(式2)より、0.96立方m(=20立方m/30日+0.29立方m)であり、前年前月使用量と今年前月使用量の変化量の今月1日当りの平均値(前年→今年変化量(平均))は、(式3)より、0.17立方m(=(25立方m-20立方m)/30日)である。この結果、当月予測日(2017年11月15日)の日別予測使用量は、(式4)より、1.13立方m(=0.96立方m+0.17立方m)となる。 As shown in the November 15 column of FIG. 10C, the predicted usage amount of the current month is 0.96 cubic m (= 20 cubic m / 30 days + 0. 29 cubic meters), and the average value of the amount of change in the previous month's previous month's usage and this year's previous month's usage per day this month (previous year → this year's variation (average)) is 0.17 cubic m (from Equation 3) = (25 cubic m-20 cubic m) / 30 days). As a result, the predicted daily usage amount on the predicted date of the current month (November 15, 2017) is 1.13 cubic m (= 0.96 cubic m + 0.17 cubic m) from (Equation 4).
 上記(式1)~(式4)の計算を2017年11月1日~11月30日についてそれぞれ行う。これにより、同図(c)に示す2017年11月の日別予測使用量テーブルが得られる。 The calculations of (Equation 1) to (Equation 4) are performed for November 1 to November 30, 2017, respectively. As a result, the daily forecast usage table for November 2017 shown in FIG.
 なお、上記(1-1)および上記(2)の場合は、同図(c)に示す日別予測使用量テーブルを月毎に1回作成する(例えば、月末に次月分の日別予測使用量テーブルを作成する)。また、上記(1-2)の場合は、日次で(毎日)1ヶ月分の日別予測使用量テーブルを作成(更新)する。 In the case of (1-1) and (2) above, the daily forecast usage table shown in (c) of the figure is created once a month (for example, the daily forecast for the next month at the end of the month). Create a usage table). In the case of (1-2), a daily predicted usage table for one month is created (updated) on a daily basis (daily).
 図16(a)を参照して、本実施形態によれば、(式2)で算出される当月予測日の使用予測量(前年前月の総使用量を当月の日数で平均した量)に、日ごとに増加または減少するように算出された予測日の予測使用変化量(式1)と、前年前月使用量と今年前月使用量の変化量の今月1日当りの平均値(式3)を加算して、日別予測使用量を算出する。 With reference to FIG. 16 (a), according to the present embodiment, the predicted usage amount of the current month calculated by (Equation 2) (the total usage amount of the previous month of the previous year is averaged by the number of days in the current month), Predicted usage change amount (Equation 1) calculated to increase or decrease every day, plus the average value per day of this month (Equation 3) of the previous month's previous month's usage and this month's previous month's usage Then, the daily forecast usage is calculated.
 一方、同図(a)の破線は比較例であって、過去の1ヶ月の使用量(実績量)を月日数で除算して変化量の平均値を求め、変化量の平均値を基準となる当月(予測日)のベース使用量に加算する予測方法の結果である。 On the other hand, the broken line in FIG. 9A is a comparative example, and the average amount of change is obtained by dividing the past month's usage (actual amount) by the number of months, and the average value of the change is used as a reference. It is the result of the prediction method added to the base usage amount of the current month (forecast date).
 ガスの使用量は、実際には季節の変化に応じて、日ごとに増加あるいは減少するものである。つまり、同図(a)の破線で示すように変化量が平均されてしまうと、例えば配送の予定日が月末に算出されてしまうほど、ガスボンベ20の交換前にガスが欠乏してしまう可能性が高くなる。 The amount of gas used actually increases or decreases from day to day according to seasonal changes. That is, if the amount of change is averaged as shown by the broken line in FIG. 9A, for example, the estimated date of delivery is calculated at the end of the month, and the gas may be deficient before the gas cylinder 20 is replaced. Becomes higher.
 本実施形態によれば、予測使用変化量が日ごとに増加又は減少(同図(a)では増加)するように算出しているため、例えば配送の予定日が月末に算出されてしまう場合であっても実情に沿いやすくなり、ガスボンベ20の交換前にガスが欠乏するリスクを回避できる。 According to the present embodiment, since the predicted usage change amount is calculated so as to increase or decrease from day to day (in the figure (a), increase), for example, when the scheduled delivery date is calculated at the end of the month. Even if it exists, it becomes easy to follow the actual situation, and it is possible to avoid the risk of gas shortage before replacing the gas cylinder 20.
 また、予測使用変化量に加えて、前年前回使用量と今年前回使用量の変化量の1日当りの平均変化量(前年→今年変化量(平均))も加算するため、より実情に合わせた使用量予測が可能となる。 Also, in addition to the predicted usage change amount, the average change amount per day (previous year → change this year (average)) of the previous year's previous year's usage amount and this year's previous usage change amount is also added. Quantity prediction is possible.
 そして、図16(b)に示すように、限界日算出処理S06では、予測使用変化量に基づいて限界日算出テーブルを作成する。 Then, as shown in FIG. 16B, in the limit date calculation process S06, a limit date calculation table is created based on the predicted usage change amount.
 この例では、2017年11月15日に取得したガスメータ情報に基づき、当日以降(2017年11月16日~同年11月30日)までの値を求めている。2017年11月15日に取得したガスメータ情報(実績値)の内容は、ガス残量が15立方m、供給先施設Uのガスボンベ20の容量は、合計で100立方m(50kg×2本)とし、配送限界閾値は5%、限界日数は、3日に設定されているとする。 In this example, based on the gas meter information acquired on November 15, 2017, the values after that day (November 16, 2017 to November 30, 2017) are obtained. The contents of the gas meter information (actual value) acquired on November 15, 2017 are as follows: the remaining amount of gas is 15 cubic meters, and the capacity of the gas cylinder 20 of the supply destination facility U is 100 cubic meters (50 kg × 2) in total. It is assumed that the delivery limit threshold is set to 5% and the limit days are set to 3 days.
 同図に示すように、11月16日以降の日別予測使用量に基づき、11月16日以降の合計予測使用量(16日は1.14立方m、17日は2.31(≒1,14+1.16)立方m・・・)を算出し、実際のガス残量(15立方m)から日毎に合計使用量を減算して(16日は13.86(=15-1.14)立方m、17日は12.69(=15-2.31)立方m・・・)、11月16日以降の各日におけるガス残量予測値、およびその供給先施設Uにおけるガスボンベ20の総容量に対するガス残量予測値の割合を算出する。 As shown in the figure, based on the daily predicted usage after November 16, the total predicted usage after November 16 (1.14 cubic m on 16th, 2.31 on 17th (≈1). , 14 + 1.16) cubic m ...), and subtract the total amount used every day from the actual gas remaining amount (15 cubic m) (13.86 on the 16th (= 15-1.14)) Cubic m, 17th is 12.69 (= 15-2.31) cubic m ...), the estimated remaining gas amount for each day after November 16, and the total number of gas cylinders 20 at the supply facility U The ratio of the estimated remaining gas amount to the capacity is calculated.
 そして、その供給先施設Uにおけるガスボンベ20の総容量に対するガス残量予測値の割合が、配送限界閾値(限界率)を下回る直近の日付(この例では11月24日)を特定し、その日よりも限界日数(3日)前の日付(この例では11月21日)を配送の限界日として決定する。 Then, the most recent date (November 24 in this example) where the ratio of the gas remaining amount prediction value to the total capacity of the gas cylinder 20 in the supply destination facility U falls below the delivery limit threshold (limit rate) is specified, and from that date Also, the date (November 21 in this example) before the limit number of days (3 days) is determined as the limit date of delivery.
 以上、配送予測処理について、具体例を挙げて説明したが、本実施形態の配送予測処理は、上記の例に限らない。すなわち、週に1回よりも多頻度(例えば日次)でガスメータ情報を取得し、日ごとに増加または減少するように日別予測使用量を算出し、LPガス契約者にガスの欠乏などのリスクが生じない範囲で可能な限りガス残量予測値が少なくなる配送の限界日を算出するとともに、配送の担当者(配送者)および配送車毎に最適な配送ルートを予測するものであればよい。 The delivery prediction process has been described with a specific example, but the delivery prediction process of the present embodiment is not limited to the above example. That is, gas meter information is acquired more frequently than once a week (for example, daily), daily forecast usage is calculated so that it increases or decreases every day, and LP gas contractors are informed of gas shortages, etc. If it is possible to calculate the delivery limit date when the estimated amount of gas remaining is as low as possible without causing a risk, and predict the optimal delivery route for each person in charge of delivery (delivery person) and delivery vehicle Good.
 以上説明したように、本実施形態のLPWAを利用したガス供給管理システム10では、管理装置13(配送管理手段50)がガスメータ情報を遠隔で、任意のタイミングで自動取得することができる。これにより、管理装置13(配送管理手段50)はガスメータ情報を日次で(随時)把握することができ、これをLPガスの配送業務の効率化に活用することができる。具体的には、ガスボンベ20を配送する上で最適な配送日と効率的な配送ルートを予測し、複数の配送車に積載するガスボンベ20の本数を指示するまでのプロセスを自動的に行う。これにより、従来では検針員の検針作業や、ガスボンベの配送員に依存する要素の強かったLPガスの配送業務において、属人化したノウハウの継承を必要とせず、常に効率の良いLPガス配送業務が可能となる。 As described above, in the gas supply management system 10 using the LPWA of this embodiment, the management device 13 (delivery management means 50) can automatically acquire gas meter information remotely at an arbitrary timing. Thereby, the management apparatus 13 (delivery management means 50) can grasp | ascertain gas meter information on a daily basis (at any time), and can utilize this for efficiency improvement of LP gas delivery work. Specifically, an optimal delivery date and an efficient delivery route for delivering the gas cylinder 20 are predicted, and a process until the number of gas cylinders 20 loaded on a plurality of delivery vehicles is instructed automatically is performed. As a result, in the past, the meter reading work of meter readers and the delivery of LP gas, which had strong elements depending on the delivery of gas cylinders, did not require the transfer of know-how that belonged to the individual, and always efficient LP gas delivery work. Is possible.
 また、LPWAを用いることにより、安価かつ低消費電力で、広いエリアのユーザ(ガスボンベ20の供給先施設U)をカバーすることができる。 Further, by using LPWA, it is possible to cover a wide area user (a supply destination facility U of the gas cylinder 20) with low cost and low power consumption.
 なお、ガスメータ情報は、管理装置13(配送管理手段50)による自動取得に加えて、第1実施形態と同様に携帯端末12によって収集するようにしてもよい。例えば、携帯端末12は、情報送信装置11から送信されたガスメータ情報を受信・収集し、ネットワークNW1(またはネットワークNW3)を介して管理装置13に当該ガスメータ情報を送信(アップロード)するようにしてもよい(図1参照)。これにより、ネットワークNW3(LPWAネットワーク)によってガスメータ情報を取得できない地域などにおいては、第1実施形態で説明したように検針者が携帯端末12を所持して、検針対象の地域に赴き、ガスメータ情報を収集することができる。 The gas meter information may be collected by the portable terminal 12 in the same manner as in the first embodiment, in addition to automatic acquisition by the management device 13 (delivery management means 50). For example, the mobile terminal 12 receives and collects the gas meter information transmitted from the information transmission device 11, and transmits (uploads) the gas meter information to the management device 13 via the network NW1 (or network NW3). Good (see FIG. 1). As a result, in areas where the gas meter information cannot be acquired by the network NW3 (LPWA network), the meter reader has the portable terminal 12 as described in the first embodiment, goes to the area to be metered, and displays the gas meter information. Can be collected.
 また、ガス供給管理システム10を構成する各装置(ハードウェア)の一部または全てを、当該装置(ハードウェア)と同等の機能を実現するソフトウェアに置き換えてもよい。 Further, a part or all of each device (hardware) constituting the gas supply management system 10 may be replaced with software that realizes a function equivalent to the device (hardware).
 また、本発明のガス供給管理システム10等は、上記した実施の形態に限定されるものではなく、本発明の要旨を逸脱しない範囲内において種々変更を加え得ることは勿論である。 Further, the gas supply management system 10 and the like of the present invention are not limited to the above-described embodiments, and it is needless to say that various modifications can be made without departing from the gist of the present invention.
10  ガス供給管理システム
11  情報送信手段(情報送信装置)
12  携帯端末
13  管理装置
14  事業者用サーバ装置
20  ガスボンベ
21  ガスメータ
22  外部端子
23  接続手段
25  ガス供給管
50  配送管理手段
111  接続部
112  取得部
113  通信部
114  電池
115  制御部
116  メモリ
117  情報送信要求受信手段
118  個別情報送信手段
121  表示手段
122  入力手段
123  メモリ
124  通信手段
127  地理情報表示手段
128  情報送信要求手段
129  情報受付送信手段
133  記憶手段(記憶装置)
134  入力手段
135  出力手段
136  通信手段
137  使用量算出手段
138  配送予測手段
139  地理情報表示手段
NW  ネットワーク
NW1  ネットワーク
NW2  ネットワーク
NW3  ネットワーク 
10 Gas Supply Management System 11 Information Transmitting Means (Information Transmitting Device)
DESCRIPTION OF SYMBOLS 12 Mobile terminal 13 Management apparatus 14 Server apparatus 20 for business operators Gas cylinder 21 Gas meter 22 External terminal 23 Connection means 25 Gas supply pipe 50 Delivery management means 111 Connection part 112 Acquisition part 113 Communication part 114 Battery 115 Control part 116 Memory 117 Information transmission request Reception means 118 Individual information transmission means 121 Display means 122 Input means 123 Memory 124 Communication means 127 Geographic information display means 128 Information transmission request means 129 Information reception / transmission means 133 Storage means (storage device)
134 Input means 135 Output means 136 Communication means 137 Usage amount calculation means 138 Delivery prediction means 139 Geographic information display means NW Network NW1 Network NW2 Network NW3 Network

Claims (35)

  1.  情報送信手段と、収集手段と、管理手段とを備えたガス供給管理システムであって、
     前記情報送信手段は、複数の供給先施設のガス容器に対応したガスメータとそれぞれ接続し、該ガスメータからの情報を取得して前記収集手段に送信し、
     前記収集手段は、前記情報送信手段から送信された前記情報を収集し、
     前記管理手段は、使用量算出手段と、配送予測手段と、を有し、前記収集手段が収集した前記情報をネットワークを介して取得し、
     前記情報に基づき、前記使用量算出手段によって前記ガス容器ごとのガス使用量を算出して出力し、
     前記配送予測手段によって前記供給先施設ごとに前記ガス容器の配送の予定日を予測する、
    ことを特徴とするガス供給管理システム。
    A gas supply management system comprising an information transmission means, a collection means, and a management means,
    The information transmitting means is connected to each gas meter corresponding to a gas container of a plurality of supply destination facilities, acquires information from the gas meter, and transmits the information to the collecting means.
    The collecting means collects the information transmitted from the information transmitting means;
    The management unit includes a usage amount calculation unit and a delivery prediction unit, and acquires the information collected by the collection unit via a network,
    Based on the information, the usage calculation means calculates and outputs the gas usage for each gas container,
    Predicting the scheduled delivery date of the gas container for each of the destination facilities by the delivery prediction means;
    A gas supply management system characterized by that.
  2.  前記管理手段は、月次よりも高い頻度で前記情報を収集する、
    ことを特徴とする請求項1に記載のガス供給管理システム。
    The management means collects the information more frequently than monthly;
    The gas supply management system according to claim 1.
  3.  前記管理手段は、予測した前記配送の予定日に基づき、配送すべき前記供給先施設を特定し、出力する、
    ことを特徴とする請求項1または請求項2に記載のガス供給管理システム。
    The management means identifies and outputs the supply destination facility to be delivered based on the predicted delivery date predicted.
    The gas supply management system according to claim 1 or 2, wherein
  4.  前記配送予測手段は、前記配送の予定日に基づき、最適な配送経路を予測する、
    ことを特徴とする請求項1から請求項3のいずれかに記載のガス供給管理システム。
    The delivery prediction means predicts an optimal delivery route based on the scheduled delivery date;
    The gas supply management system according to any one of claims 1 to 3, wherein
  5.  移動通信端末を備え、
     前記管理手段は、前記移動通信端末に前記配送経路を送信する、
    ことを特徴とする請求項4に記載のガス供給管理システム。
    Equipped with mobile communication terminals,
    The management means transmits the delivery route to the mobile communication terminal.
    The gas supply management system according to claim 4.
  6.  前記収集手段は、基地局または基地局に接続する端末であり、
     前記ネットワークに接続し、前記収集手段が収集した前記情報を格納する格納手段を備え、
     前記管理手段は、前記格納手段から前記情報を取得し、
     前記配送予測手段は、将来の日付けにおける日別の予測使用量を算出可能である、
    ことを特徴とする請求項1から請求項5のいずれかに記載のガス供給管理システム。
    The collection means is a base station or a terminal connected to the base station,
    Storage means for connecting to the network and storing the information collected by the collection means;
    The management means acquires the information from the storage means,
    The delivery prediction means is capable of calculating a daily estimated usage amount in a future date.
    The gas supply management system according to any one of claims 1 to 5, wherein
  7.  前記配送予測手段は、日数の経過に伴って増加又は減少するように前記予測使用量を算出する、
    ことを特徴とする請求項6に記載のガス供給管理システム。
    The delivery prediction means calculates the predicted usage amount so as to increase or decrease with the passage of days;
    The gas supply management system according to claim 6.
  8.  前記配送予測手段は、
     過去の所定期間における基準ガス使用量に基づいて日毎に単位予測使用変化量を算出し、
     前記単位予測使用変化量に基づいて前記予測使用量を算出する、
    ことを特徴とする請求項6または請求項7に記載のガス供給管理システム。
    The delivery prediction means includes
    Based on the reference gas usage in the past predetermined period, calculate the unit predicted usage change amount every day,
    Calculating the predicted usage based on the unit predicted usage change amount;
    The gas supply management system according to claim 6 or 7, wherein
  9.  前記基準ガス使用量は、過去の使用実績量である、
    ことを特徴とする請求項8に記載のガス供給管理システム。
    The reference gas usage amount is a past usage amount,
    The gas supply management system according to claim 8.
  10.  前記基準ガス使用量は、例年のガス使用量の傾向に基づく設定値である、
    ことを特徴とする請求項8に記載のガス供給管理システム。
    The reference gas use amount is a set value based on a trend of gas use amount in an ordinary year.
    The gas supply management system according to claim 8.
  11.  前記配送予測手段は、前記予測使用量に基づいて前記ガス容器内の将来の日付けにおける日別のガス残量を予測し、該ガス残量が所定量に減量する日付けを予測して前記配送の予定日を決定する、
    ことを特徴とする請求項6から請求項10のいずれかに記載のガス供給管理システム。
    The delivery predicting means predicts a daily gas remaining amount in a future date in the gas container based on the predicted usage, and predicts a date when the gas remaining amount is reduced to a predetermined amount. Determine the expected delivery date,
    The gas supply management system according to any one of claims 6 to 10, wherein
  12.  前記配送予測手段は、
     前記配送の予定日が同じである複数の前記供給先施設を少なくとも含む所定範囲の複数の前記供給先施設について、最短経路で配送可能となるルートを決定する、
    ことを特徴とする請求項1から請求項11のいずれかに記載のガス供給管理システム。
    The delivery prediction means includes
    Determining a route that can be delivered by a shortest route for a plurality of the supply destination facilities in a predetermined range including at least the plurality of supply destination facilities having the same scheduled delivery date;
    The gas supply management system according to any one of claims 1 to 11, wherein
  13.  前記収集手段は、移動通信が可能な携帯端末である、
    ことを特徴とする請求項1に記載のガス供給管理システム。
    The collecting means is a portable terminal capable of mobile communication.
    The gas supply management system according to claim 1.
  14.  前記情報送信手段は、周期的に前記携帯端末からの情報送信要求を受信し、該情報送信要求に基づき前記情報を前記携帯端末に送信する、
    ことを特徴とする請求項13に記載のガス供給管理システム。
    The information transmission means periodically receives an information transmission request from the mobile terminal, and transmits the information to the mobile terminal based on the information transmission request.
    The gas supply management system according to claim 13.
  15.  前記携帯端末は、前記情報送信手段に対して任意のタイミングで所定期間に亘り前記情報送信要求を送信し、
     前記情報送信手段から送信される前記情報を受信して前記管理手段に対して前記情報を送信する、
    ことを特徴とする請求項14に記載のガス供給管理システム。
    The portable terminal transmits the information transmission request over a predetermined period at an arbitrary timing to the information transmission means,
    Receiving the information transmitted from the information transmitting means and transmitting the information to the management means;
    The gas supply management system according to claim 14.
  16.  前記携帯端末は、対象となる前記ガスメータごとの前記情報の取得の成否を表示する表示手段を備える、
    ことを特徴とする請求項13から請求項15のいずれかに記載のガス供給管理システム。
    The portable terminal includes display means for displaying success or failure of acquisition of the information for each target gas meter.
    The gas supply management system according to any one of claims 13 to 15, wherein
  17.  前記携帯端末は、該携帯端末の使用者による前記情報の入力を受け付け、前管理端末に該情報を送信する情報受付送信手段を備える、
    ことを特徴とする請求項13から請求項16のいずれかに記載のガス供給管理システム。
    The mobile terminal includes an information reception / transmission unit that receives an input of the information by a user of the mobile terminal and transmits the information to a previous management terminal.
    The gas supply management system according to any one of claims 13 to 16, wherein
  18.  前記情報は、前記ガスメータを識別可能な固有番号と、前記ガス容器ごとのガス使用量を示す指針値および保安情報とを含む情報である、
    ことを特徴とする請求項1から請求項17のいずれかに記載のガス供給管理システム。
    The information is information including a unique number that can identify the gas meter, and a guideline value and safety information indicating a gas usage amount for each gas container.
    The gas supply management system according to any one of claims 1 to 17, wherein
  19.  前記情報送信手段は、電池を内蔵する、
    ことを特徴とする請求項1から請求項18のいずれかに記載のガス供給管理システム。
    The information transmitting means includes a battery.
    The gas supply management system according to any one of claims 1 to 18, wherein the system is a gas supply management system.
  20.  情報送信手段と、収集手段と、管理手段とを用いるガス供給管理方法であって、
     複数の供給先施設のガス容器に対応したガスメータとそれぞれ接続する情報送信手段によって前記ガスメータからの情報を取得して前記収集手段に送信するステップと、
     前記管理手段が、前記収集手段が収集した前記情報をネットワークを介して取得し、該情報に基づき、前記ガス容器ごとのガスの使用量を算出して出力するステップと、
     前記情報に基づき、前記供給先施設ごとに前記ガス容器の次回の配送の予定日を予測するステップと、を有する、
    ことを特徴とするガス供給管理方法。
    A gas supply management method using an information transmission means, a collection means, and a management means,
    Acquiring information from the gas meter by information transmitting means connected to gas meters corresponding to gas containers of a plurality of supply destination facilities and transmitting the information to the collecting means;
    The management means obtains the information collected by the collecting means via a network, and calculates and outputs the amount of gas used for each gas container based on the information;
    Based on the information, predicting the next delivery date of the gas container for each of the supply destination facilities,
    The gas supply management method characterized by the above-mentioned.
  21.  前記情報を、月次よりも高い頻度で収集する、
    ことを特徴とする請求項20に記載のガス供給管理方法。
    Collecting the information more frequently than monthly;
    The gas supply management method according to claim 20, wherein
  22.  予測した前記配送の予定日に基づき、配送すべき前記供給先施設を特定する、
    ことを特徴とする請求項20または請求項21に記載のガス供給管理方法。
    Identifying the destination facility to be delivered based on the estimated delivery date predicted;
    The gas supply management method according to claim 20 or claim 21, wherein
  23.  前記配送の予定日に基づき、最適な配送経路を予測するステップを有する、
    ことを特徴とする請求項20から請求項22のいずれかに記載のガス供給管理方法。
    Predicting an optimal delivery route based on the scheduled delivery date;
    The gas supply management method according to any one of claims 20 to 22, wherein the gas supply management method is provided.
  24.  前記管理手段が予測した前記配送経路を移動通信端末に送信する、
    ことを特徴とする請求項23に記載のガス供給管理方法。
    Transmitting the delivery route predicted by the management means to a mobile communication terminal;
    The gas supply management method according to claim 23.
  25.  前記収集手段は、基地局または基地局に接続する端末であり、
     前記ネットワークに接続し、前記収集手段が収集した前記情報を格納する格納手段を備え、
     前記管理手段によって、前記格納手段から前記情報を取得し、将来の日付けにおける日別の予測使用量を算出する、
    ことを特徴とする請求項22から請求項24のいずれかに記載のガス供給管理方法。
    The collection means is a base station or a terminal connected to the base station,
    Storage means for connecting to the network and storing the information collected by the collection means;
    The management unit obtains the information from the storage unit, and calculates a daily predicted usage amount in a future date;
    25. The gas supply management method according to any one of claims 22 to 24, wherein:
  26.  日数の経過に伴って増加又は減少するように前記予測使用量を算出する、
    ことを特徴とする請求項25に記載のガス供給管理方法。
    Calculate the predicted usage so that it increases or decreases with the passage of days,
    26. The gas supply management method according to claim 25.
  27.  過去の所定期間における基準ガス使用量に基づいて日毎の単位予測使用変化量を算出し、
     前記単位予測使用変化量に基づいて前記予測使用量を算出する、
    ことを特徴とする請求項25または請求項26に記載のガス供給管理方法。
    Based on the reference gas usage over a predetermined period in the past, the daily unit usage change is calculated,
    Calculating the predicted usage based on the unit predicted usage change amount;
    27. The gas supply management method according to claim 25 or claim 26.
  28.  前記基準ガス使用量は、過去の使用実績量である、
    ことを特徴とする請求項27に記載のガス供給管理方法。
    The reference gas usage amount is a past usage amount,
    The gas supply management method according to claim 27.
  29.  前記基準ガス使用量は、例年のガス使用量の傾向に基づく設定値である、
    ことを特徴とする請求項27に記載のガス供給管理方法。
    The reference gas use amount is a set value based on a trend of gas use amount in an ordinary year.
    The gas supply management method according to claim 27.
  30.  前記予測使用量に基づいて前記ガス容器内の将来の日付けにおける日別のガス残量を予測し、該ガス残量が所定量に減量する日付けを予測して前記配送の予定日を決定する、
    ことを特徴とする請求項25から請求項29のいずれかに記載のガス供給管理方法。
    Based on the predicted usage amount, the gas remaining amount by day in the future date in the gas container is predicted, and the date on which the remaining gas amount is reduced to a predetermined amount is predicted to determine the scheduled delivery date. To
    The gas supply management method according to any one of claims 25 to 29, wherein:
  31.  前記配送の予定日が同じである複数の前記供給先施設を少なくとも含む所定範囲の複数の前記供給先施設について、最短経路で配送可能となるルートを決定する、
    ことを特徴とする請求項22から請求項30のいずれかに記載のガス供給管理方法。
    Determining a route that can be delivered by a shortest route for a plurality of the supply destination facilities in a predetermined range including at least the plurality of supply destination facilities having the same scheduled delivery date;
    The gas supply management method according to any one of claims 22 to 30, wherein the gas supply management method is provided.
  32.  前記収集手段は、移動通信が可能な携帯端末であり、前記携帯端末が、前記情報送信手段に対して任意のタイミングで所定期間に亘り情報送信要求を送信するステップと、
     前記情報送信手段が、周期的に前記携帯端末からの前記情報送信要求を受信し、該情報送信要求に基づき前記情報を前記携帯端末に送信するステップと、を有する、
    ことを特徴とする請求項22に記載のガス供給管理方法。
    The collection means is a mobile terminal capable of mobile communication, and the mobile terminal transmits an information transmission request to the information transmission means at an arbitrary timing for a predetermined period;
    The information transmission means periodically receiving the information transmission request from the portable terminal, and transmitting the information to the portable terminal based on the information transmission request.
    The gas supply management method according to claim 22, wherein:
  33.  前記供給先施設ごとの前記ガス容器の配送日から所定期間後に前記携帯端末から送信された前記情報の入力を受け付ける情報受付日を設定し、
     前記情報受付日に入力された前記情報に基づき前記ガス容器内のガス残量を算出するとともに、該ガス残量が所定量に減量するまでの日数を予測して前記予定日を決定する、
    ことを特徴とする請求項32に記載のガス供給管理方法。
    Set an information reception date for receiving input of the information transmitted from the portable terminal after a predetermined period from the delivery date of the gas container for each supply facility,
    Calculating the remaining amount of gas in the gas container based on the information input on the information reception date, and determining the scheduled date by predicting the number of days until the remaining amount of gas is reduced to a predetermined amount;
    The gas supply management method according to claim 32, wherein:
  34.  請求項22から請求項33のいずれかに記載のガス供給管理方法をコンピュータに実行させることを特徴とするプログラム。 A program that causes a computer to execute the gas supply management method according to any one of claims 22 to 33.
  35.  交換可能な電池と、
     複数の供給先施設のガス容器に対応したガスメータの外部端子にそれぞれ接続する接続部と、
     前記ガスメータからの情報を取得する取得部と、
     前記情報をネットワークを介して収集手段に送信可能な通信部と、
     を備えた情報送信装置。
    With replaceable batteries,
    A connecting portion for connecting to an external terminal of a gas meter corresponding to a gas container of a plurality of supply facilities;
    An acquisition unit for acquiring information from the gas meter;
    A communication unit capable of transmitting the information to the collecting means via a network;
    An information transmission device comprising:
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