INFORMATION MANAGEMENT SYSTEM, CARBON DIOXIDE COLLECTION STATION, AND INFORMATION MANAGEMENT DEVICE

Abstract

An information management system includes: a plurality of CO2 recovery devices configured to recover CO2; a CO2 collection station configured to collect CO2 recovered by the plurality of CO2 recovery devices; a CO2 using facility configured to use CO2 collected at the CO2 collection station; and an information management device including a communication unit configured to transmit linked information in which intended use information indicating intended use of CO2 in the CO2 using facility and an amount of use for the intended use is linked with identification information of a user of each of the plurality of CO2 recovery devices to an information communication terminal used by the user.

Description

The present application is a continuation of U.S. patent application Ser. No. 17/038,142 filed on Sep. 30, 2020, which claims the benefit of Japanese Priority Patent Application No. 2019-202558 filed in Japan on Nov. 7, 2019, the entire contents of which are incorporated herein by reference.

BACKGROUND

The present disclosure relates to an information management system, a CO₂ using facility, a CO₂ collection station, an information management device, a vehicle, a building, and an information communication terminal.

There has been known a CO₂ recovery system that reduces the amount of CO₂ emitted from vehicles by using a CO₂ recovery device that captures and stores carbon dioxide (CO₂) emitted from vehicles (JP 2014-509360 A).

SUMMARY

In the CO₂ recovery system described in JP 2014-509360 A, it is assumed that CO₂ recovered from a vehicle having a CO₂ recovery device is collected at another place such as a CO₂ collection station, and the collected CO₂ is used for conversion into fuel. However, there has not been disclosed information management technology for informing a user who uses the CO₂ recovery device of information such as the intended use and amount of use of CO₂ collected from the CO₂ recovery device.

There is a need for an information management system that is capable of informing a user who uses a CO₂ recovery device of information such as the intended use and amount of use of CO₂ recovered from the CO₂ recovery device, and a CO₂ using facility, a CO₂ collection station, an information management device, a vehicle, a building, and an information communication terminal that are suitable for constructing the information management system.

According to one aspect of the present disclosure, there is provided an information management system including: a plurality of CO₂ recovery devices configured to recover CO₂; a CO₂ collection station configured to collect CO₂ recovered by the plurality of CO₂ recovery devices; a CO₂ using facility configured to use CO₂ collected at the CO₂ collection station; and an information management device including a communication unit configured to transmit linked information in which intended use information indicating intended use of CO₂ in the CO₂ using facility and an amount of use for the intended use is linked with identification information of a user of each of the plurality of CO₂ recovery devices to an information communication terminal used by the user.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram illustrating an information management system according to a first embodiment;

FIGS. 2A to 2D are explanatory diagrams of a database B of a CO₂ collection station according to the first embodiment;

FIG. 3 is an explanatory diagram of information processing in a processing plant according to the first embodiment;

FIG. 4 is an explanatory diagram of a database F of an information management center according to the first embodiment;

FIG. 5 is an explanatory diagram of an information communication terminal 12 according to the first embodiment;

FIG. 6A is a control flowchart performed by a vehicle according to the first embodiment;

FIG. 6B is a control flowchart performed by the CO₂ collection station according to the first embodiment;

FIGS. 7A and 7B are control flowcharts performed by the CO₂ collection station and a transportation vehicle according to the first embodiment, respectively;

FIGS. 8A and 8B are control flowcharts performed by the transportation vehicle and the processing plant according to the first embodiment, respectively;

FIG. 9 is a control flowchart of information processing performed by the processing plant according to the first embodiment;

FIG. 10A is a control flowchart performed by the processing plant according to the first embodiment;

FIG. 10B is a control flowchart performed by the information management center according to the first embodiment;

FIGS. 11A and 11B are control flowcharts performed by the vehicle and the information management center according to the first embodiment, respectively; and

FIG. 12 is a control flowchart performed by the information communication terminal according to the first embodiment.

DETAILED DESCRIPTION

Hereinafter, an embodiment will be described with reference to the drawings.

Information Management System

FIG. 1 is a block diagram illustrating an information management system according to a first embodiment. An information management system 1000 includes three vehicles 1A, 1B, and 1C as an example of a plurality of vehicles, two CO₂ collection stations 2A and 2B as an example of a plurality of CO₂ collection stations, a transportation vehicle 3, a processing plant 4, an information management center 5, and a communication network 6. In the first embodiment, a description will be given assuming that among the vehicles 1A, 1B, and 1C, the vehicle 1A is appropriately used as a representative, among the CO₂ collection stations 2A and 2B, the CO₂ collection station 2A is appropriately used as a representative, and the processing plant 4 is used as an example of a CO₂ using facility. Other vehicles 1B and 1C may have the same configuration as the vehicle 1A. The CO₂ collection station 2B may have the same configuration as the CO₂ collection station 2A.

Vehicle

The vehicle 1A includes a CO₂ recovery device 10, a controller 11, and an information communication terminal 12. The CO₂ recovery device 10, the controller 11, and the information communication terminal 12 are communicably connected to each other using an in-vehicle network such as CAN (controller area network).

The CO₂ recovery device 10 includes a CO₂ recovery unit 100, a CO₂ recovery control unit 101, and a CO₂ tank 102. The CO₂ recovery unit 100 recovers exhaust gas emitted from the vehicle 1A or CO₂ gas contained in the atmosphere by, for example, the method described in JP 2014-509360 A, that is, the method such as chemical adsorption or physical adsorption. The CO₂ recovery unit 100 discharges the recovered CO₂ to the CO₂ collection station. The CO₂ tank 102 stores the CO₂ recovered by the CO₂ recovery unit 100. The CO₂ recovery control unit 101 controls the start and end of CO₂ recovery of the CO₂ recovery unit 100 according to the storable amount of the CO₂ tank 102 and the like. The CO₂ recovery control unit 101 includes a computation processing unit such as a CPU (central processor) and an FPGA (field-programmable gate array), and a storage unit that includes a ROM (read only memory) storing a program executed by the computation processing unit and various data and a RAM (random access memory) as a work space for computation processing. The CO₂ recovery control unit 101 executes the control described above by the computation processing unit executing the program stored in the storage unit. The CO₂ recovery unit 100 also includes a connection sensor that detects whether the CO₂ recovery unit 100 is connected to the CO₂ collection station 2A.

The CO₂ tank 102 is a tank that compresses and stores CO₂ recovered by the CO₂ recovery unit 100. The CO₂ tank 102 includes a storage amount sensor that detects a storage amount.

The controller 11 includes a control unit 110 and a storage unit 111.

The control unit 110 includes a computation processing unit such as a CPU, and executes a program stored in the storage unit 111, thus storing information received by a communication unit 120 in the storage unit 111 or transmitting the information in the storage unit 111 from the communication unit 120 included in the information communication terminal 12.

The storage unit 111 includes a main storage unit such as a ROM or a RAM, and stores a program executed by the control unit 110 and various data, and provides a work space for computation processing. Further, the storage unit 111 stores identification information of the user of the CO₂ recovery device 10, the amount of CO₂ recovered by the CO₂ recovery device 10, and information about the intended use of the recovered CO₂ in a database A1110. The user of the CO₂ recovery device 10 is, for example, the owner of the vehicle 1A including the CO₂ recovery device 10. The intended use information will be described in detail later. The storage unit 111 may include a large-capacity auxiliary storage device using a magnetic medium such as an HDD (hard disc drive), an optical medium such as a DVD (digital versatile disc), or a semiconductor memory such as an SSD (solid state drive).

The information communication terminal 12 includes the communication unit 120, an output unit 121, an input unit 122, and a terminal control unit 123.

The communication unit 120 transmits and receives information to and from the information management center 5 via the communication network 6 including a wireless communication network. The communication unit 120 transmits and receives information to and from the CO₂ collection station 2 through near-field communication such as WI-FI (registered trademark) or Bluetooth (registered trademark). The communication unit 120 is implemented by, for example, a DCM (data communication module).

The output unit 121 displays or speaks the information about the intended use and amount of use of CO₂ received from the information management center 5 by the communication unit 120, and includes, for example, a liquid crystal display or a speaker. The input unit 122 allows a user to input an operation, and includes, for example, a touch panel and a microphone. The information about the intended use and amount of use of CO₂ will be described in detail later.

The terminal control unit 123 includes a computation processing unit and a storage unit that stores a program a program executed by the computation processing unit and various data and also provides a work space for computation processing. As the computation processing unit executes the program stored in the storage unit, the information stored in the storage unit 111 is output to the output unit 121, and the input information input from the input unit 122 is output to the control unit 110.

The information communication terminal 12 may be any terminal that may be used by a user and whose output may be checked, and may be achieved by an in-vehicle navigation system and a mobile information communication terminal such as a smartphone or a tablet. The communication unit 120 may be implemented by a communication module mounted on the vehicle 1A, for example, a DCM (data communication module).

CO₂ Collection Station

The CO₂ collection stations 2A and 2B are stations for collecting CO₂ recovered by the CO₂ recovery device 10 in any of the vehicles 1A, 1B, and 1C. The CO₂ collection station 2A includes a CO₂ collection device 20 and a controller 21 that are communicably connected to each other.

The CO₂ collection device 20 includes a CO₂ collection unit 200, a CO₂ collection control unit 201, and a CO₂ tank 202.

The CO₂ collection unit 200 is connected to the CO₂ recovery device 10 of the vehicle 1A to collect CO₂ stored in the CO₂ tank 102 of the vehicle 1A. The CO₂ collection unit 200 is also connected to a CO₂ collection device 30 of the transportation vehicle 3 to discharge CO₂ stored in the CO₂ tank 202 into the transportation vehicle 3. Moreover, the CO₂ collection unit 200 includes a connection sensor that detects which of the CO₂ collection station 2 and the transportation vehicle 3 is connected to the CO₂ collection unit 200.

The CO₂ tank 202 is a tank that compresses and stores CO₂ collected by the CO₂ collection unit 200. The CO₂ tank 202 includes a storage amount sensor that detects a storage amount.

The CO₂ collection control unit 201 controls the start or end of collection control in the CO₂ collection unit 200 based on the storage amount of the CO₂ tank 102 in the vehicle 1A and the like. The CO₂ collection control unit 201 includes a computation processing unit and a storage unit that stores a program executed by the computation processing unit and various data and provides a work space for computation processing. The CO₂ collection control unit 201 executes the above control by the computation processing unit executing the program stored in the storage unit.

The controller 21 includes a communication unit 210, a storage unit 211, and a control unit 212.

The communication unit 210 is a communication module, and transmits and receives information to and from the vehicle 1A or the transportation vehicle 3 through near-field communication.

The storage unit 211 includes a main storage unit, and stores a program executed by the control unit 212 and various data, and provides a work space for computation processing. Further, the storage unit 211 stores identification information of the user of the CO₂ recovery device 10 and the amount of CO₂ collected from the CO₂ recovery device 10 in a database B2110. The storage unit 211 may include a large-capacity auxiliary storage device.

The control unit 212 includes a computation processing unit, and executes the program stored in the storage unit 211, thus causing the communication unit 210 to transmit the information in the storage unit 211 and linking the information received by the communication unit 210 with a CO₂ collection start time for storage in the storage unit 211. The CO₂ collection start time and the information linked with the CO₂ collection start time will be described in detail later.

Transportation Vehicle

The transportation vehicle 3 is a vehicle that transports CO₂ from the CO₂ collection stations 2A and 2B to the processing plant 4, and is, for example, a tank truck. The transportation vehicle 3 includes the CO₂ collection device 30 and a controller 31 that are communicably connected to each other.

The CO₂ collection device 30 includes a CO₂ collection unit 300, a CO₂ collection control unit 301, and a CO₂ tank 302.

The CO₂ collection unit 300 is connected to the CO₂ collection device 20 in the CO₂ collection station 2 to collect CO₂ stored in the CO₂ tank 202 of the CO₂ collection station 2A. The CO₂ collection unit 300 also discharges CO₂ in the CO₂ tank 302 of the transportation vehicle 3 into the processing plant 4. Moreover, the CO₂ collection unit 300 includes a connection sensor that detects which of the CO₂ collection station 2 and the processing plant 4 is connected to the CO₂ collection unit 300.

The CO₂ tank 302 is a tank that compresses and stores CO₂ collected by the CO₂ collection unit 300. The CO₂ tank 302 includes a storage amount sensor that detects a storage amount.

The CO₂ collection control unit 301 controls the start or end of collection control in the CO₂ collection unit 300 based on the storage amount of the CO₂ tank 202 in the CO₂ collection station 2A and the like. The CO₂ collection control unit 301 includes a computation processing unit and a storage unit that stores a program executed by the computation processing unit and various data and provides a work space for computation processing. The CO₂ collection control unit 301 executes the above control by the computation processing unit executing the program stored in the storage unit.

The controller 31 includes a communication unit 310, a storage unit 311, and a control unit 312.

The communication unit 310 is a communication module, and transmits and receives information to and from the CO₂ collection station 2 or the processing plant 4 through near-field communication.

The storage unit 311 includes a main storage unit, and stores a program and various data, and provides a work space for computation processing. Further, the storage unit 311 stores the identification information of the user of the CO₂ recovery device 10, the amount of CO₂ collected from the user, and a collection start time in a database C3110. The storage unit 311 may include a large-capacity auxiliary storage device.

The control unit 312 executes the program stored in the storage unit 311, thus causing the communication unit 310 to transmit the information in the storage unit 311 or storing the information received by the communication unit 310 in the storage unit 311.

Processing Plant

The processing plant 4 includes a CO₂ processing device 40, a CO₂ collection device 41, and a controller 42 that are communicably connected to each other.

The CO₂ processing device 40 is a processing device capable of processing CO₂ or utilizing CO₂ as it is, and is a device having a plurality of intended uses such as uses of CO₂ for conversion into fuel and photosynthesis of plants. In the present specification, it may be described that CO₂ is processed, even when CO₂ is used as it is without being processed, such as use for photosynthesis of plants.

The CO₂ collection device 41 includes a CO₂ collection unit 410, a CO₂ collection control unit 411, and a CO₂ tank 412.

The CO₂ collection unit 410 is connected to the CO₂ collection device 30 of the transportation vehicle 3, thus collecting CO₂ stored in the CO₂ tank 302 of the transportation vehicle 3.

The CO₂ tank 412 is a tank that compresses and stores CO₂ collected by the CO₂ collection unit 410. The CO₂ tank 412 includes a storage amount sensor that detects a storage amount.

The CO₂ collection control unit 411 controls the start or end of collection control in the CO₂ collection unit 410 based on the storage amount of the CO₂ tank 302 of the transportation vehicle 3 and the like.

The controller 42 includes a communication unit 420, a storage unit 421, a processor 422, and a control unit 423.

The communication unit 420 is a communication module, and transmits and receives information to and from the transportation vehicle 3 through near-field communication, or transmits and receives information to and from the information management center 5 via the communication network 6.

The storage unit 421 includes a main storage unit, and stores a program and various data, and provides a work space for computation processing. The storage unit 421 includes a database D4210 and a database E4211. The storage unit 421 stores the identification information of the user of the CO₂ recovery device 10, the amount of CO₂ collected from the CO₂ recovery device 10, and the information indicating a CO₂ collection start time in the database D4210. The storage unit 421 stores the identification information of the user of the CO₂ recovery device 10 and the information about the amount of CO₂ collected from the user, these pieces of information being stored in the database D4210, and information indicating the amount of use and intended use of CO₂ in the CO₂ processing device 40 in the database E4211.

The processor 422 executes the program stored in the storage unit 421 to calculate the amount of CO₂ used in the CO₂ processing device 40 and perform information processing for linking the information about the amount of use calculated and the intended use with the information in the database D4210.

The control unit 423 executes the program stored in the storage unit 421, thus causing the communication unit 420 to transmit the information in the storage unit 421 or storing the information received by the communication unit 420 in the storage unit 421.

Information Management Center

The information management center 5 has a controller 50 that includes a communication unit 500, a storage unit 501, a processor 502, and a control unit 503 that are communicable with each other.

The communication unit 500 is a communication module, and transmits and receives information to and from the processing plant 4 and the vehicle 1A via the communication network 6.

The storage unit 501 includes a main storage unit, and stores a program and various data, and provides a work space for computation processing. The storage unit 501 also includes a database F5010. The storage unit 501 stores the intended use in the processing plant 4, the amount of use of CO₂, and the identification information of the user of the CO₂ recovery device 10, these pieces of information being received from the processing plant 4, in the database F5010.

The processor 502 executes the program stored in the storage unit 501 to perform a process such as linking the information newly received from the processing plant 4 with the information in the database F5010 for updating.

The control unit 503 executes the program stored in the storage unit 501, thus causing the communication unit 500 to transmit the information in the storage unit 501 to the vehicle 1A or the processing plant 4.

Control and Information Flow in Information Management System

Control and a flow of information in the information management system 1000 will be described with reference to FIG. 1. In each of the vehicles 1A, 1B, and 1C, the CO₂ recovery device 10 recovers CO₂. For example, when the CO₂ recovery device 10 has recovered a certain amount of CO₂, a user of the vehicles 1A, 1B, or 1C goes to the CO₂ collection station 2A or 2B. CO₂ recovered in the vehicles 1A, 1B, and 1C is collected in the CO₂ collection stations 2A and 2B. Along with this collection, the identification information of the user of the CO₂ recovery device 10 and the information about the amount of CO₂ collected from the CO₂ recovery device 10 and a collection start time are linked with each other and stored in the storage unit 211 of the controller 21 in the CO₂ collection stations 2A and 2B. The identification information of the user of the CO₂ recovery device 10 is transmitted from the storage unit 111 of the controller 11 by the communication unit 120 of the information communication terminal 12 and received by the communication unit 210.

The linked information stored in the storage unit 211 is transmitted to the processing plant 4 via the transportation vehicle 3. In the processing plant 4, the amount of collection of CO₂ and the information indicating the intended use in the processing plant 4 and the amount of use of CO₂ for the intended use are linked with each other and stored in the storage unit 421 of the controller 42. The linked information stored in the storage unit 421 is transmitted to the information management center 5. The information including the intended use information such as the intended use and amount of use of CO₂ that are linked with each other is transmitted from the information management center 5 to the information communication terminal 12 of each of the vehicles 1A, 1B, and 1C including the CO₂ recovery device 10. As the information communication terminal 12 displays or speaks the information including the intended use information to notify each user of the CO₂ recovery device 10 of the information including the intended use information.

FIGS. 2A to 2D are explanatory diagrams of the database B of the CO₂ collection station according to the first embodiment. FIG. 2A illustrates an example of the state of the CO₂ tank 202 in the CO₂ collection station 2A, and FIG. 2B illustrates the contents of the database B2110 of the CO₂ collection station 2A corresponding to FIG. 2A. FIG. 2C illustrates an example of the state of the CO₂ tank 202 in the CO₂ collection station 2B, and FIG. 2D illustrates the contents of a database B2111 of the CO₂ collection station 2B corresponding to FIG. 2C. It is assumed that the CO₂ collection station 2A has the CO₂ tank 202 having a maximum capacity of (MAX), collects (20) of the amount of CO₂ from the vehicle 1A used by a user A, and collects (10) of the amount of CO₂ from the vehicle 1B used by a user B. It is assumed that the CO₂ collection station 2B has the CO₂ tank 202 having a maximum capacity of (MAX), and collects (15) of the amount of CO₂ from the vehicle 1C used by a user C. While the unit of the amount of collection is, for example, mass, the unit is a dimensionless unit for the sake of simplicity. At this time, the identification information of the user of the CO₂ recovery device 10, the collection start time when the user starts the collection in the CO₂ collection station 2, and the amount of collection of CO₂ are linked with each other, and stored in the database B2110 of the CO₂ collection station 2A and the database B2111 of the CO₂ collection station 2B, respectively. The user identification information is information for identifying the user on the information management system 1000, and for example, a registration number corresponding to a user registered in the database of a dealer when the owner of the vehicle 1A has purchased the vehicle 1A including the CO₂ recovery device 10 is used. These pieces of information stored in the database B2111 are transmitted to the database C3110 included in the controller 31 of the transportation vehicle 3, and further transmitted to the database D4210 included in the controller 42 of the processing plant 4.

FIG. 3 is an explanatory diagram of information processing in the processing plant according to the first embodiment. FIG. 3 illustrates the storage state of the CO₂ tank 412 in the processing plant 4 and the information processing in the database D4210 in a corresponding manner. In the processing plant 4, CO₂ stored in the CO₂ tank 412 is sequentially allocated to the identification information of a user whose collection start time is earlier. For example, in the database D4210 that stores the information in which the user identification information, the CO₂ collection start time, the amount of collection of CO₂, and the amount of use of CO₂ are linked with each other, the linked information is sorted in ascending order of the collection start time. In practice, it is not possible to distinguish which CO₂ in the CO₂ tank 412 is collected by which user, and thus this linking is for data processing. In the example illustrated in FIG. 3, the user A, the user C, and the user B are sorted in this order. Information processing is then performed to link the amount of collection with the amount of use (for example, amount of use subjected to process of conversion into fuel) in the sorted order, that is, in ascending order of the collection start time. For example, assuming that the amount of CO₂ used for conversion into fuel is (30), information processing is performed first to link the amount (20) of collection of CO₂ of the user A whose collection start time is the earliest with the amount of use of CO₂. The remaining amount of use that is not linked is (30−20=10), which is indicated by V′. For V′, information processing is performed to link the amount (15) of collection of CO₂ of the user C whose collection start time is the second earliest after the user A with the amount of use of CO₂. Since the remaining amount V′ of use of CO₂, that is, (10) is less than the amount of collection of CO₂ of the user C, that is, (15), information processing is performed to link the remaining amount V′ of (10) that may be linked out of the amount of collection of CO₂ with the amount of use of CO₂. The database D4210 is then updated with the amount (5) of collection of CO₂ that has not been linked as the amount of collection of CO₂ of the user C. The above processing is repeatedly performed every predetermined time interval. Similar information processing is performed on the amount used for photosynthesis. This linking will be described later in more detail using flow charts.

FIG. 4 is an explanatory diagram of the database F of the information management center according to the first embodiment. The information about the amount of CO₂ collected at the CO₂ collection station 2A, the amount of CO₂ used in the processing plant 4, the date of use, and the intended use, and the information about the total amount of use of CO₂ are stored in the database F5010 for each of the pieces of user identification information.

FIG. 5 is an explanatory diagram of the information communication terminal 12 according to the first embodiment. When a display command is input from a user through the input unit 122 exemplified as buttons displayed on a touch panel, the information about the amount of collection of CO₂, the amount of use of CO₂, and the intended use of CO₂ is output to the output unit 121 as illustrated in FIG. 5.

Control Flow

FIGS. 6A and 6B are control flowcharts performed by the vehicle and the CO₂ collection station according to the first embodiment. While the vehicle 1A and the CO₂ collection station 2A will be described, similar control is executed in other vehicles 1B and 1C and the CO₂ collection station 2B.

FIG. 6A will be described first. At step S1, the CO₂ recovery control unit 101 determines whether or not the CO₂ recovery unit 100 is connected to the CO₂ collection unit 200 of the CO₂ collection station 2A, based on connection information detected by the connection sensor of the CO₂ recovery unit 100. When the CO₂ recovery unit 100 is not connected to the CO₂ collection unit 200 (step S1: No), the control flow ends. When the CO₂ recovery unit 100 is connected to the CO₂ collection unit 200 (step S1: Yes), the control unit 110 causes the communication unit 120 to transmit identification information of the user of the CO₂ recovery device 10 stored in the database A1110 of the storage unit 111 to the CO₂ collection station 2A (step S2), and the process proceeds to step S3.

At step S3, the control unit 110 starts counting a timer value from the time of the transmission at step S2, and the process proceeds to step S4.

At step S4, the control unit 110 determines whether or not a reception completion notification and a CO₂ discharge control start request have been received from the CO₂ collection station 2A via the communication unit 120. When the reception completion notification and the CO₂ discharge control start request have not been received (step S4: No), the process proceeds to step S5.

At step S5, the control unit 110 determines whether or not the counted timer value is more than or equal to a predetermined value. When the timer value is less than the predetermined value (step S5: No), the process returns to step S4. If the timer value is more than or equal to the predetermined value (step S5: Yes), the process returns to step S2.

At step S4, when the reception completion notification and the CO₂ discharge control start request are received (step S4: Yes), the CO₂ recovery control unit 101 causes the CO₂ recovery unit 100 to discharge CO₂ from the CO₂ tank 102 into the CO₂ collection unit 200 of the CO₂ collection station 2A (step S6), and the process proceeds to step S7.

At step S7, the CO₂ recovery control unit 101 determines whether or not discharging from the CO₂ tank 102 has been completed, based on remaining amount information detected by the storage amount sensor of the CO₂ tank 102. When discharging has not been completed (step S7: No), step S7 is repeated until discharging is completed. When discharging has been completed (step S7: Yes), the CO₂ recovery control unit 101 causes the communication unit 120 to transmit a CO₂ discharge completion notification to the CO₂ collection station 2A (step S8), and the process proceeds to step S9.

At step S9, the control unit 110 resets the counted timer value and ends the control flow.

Next, FIG. 6B will be described. At step S101, the control unit 212 determines whether or not user identification information has been received from the vehicle 1A every time a predetermined time elapses. When the identification information has not been received (step S101; No), the control flow ends. When the identification information has been received (step S101), the control unit 212 transmits a reception completion notification and a CO₂ discharge control start request to the vehicle 1A (step S102), and the process proceeds to step S103.

At step S103, the control unit 212 starts counting a timer value from the time of the transmission at step S102, the CO₂ collection control unit 201 starts CO₂ collection control, and the process proceeds to step S104.

At step S104, the control unit 212 determines whether or not a CO₂ discharge completion notification has been received from vehicle 1A. When the CO₂ discharge completion notification has not been received (step S104: No), it is determined whether or not the timer value is more than or equal to a predetermined value (step S105).

When the timer value is less than the predetermined value at step S105 (step S105: No), the process returns to step S104. When the timer value is more than or equal to the predetermined value (step S105: Yes), the control unit 212 notifies an error notification to a manager of the CO₂ collection station 2A or the like via the communication unit 210 (step S106), and the process proceeds to step S108.

At step S104, when the CO₂ discharge completion notification is received (step S104: Yes), the process proceeds to step S107.

At step S107, the CO₂ collection control unit 201 ends the CO₂ collection control, and the control unit 212 performs information processing to link the user identification information received from the vehicle 1A with the amount of collection of CO₂ and the collection start time, stores the linked information in the database B2110 of the storage unit 211, and the process proceeds to step S108.

At step S108, the control unit 212 resets the counted timer value and ends the control flow.

FIGS. 7A and 7B are control flowcharts performed by the CO₂ collection station and the transportation vehicle according to the first embodiment, respectively. FIG. 7A is a control flowchart performed by the CO₂ collection station, and FIG. 7B is a control flowchart performed by the transportation vehicle.

FIG. 7A will be described first. At step S201, the CO₂ collection control unit 201 determines whether or not the CO₂ collection unit 200 is connected to the CO₂ collection unit 300 of the transportation vehicle 3, based on connection information detected by the connection sensor of the CO₂ collection unit 200. When the CO₂ collection unit 200 is not connected to the CO₂ collection unit 300 (step S201: No), the control flow ends. When the CO₂ collection unit 200 is connected to the CO₂ collection unit 300 (step S201: Yes), the process proceeds to step S202.

At step S202, the CO₂ collection control unit 201 starts control to discharge CO₂ into the CO₂ tank 202, and the process proceeds to step S203.

At step S203, the CO₂ collection control unit 201 determines whether or not discharging of CO₂ has been completed based on the remaining amount of the CO₂ tank. When discharging has not been completed (step S203: No), step S203 is repeated until discharging is completed. When discharging has been completed (step S203: Yes), the control unit 212 causes the communication unit 210 to transmit a CO₂ discharge completion notification and the information stored in the database B2110 (information in which user identification information, amount of collection of CO₂, and collection start time are linked with each other) to the transportation vehicle 3 (step S204), and the control flow ends.

Next, FIG. 7B will be described. At step S301, the control unit 312 determines whether or not the CO₂ discharge completion notification and the information in the database B2110 have been received from the CO₂ collection station 2A via the communication unit 310 every time a predetermined time elapses. When the completion notification and the information have not been received (step S301: No), the control flow ends. When the completion notification and the information have been received (step S301: Yes), the control unit 312 stores the received information in the database C3110 of the storage unit 311 (step S302), and the control flow ends.

FIGS. 8A and 8B are control flowcharts performed by the transportation vehicle and the processing plant according to the first embodiment, respectively. FIG. 8A is a control flowchart performed by the transportation vehicle, and FIG. 8B is a control flowchart executed by the processing plant. While FIG. 8B describes a case of use for a process of conversion into fuel, similar control is executed in a case of use for photosynthesis.

FIG. 8A will be described first. At step S401, the CO₂ collection control unit 301 determines whether or not the CO₂ collection unit 300 is connected to the CO₂ collection unit 410 of the processing plant 4, based on connection information detected by the connection sensor of the CO₂ collection unit 300. When the CO₂ collection unit 300 is not connected to the CO₂ collection unit 410 (step S401: No), the control flow ends. When the CO₂ collection unit 300 is connected to the CO₂ collection unit 410 (step S401: Yes), the CO₂ collection unit 300 starts CO₂ discharge control (step S402), and the process proceeds to step S403.

At step S403, the CO₂ collection control unit 301 determines whether or not discharging of CO₂ has been completed, based on remaining amount information detected by the storage amount sensor of the CO₂ tank 302. When discharging has not been completed (step S403: No), step S403 is repeated until discharging is completed. When discharging has been completed (step S403: Yes), the control unit 312 causes the communication unit 420 to transmit a discharge completion notification and information in the database C3110 (information in which user identification information, amount of collection of CO₂, and collection start time are linked with each other) to the processing plant 4 (step S404), and the control flow ends.

Next, FIG. 8B will be described. At step S501, the control unit 423 determines whether or not the CO₂ discharge completion notification and the information in the database C3110 have been received from the transportation vehicle 3 every time a predetermined time elapses. When the discharge completion notification and the information have not been received (step S501: No), the process proceeds to step S503. When the completion notification and the information have been received (step S501: Yes), the processor 422 updates the information in the database D4210 using the information received (step S502), and the process proceeds to step S503.

At step S503, the control unit 423 determines whether or not CO₂ in the CO₂ tank 412 has been used for conversion into fuel in the CO₂ processing device 40, based on a change in the amount of CO₂ in the CO₂ tank 412, the change being detected by the storage amount sensor. When CO₂ has not been used for conversion into fuel (step S503: No), the control flow ends. When CO₂ has been used for conversion into fuel (step S503: Yes), the processor 422 calculates the amount of CO₂ used for conversion into fuel (amount of use of CO₂) V (step S504), and the process proceeds to step S505.

At step S505, the processor 422 performs information processing to link the user identification information and the information about the amount of collection of CO₂ among the information received from the transportation vehicle 3 and stored in the database D4210 with the intended use of CO₂ (conversion into fuel) and the amount of CO₂ used for conversion into fuel and to store the linked information in the database E4211, and the control flow ends.

FIG. 9 is a control flowchart of information processing performed by the processing plant 4 according to the first embodiment.

At step S601, the processor 422 sorts the information in the database D4210 in ascending order of the CO₂ collection start time, and the process proceeds to step S602.

At step S602, the processor 422 extracts identification information of a user whose CO₂ collection start time is the earliest and an amount S of collection of CO₂ of the user from the database D4210, and the process proceeds to step S603.

At step S603, the processor 422 determines whether or not a previous remaining processing amount V′old (amount of use not linked with amount of collection) is stored in the storage unit 421. When V′old is not stored (step S603: No), the process proceeds to step S605. When V′old is stored (step S603: Yes), the processor 422 performs a correction to add the previous remaining processing amount V′old to the amount of CO₂ used for conversion into fuel, which has been calculated at step S504, and deletes the information about the previous remaining processing amount V′old from the storage unit 421 (step S604), and the process proceeds to step S605.

At step S605, the processor 422 determines whether or not a difference V′ (=V−S) between the amount V of CO₂ used for conversion into fuel, the amount V beings calculated by the processor 422, or the amount V of use of CO₂ corrected at step S604 and the amount S of collection of CO₂ of the user, the amount S being extracted at step S602, is more than or equal to 0. When V′ is less than 0, that is, when the amount S of collection of CO₂ is more than the amount V of use of CO₂ (step S605: No), the process proceeds to step S609. When V′ is more than or equal to 0, that is, when the amount S of collection of CO₂ is less than the amount V of use of CO₂ (step S605: Yes), the processor 422 performs a process corresponding to the determination that all the amount S of collection of CO₂ of the user is used. That is, the user identification information, the amount S of collection of CO₂, and the amount V used for conversion into fuel are linked with each other and stored in the database E4211 (step S606). Thereafter, the control process proceeds to step S607.

At step S607, the information about the user stored in the database D4210, which has been linked, is deleted. Thereafter, the control process proceeds to step S608.

At step S608, the processor 422 stores the difference V′ as V′old in the storage unit 421, and the process returns to step S602.

At step S609, the processor 422 performs a process corresponding to the determination that, out of the amount S of collection of CO₂, the amount V of CO₂ to be converted into fuel has been converted into fuel. That is, the user identification information, the amount S of collection of CO₂, and the amount V of CO₂ used for conversion into fuel are linked with each other and stored in the database E4211, and the process proceeds to step S610.

At step S610, the database D4210 is updated by changing the amount S of collection of CO₂ of the user stored in the database D4210 to the absolute value of the difference V′ (amount of collection of CO₂ that has not been used for conversion into fuel), the process proceeds to step S611.

At step S611, the processor 422 stores the amount of difference V′old as 0 in the storage unit 421, and the control flow ends.

As described above, the information processing is performed to link the amount of collection of CO₂ with the amount of use of CO₂ in an order from the user whose CO₂ collection start time is the earliest in the CO₂ collection device.

The control flowchart of FIG. 9 will be specifically described with reference to FIG. 3.

The processor 422 sorts the information in the database D4210 in ascending order of the CO₂ collection start time as in the table on the upper right side of FIG. 3 (step S601).

Next, the identification information of the user A whose CO₂ collection start time is the earliest and the amount (20) of collection of CO₂ are extracted (step S602).

Next, at step S603, the control unit 423 determines that the previous remaining processing amount V′old is not stored (it is assumed that V′old is not stored).

Next, the processor 422 calculates the difference V′ (=30−20) between the amount (30) of use of CO₂ and the amount (20) of collection of CO₂ of the user A, determines that V′ is more than or equal to 0 (Step S605), links the identification information of the user A, the amount (20) of use of CO₂, the amount (20) of collection of CO₂, and intended use information indicating conversion into fuel with each other, and stores the linked information in the database E4211 (step S606).

Next, the processor 422 deletes the information about the user A from the database D4210 as illustrated in the table on the middle right side of FIG. 3 (step S607).

Next, the processor 422 stores the difference V′ (10) calculated at step S605 as V′old in the storage unit 421 (step S608).

Next, the control process returns to step S602, and the processor 422 extracts the identification information of the user C whose collection start time is the second earliest after the user A and the amount (15) of collection of CO₂.

Next, since the previous remaining processing amount V′old is determined as (10) at step S603 and stored at step S608, the processor 422 performs a correction to add the previous remaining processing amount V′old to the amount V of use of CO₂ (Step S604). Here, it is assumed that the amount of use of CO₂ for new conversion into fuel is 0, and thus the corrected amount V of use of CO₂ is the previous remaining processing amount V′old (10).

Next, the processor 422 calculates the difference V′ (=10−15=−5) between the corrected amount (10) of use of CO₂ and the amount (15) of collection of CO₂ of the user C, determines that V′ is less than 0 (Step S605), links the identification information of the user C, the amount (10) of use of CO₂, the amount (15) of collection of CO₂, and the intended use information indicating conversion into fuel with each other, and stores the linked information in the database E4211 (step S609).

Next, the processor 422 updates the information stored in the database D4210 by storing the absolute value (5) of the difference V′ calculated at step S605 described above (out of amount of collection of CO₂ of user C, amount not used for conversion into fuel) as the amount of CO₂ of the user C (step S610).

Next, the processor 422 stores the remaining processing amount V′old as 0 in the storage unit 421 (step S611), and the control flow ends.

As described above, the extraction process and the linking process are repeatedly performed in ascending order of the CO₂ collection start time.

FIGS. 10A and 10B are control flowcharts performed by the processing plant and the information management center according to the first embodiment, respectively. FIG. 10A is a control flowchart performed by the processing plant 4, and FIG. 10B is a control flowchart performed by the information management center.

FIG. 10A will be described first. At step S701, the control unit 423 determines whether or not there is information stored in the database E4211. When there is no information (step S701: No), the control flow ends. When there is information (step S701: Yes), the process proceeds to step S702.

At step S702, the control unit 423 causes the communication unit 420 to transmit the information in the database E4211 to the information management center 5, and the process proceeds to step S703.

At step S703, the control unit 423 starts counting a timer value from the time of the transmission at step S702, and the process proceeds to step S704.

At step S704, the control unit 423 determines whether or not a reception completion notification has been received from the information management center 5. When the notification has not been received (step S704: No), the process proceeds to step S707. When the notification has been received (step S704: Yes), the control unit 423 causes the processor 422 to delete the transmitted information from the database E4211 (step S705), and the process proceeds to step S706.

At step S706, the control unit 423 resets the timer value, and the control flow ends.

At step S707, the control unit 423 determines whether or not the counted timer value is more than a predetermined value. When the timer value is less than or equal to the predetermined value (step S707: No), the process proceeds to step S704. When the timer value is more than the predetermined value (step S707: Yes), the process returns to step S702.

Next, FIG. 10B will be described. At step S801, the control unit 503 determines whether the information in the database E4211 has been received from the processing plant 4. When the information has not been received (step S801: No), the control flow ends. When the information has been received (step S801: Yes), the process proceeds to step S802.

At step S802, the processor 502 determines whether or not the received information is already stored and the received information is about a user already registered in the database F5010. When the received information is already registered, based on the received information, the information about the intended use of CO₂ (conversion into fuel) and the information about the amount of use of CO₂, these pieces of information being collected from the user, are updated (step S803), and the process proceeds to step S805. When the received information is not stored, the received information is newly added to the database F5010 (step S804), and the process proceeds to step S805.

At step S805, the processor 502 determines whether the process of updating or adding all the received information has been completed. When the process has not been completed (step S805: No), the process returns to step S802. When the process has been completed (step S805: Yes), the process proceeds to step S806.

At step S806, the control unit 503 causes the communication unit 500 to transmit a reception completion notification to the processing plant 4, and the control flow ends.

FIGS. 11A and 11B are control flowcharts performed by the vehicle and the information management center according to the first embodiment, respectively. FIG. 11A is a control flowchart performed by the vehicle 1A, and FIG. 11B is a control flowchart performed by the information management center 5. The control flowchart performed by the vehicle 1A illustrated in FIG. 11A will be described first. Similar control is executed in other vehicles 1B and 1C.

At step S901, the control unit 110 causes the communication unit 120 to transmit a request to update information about the amount of use and intended use of CO₂ to the information management center 5 every time a predetermined time elapses, and the process proceeds to step S902.

At step S902, the control unit 110 starts counting a timer value from the time of the transmission at step S901, and the process proceeds to step S903.

At step S903, the control unit 110 determines whether or not update information has been received via the communication unit 120. When the update information has not been received (step S903: No), the control unit 110 determines whether or not the timer value is more than a predetermined value (step S905). When the timer value is less than or equal to the predetermined value (step S905: No), the process returns to step S903, and when the timer value is more than the predetermined value (step S905: Yes), the process returns to step S901.

When the update information is received at step S903 (step S903: Yes), the control unit 110 updates the information in the database A1110 based on the received information (step S904), and then the control unit 110 resets the timer value (step S906), and the process proceeds to step S907.

At step S907, control unit 110 causes the information communication terminal 12 to display the resultant information on a screen based on a user's request, and ends the control flow. A specific control flow of displaying the information on the screen will be described with reference to FIG. 12.

Next, a control flowchart performed by the information management center 5 illustrated in FIG. 11B will be described.

At step S911, the control unit 503 determines whether or not the update request has been received from the vehicle 1A via the communication unit 500. When the update request has not been received (step S911: No), the control flow ends. When the update request has been received (step S911: Yes), the control unit 503 causes the communication unit 500 to transmit the information in the database F5010 to the vehicle 1A (step S912), and the control flow ends.

FIG. 12 is a control flowchart performed by the information communication terminal according to the first embodiment.

At step S908, the terminal control unit 123 determines whether or not a request to display information about the amount of use and intended use of CO₂ has been input from a user of the CO₂ recovery device 10 through the input unit 122. When the display request has not been input (step S908: No), the control flow ends. When the display request has been input (step S908: Yes), the terminal control unit 123 causes the output unit 121 to display the information about the amount of use and intended use of CO₂, the information being stored in the storage unit 111, (step S909), and the control flow ends.

In this way, with respect to CO₂ that is recovered by the CO₂ recovery device 10 of the vehicles 1A, 1B, and 1C and collected at the CO₂ collection stations 2A and 2B, the identification information of the user of the CO₂ recovery device 10, the amount of recovery of CO₂, and the information about the intended use and amount of use of CO₂ may be managed between the vehicles 1A, 1B, and 1C, the CO₂ collection stations 2A and 2B, the transportation vehicle 3, the processing plant 4, and the information management center 5. Furthermore, since the user of the CO₂ recovery device 10 may check the information indicating the intended use of CO₂ collected, the user is aware of CO₂ recovery and social contribution, which raises user's motivation, and as a result of that, the CO₂ recovery may be promoted. In addition, as information processing is performed to link the amount of collection of CO₂ with the amount of use of CO₂ in an order from the user whose CO₂ collection start time in the CO₂ collection device 20 is the earliest, the earlier CO₂ is collected, the earlier CO₂ is used, and the user is aware of early recovery of CO₂ to be highly motivated. Further, since information may be updated or added to the database or the like, the user may recognize the latest information about the intended use and amount of use of CO₂. Moreover, a new user may be easily added to the information management system 1000, and may recognize the intended use information. In addition, new intended use may be easily added to the information management system 1000.

While the vehicles 1A, 1B, and 1C include the CO₂ recovery device 10 in the first embodiment described above, the CO₂ recovery device 10 may be provided in other structures that emit CO₂. For example, the CO₂ recovery device 10 may be provided in a house such as a detached house or a condominium, a public facility, or a building such as a factory.

While the user is, for example, the owner of the vehicle 1A including the CO₂ recovery device 10 in the first embodiment described above, in a case where the vehicle 1A is a vehicle used for services such as car rental and car sharing, the user may be a user of the service or a service provider. When the user is a service user, the intended use information may be shared when a plurality of different vehicles is used. When the user is a service provider, the intended use information may be shared with vehicles. When the CO₂ recovery device 10 is provided in a rental building, the user may be the owner or the borrower.

While the processing plant 4 has a plurality of intended uses such as the use of CO₂ for conversion into fuel and the use of CO₂ for photosynthesis of plants in the first embodiment described above, each processing plant has a single intended use like a plant dedicated for conversion into fuel. When CO₂ collected from the CO₂ recovery device 10 of a certain user is used in a different processing plant (CO₂ using facility), user identification information and intended use information are transmitted from each processing plant to the information management center 5, and managed collectively. In addition, the intended use of CO₂ in the CO₂ using facility is not limited to conversion into fuel and photosynthesis, and for example, the use of CO₂ for generating carbon dioxide gas may be included.

Further, while CO₂ is transported from the CO₂ collection stations 2A and 2B to the processing plant 4 by the transportation vehicle 3 in the first embodiment described above, CO₂ may be transported by other transportation such as a ship or a railroad, or may be transported by a pipeline or the like. When the pipeline is used, for example, information is directly transmitted from the CO₂ collection stations 2A and 2B to the processing plant 4 via the communication network 6.

Moreover, whether or not CO₂ has been actually used for conversion into fuel is determined and then the amount V of CO₂ converted into fuel is calculated, and the information processing is performed to link the amount of collection of CO₂ with the amount of use of CO₂ in the first embodiment described above, but a virtual amount V of CO₂ used for conversion into fuel may be set before CO₂ is used, and then the information processing of linking may be performed.

Further, in the first embodiment described above, while the linked information is sorted in ascending order of the collection start time in the database D4210, the sorting does not need to be performed, and the information with the earliest collection start time among the linked information may be extracted.

Furthermore, while the information communication terminal 12 displays intended use information in a table format in the first embodiment described above, the intended use information may be displayed in a graph format such as a pie graph or a bar graph. In addition, the processing plant 4 may transmit its own positional information to the information management center 5, and the information communication terminal 12 may display in which area CO₂ is used. The information to be displayed and the display format may be switched by an operation of the input unit 122.

According to the present disclosure, it is possible to inform a user who uses a CO₂ recovery device of information such as the intended use and amount of use of CO₂ recovered from the CO₂ recovery device.

Although the disclosure has been described with respect to specific embodiments for a complete and clear disclosure, the appended claims are not to be thus limited but are to be construed as embodying all modifications and alternative constructions that may occur to one skilled in the art that fairly fall within the basic teaching herein set forth.

Claims

1. An information management device comprising:

a receiver configured to receive intended use information indicating at least one of: intended use of CO2 in a processing device configured to process CO2 recovered by a CO2 recovery device configured to recover CO2; and an amount of use for the intended use; and positional information of the processing device; and

a controller configured to control the information management device, wherein

when the receiver receives the intended use information, the controller is configured to control the information management device to transmit information including the intended use information to an information communication terminal used by a user who has used the CO2 recovery device, or control the information communication terminal to output the information including the intended use information, and

when the receiver does not receive the intended use information, the controller is configured to control the information management device not to transmit the information including the intended use information, or control the information communication terminal not to output the information including the intended use information.

2. The information management device according to claim 1, wherein the information including the intended use information further includes identification information of the user.

3. The information management device according to claim 2, wherein the controller is configured to perform a process to link the intended use information with the identification information of the user.

4. The information management device according to claim 1, wherein the intended use information includes information in which an amount of collection of CO2 is linked with an amount of use of in an ascending order of a CO2 collection start time when CO2 starts to be collected from the CO2 recovery device.

5. An information communication terminal comprising: a receiver configured to receive information

including intended use information indicating at least one of: intended use of CO2 in a processing device configured to process CO2 recovered by a CO2 recovery device configured to recover CO2; and an amount of use for the intended use; and positional information of the processing device; and

an output unit configured to output the intended use information.

6. The information communication terminal according to claim 5, wherein the information including the intended use information further includes identification information of a user who has used the CO2 recovery device.

7. The information communication terminal according to claim 6, wherein the output unit is configured to output the intended use information and the identification information.

8. The information communication terminal according to claim 5, wherein the intended use information includes information in which an amount of collection of CO2 is linked with an amount of use of in an ascending order of a CO2 collection start time when CO2 starts to be collected from the CO2 recovery device.