JP6524235B2 - Hydrogen supply management device and hydrogen supply management method - Google Patents

Description

  Embodiments of the present invention relate to a hydrogen supply management device and a hydrogen supply management method.

  In recent years, hydrogen energy has been attracting attention as one of the next-generation energy, and attempts have been made to put into practice the operation of the hydrogen supply chain from the production of hydrogen to transportation and utilization.

"NEDO Hydrogen Energy White Paper", Chapter 6, Fig. 6-1, etc., [online], March 20, 2015, NEDO, [August 6, 2015 Search], Internet <URL: http: // www.nedo.go.jp/content/100639759.pdf>

  In the operation of the hydrogen supply chain, it is desirable to construct a mechanism by which an operator can easily grasp the relationship between the hydrogen supply and demand between the hydrogen production facilities and the hydrogen demand facilities scattered in various places. However, no effective technology has been proposed at present.

  The problem to be solved by the present invention is a hydrogen supply management device and a hydrogen supply management method which make it possible to easily grasp the relationship between the demand and supply of hydrogen between each hydrogen production facility and each hydrogen demand facility. It is to provide.

The hydrogen supply management device according to the embodiment includes at least one hydrogen production facility for producing hydrogen from water or hydrocarbon, at least one transport vehicle for transporting hydrogen produced by the hydrogen production facility, and the transport vehicle Supply management apparatus applied to a system including at least one hydrogen demand facility utilizing the hydrogen to be produced, wherein the expected production amount of hydrogen produced by each hydrogen production facility on the next day, and each hydrogen demand facility on the next day An estimated production amount of hydrogen produced by each hydrogen production facility of the next day using at least the computing means for computing the expected usage of hydrogen to be used and the computation result of the computing means, and each hydrogen demand facility of the next day Display control means for displaying on the screen of the display device the expected usage of hydrogen that is used and information indicating the transport route of hydrogen connecting each hydrogen production facility and each hydrogen demand facility Comprising a.

FIG. 1 is a view showing a schematic configuration of a hydrogen supply system according to an embodiment. FIG. 2 is a view showing an example of a display screen displayed on the display device by the display control device in the hydrogen supply management device.

  Embodiments will be described below with reference to the drawings.

[Configuration of hydrogen supply system]
FIG. 1 is a view showing a schematic configuration of a hydrogen supply system according to an embodiment.

  The hydrogen supply system according to the present embodiment realizes operation of a hydrogen supply chain from production of hydrogen to storage, transportation, and utilization in a certain area, and at least one hydrogen production as a main component A facility 10, a transport system 20 comprising at least one transport vehicle, at least one hydrogen demand facility 30, and a hydrogen supply management device 40 are included. Here, the case where there are a plurality of hydrogen production facilities 10 and a plurality of hydrogen demand facilities 30, respectively, and the transport system 20 has a plurality of transport vehicles will be illustrated. However, it is not limited to this example.

  The hydrogen production facility 10 is a facility that generates electric power using renewable energy such as water power, wind power, solar light, and the like, and uses the electric power generated by the power generation to produce hydrogen from water or hydrocarbon. The hydrogen production equipment 10 is disposed so as to be scattered in a mountainous area, a seaside, or the like.

  The transport system 20 includes transport vehicles 1, 2, 3, ... for transporting the hydrogen produced by the hydrogen production facility 10 to the hydrogen demand facility 30. The transport vehicles 1, 2, 3,... Are, for example, trailers or vehicles which can transport containers storing hydrogen, tanks and the like.

  The hydrogen demand facility 30 receives hydrogen transported by the transport vehicles 1, 2, 3,... Of the transport system 20, generates electricity and heat from the hydrogen by the fuel cell device, and utilizes the generated electricity and heat. It is an equipment. For example, facilities of a heated pool, facilities of a dairy farmer, a fuel cell car, etc. may be mentioned.

  The hydrogen supply management device 40 integrally manages the hydrogen supply chain in the hydrogen supply system by controlling the hydrogen production facility 10, the transport system 20, and the hydrogen demand facility 30, respectively.

[Configuration of Individual Hydrogen Production Equipment 10]
The hydrogen production facility 10 includes a power generation device 11, a hydrogen production device 12, a data collection device 13, a communication device 14, and a control device 15 as main components. In addition, a hydrogen storage device, a storage battery, etc. not shown are also provided.

  The power generation device 11 corresponds to a hydroelectric power generation device, a wind power generation device, or a solar power generation device, and generates electric power using renewable energy. A part or all of the power generation apparatus 11 may be provided outside the hydrogen production facility 10.

The hydrogen production apparatus 12 produces hydrogen by electrolyzing, for example, water supplied from a separately provided water storage tank using the power generated by the power generation apparatus 11. The hydrogen production apparatus 12 is equipped with meters (not shown) for measuring the flow rate [Nm ³ / h], volume [Nm ³ ], purity [%], pressure [kPa], etc. of hydrogen produced. Be The produced hydrogen is transported to any hydrogen demand facility 30 by any transport vehicle of the transport system 20 after being stored in a hydrogen storage device (not shown).

  The data collection device 13 collects data such as the flow rate, volume, purity, pressure and the like of hydrogen measured by the instruments on the hydrogen production device 12 every day or at regular intervals.

  The communication device 14 performs wireless communication with the communication device 44 on the hydrogen supply management device 40 side. For example, the communication device 14 has a function of transmitting various data required by the hydrogen supply management device 40 to the hydrogen supply management device 40, and receiving a command transmitted from the hydrogen supply management device 40. There is.

  The controller 15 is responsible for the operation of the entire hydrogen production facility 10. For example, the control device 15 controls the storage amount of electric power generated by the power generation device 11, controls the production amount of hydrogen in the hydrogen production device 12, the storage amount of hydrogen, etc. Data such as flow, capacity, purity and pressure of hydrogen are sent to the hydrogen supply management device 40 via the communication device 14 every day or every fixed time, or a command sent from the hydrogen supply management device 40 It acquires via the communication device 14 and carries out processing according to the command.

[Configuration of transportation system 20]
The transport system 20 (or transport vehicles 1, 2, 3,...) Is also provided with a communication device and a control device not shown.

  The communication device of the transportation system 20 performs wireless communication with the communication device 44 on the hydrogen supply management device 40 side. For example, the communication device 14 has a function of transmitting various data required by the hydrogen supply management device 40 to the hydrogen supply management device 40, and receiving a command transmitted from the hydrogen supply management device 40. There is.

  The control device of the transport system 20 is responsible for the operation of the entire transport system 20. For example, the control device of the transport system 20 includes various information for each transport vehicle (identification information indicating the hydrogen production facility 10 of the hydrogen supply source, identification information indicating the hydrogen demand facility 30 of the hydrogen supply destination, the amount of transported hydrogen, The travel distance, etc.) is sent to the hydrogen supply management device 40 via the communication device every day or every fixed time, or the command transmitted from the hydrogen supply management device 40 is obtained via the communication device, Carry out processing according to the command.

[Composition of each hydrogen demand facility 30]
The hydrogen demand facility 30 includes a fuel cell device 31, a load 32, a data collection device 33, a communication device 34, and a control device 35 as main components.

The fuel cell device 31 generates electricity using the hydrogen transported from any transport vehicle of the transport system 20 to generate power and heat. The fuel cell apparatus 31 is equipped with meters (not shown) for measuring the flow rate of hydrogen to be used [Nm ³ / h], the volume [Nm ³ ], the purity [%], the pressure [kPa], etc. Be

  The load 32 corresponds to a power load or heat load that consumes the power or heat generated by the fuel cell device 31. The load 32 is provided with instruments (not shown) that respectively measure the amount of power and heat consumed.

  The data collection device 33 includes data such as flow, capacity, purity, and pressure of hydrogen measured by meters on the fuel cell device 31 side, data such as electric energy and heat amount measured by meters on the load 32 side, Alternatively, data indicating the amount of electricity and heat required by the load 32 is collected on a daily basis or at regular intervals.

  The communication device 34 performs wireless communication with the communication device 44 on the hydrogen supply management device 40 side. For example, the communication device 34 has a function of transmitting various data required by the hydrogen supply management device 40 to the hydrogen supply management device 40, and receiving a command transmitted from the hydrogen supply management device 40. There is.

  The controller 35 is responsible for the operation of the entire hydrogen demand facility 30. For example, the control device 35 controls the operation of the fuel cell device 31, and data such as the flow, capacity, purity, and pressure of hydrogen collected by the data collection device 13, and data such as the amount of consumed power and heat Or data indicating the amount of electricity and heat required by the load 32 is sent to the hydrogen supply management device 40 via the communication device 14 every day or at regular intervals, or from the hydrogen supply management device 40. It has a function of acquiring an incoming command via the communication device 14 and performing processing according to the command.

[Configuration of Hydrogen Supply Management Device 40]
The hydrogen supply management device 40 includes an arithmetic device 41, a display device 42, a display control device 43, a communication device 44, and a control device 45 as main components.

  Arithmetic unit 41 receives individual information obtained through communication unit 44 under the control of control unit 45 (information sent from each hydrogen production facility 10, information sent from transport system 20, each information Various calculations are performed using the information transmitted from the hydrogen demand facility 30 and the weather information transmitted from the weather forecasting agency.

  For example, the computing device 41 indicates at least weather information (atmospheric temperature, humidity, precipitation, wind conditions, solar radiation amount, etc. in a predetermined area) indicating the weather in a certain area, and the demand for electricity or heat in each hydrogen demand facility Using information, it has a function to calculate the predicted amount of hydrogen produced by each hydrogen production facility on the next day and the expected amount of hydrogen used by each hydrogen demand facility on the next day.

  Further, based on the calculation result, the arithmetic unit 41 uses a predetermined algorithm to transport the hydrogen between each hydrogen production facility and each hydrogen demand facility on the next day (hydrogen production from the hydrogen supply source for each transport vehicle). The identification information indicating the equipment 10, the identification information indicating the hydrogen demand equipment 30 to which hydrogen is supplied, and the function of determining the transport amount of hydrogen are further provided. The above algorithm ensures that when determining the transport path of hydrogen, there is no more than a certain amount of unused hydrogen in the entire hydrogen supply chain, and no more than a certain amount of hydrogen shortage. Further, the amount of hydrogen transported by each transport vehicle is made to fall between a predetermined lower limit value and an upper limit value, and the traveling distance of each transport vehicle is made not to exceed a predetermined value.

  The display device 42 is a device capable of screen display and input operation of information, such as a tablet terminal with a touch panel, for example.

  Under the control of the control device 45, the display control device 43 causes the display screen of the display device 42 to display information as shown in FIG. 2, for example.

  For example, the display control device 43 uses at least the calculation result of the calculation device 41 to at least the predicted production amount of hydrogen manufactured by each hydrogen production facility of the next day and the estimated usage amount of hydrogen used by each hydrogen demand facility of the next day And B. are displayed collectively on one screen of the display device 42.

  In addition, the display control device 43 has a function to further display the amount of hydrogen produced by each hydrogen production facility of the present day and the amount of hydrogen used by each hydrogen demand facility of the present day on the screen. There is.

  In addition, the display control device 43 has a function to further display information indicating the type of renewable energy used by each hydrogen production facility on the screen.

  In addition, the display control device 43 causes the screen to display, on the screen, information indicating the transportation route of hydrogen of the present day and / or the next day connecting each hydrogen production facility and each hydrogen demand facility, or the transport route It has a function of displaying on the screen an item which enables setting or changing of

  The communication device 44 performs wireless communication with the communication device 14 on the hydrogen production facility 10 side, the communication device 34 on the hydrogen demand facility 30 side, and the communication device on the transport system 20 side. For example, the communication device 44 transmits information transmitted from the individual hydrogen production equipment 10, information transmitted from the individual hydrogen demand equipment 30, weather information transmitted from the weather forecast agency, and the transportation system 20. It has a function to receive incoming information and to transmit various commands to individual hydrogen production facilities 10, individual hydrogen demand facilities 30, and transport system 20.

  The controller 45 is responsible for the operation of the hydrogen supply management device 40 as a whole. For example, from the individual information received by the communication device 44 using the arithmetic device 41, the control device 45 estimates the amount of hydrogen produced by each hydrogen production facility on the next day and the amount of hydrogen used by each hydrogen demand facility on the next day. Calculate the expected usage amount, determine the transport route of hydrogen the next day using the computation result of the computing device 41, and transmit a command instructing the determined transport route to the transport system 20 via the communication device 44, On the next day when the display control device 43 causes various information based on the calculation result of the calculation device 41 to be displayed collectively on one screen of the display device 42 or the operator sets or changes the items displayed on the display device 42 Command to instruct the transport route of hydrogen to the transport system 20 via the communication device 44, or an instruction on the production amount / supply amount of hydrogen via the communication device 44 Concrete or transmission facility to 10, has a function or to send to individual hydrogen demand equipment 30 via the communication device 44 the command about the amount of hydrogen used.

[Specific example of screen display]
Next, with reference to FIG. 2, an example of a display screen displayed on the display device 42 by the display control device 43 will be described.

  In the example of this display screen, information relating to each hydrogen production facility 10, information relating to each hydrogen demand facility 30, and information indicating a hydrogen transport path connecting each hydrogen production facility 10 and each hydrogen demand facility 30 And are collectively displayed simultaneously in one screen.

Information on each hydrogen production facility 10 is given by name (such as A to F), location (such as ○○ town ◆◆, ○○ town □□ ...), type (eg, wind power, solar power, small hydro power, etc.), rated output (such as Including WW, etc.), today's hydrogen production (eg NNm ³ ), and tomorrow's predicted hydrogen production (eg ○ Nm ³ ).

On the other hand, the information on each hydrogen demand facility 30 is the name (工場 factory, ビ ル building ... etc.), the location (町 ○ town ◆ ◆ ◆, ○ ○ town □ □ ... etc.), rated output (eg ○ ○ W), today Hydrogen use amount (such as N Nm ³ ), and expected hydrogen use amount tomorrow (such as ○ N m ³ ).

  As information indicating the transport route of hydrogen, for example, a path individually connecting each hydrogen production facility and each hydrogen demand facility is displayed, and further, a transport identification number (for example, transport vehicle number) 1 above the path 9 are displayed. Besides displaying the transportation route of today, the transportation route scheduled for the next day may be displayed in different colors. The operator can set or change the displayed transportation route of the day or the transportation route of the next day by performing a drag operation or the like.

  According to the present embodiment, the operator can grasp at a glance the relationship between the demand and supply of hydrogen between each hydrogen production facility and each hydrogen demand facility by browsing the screen displayed as shown in FIG. Can. In that case, not only the relationship between the demand and supply of hydrogen today, but also the relationship between the demand and supply of hydrogen the next day can be grasped together, and changes and trends in the relationship between demand and supply can be grasped. Furthermore, the transport route of hydrogen connecting each hydrogen production facility and each hydrogen demand facility can be grasped together. Therefore, the operator can grasp the operation status of the entire hydrogen supply chain at a glance, and can grasp the operation plan of hydrogen from the next day on at a glance.

  In addition, since the operator can perform setting or change by performing drag operation or the like on the displayed transportation route of today or the transportation route of the next day, the amount of supplied or used hydrogen is expected for some reason. If it is contrary to the above, it is possible to change the hydrogen transportation plan manually.

  The hydrogen production facility 10 may be a facility that produces hydrogen from water or hydrocarbon using a system power.

  Alternatively, the hydrogen produced by the hydrogen production facility 10 may be supplied to the hydrogen demand facility 30 through a hydrogen pipe without using the transport system 20. As described in detail above, according to the embodiment, it is possible to easily grasp the relationship between the demand and supply of hydrogen between each hydrogen production facility and each hydrogen demand facility.

  While certain embodiments of the present invention have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, substitutions, and modifications can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and the gist of the invention, and are included in the invention described in the claims and the equivalent scope thereof.

  10 ... hydrogen production facility, 20 ... transport system, 30 ... hydrogen demand facility, 40 ... hydrogen supply management device.

Claims (6)

At least one hydrogen production facility for producing hydrogen from water or hydrocarbons, at least one transport vehicle for transporting hydrogen produced by the hydrogen production facility, and at least one for utilizing hydrogen transported by the transport vehicle A hydrogen supply management device applied to a system including a hydrogen demand facility, comprising:
Calculating means for calculating an estimated amount of hydrogen produced by each hydrogen production facility on the next day and an expected amount of hydrogen used in each hydrogen demand facility on the next day,
Based on the calculation result of the calculation means, at least an estimated production amount of hydrogen produced by each hydrogen production facility of the next day, an expected usage amount of hydrogen used by each hydrogen demand facility of the next day, each hydrogen production facility and each A hydrogen supply management device comprising: display control means for displaying on a screen of a display device information indicating a hydrogen transport path connecting a hydrogen demand facility. At least one hydrogen production facility for producing hydrogen from water or hydrocarbons, at least one transport vehicle for transporting hydrogen produced by the hydrogen production facility, and at least one for utilizing hydrogen transported by the transport vehicle A hydrogen supply management device applied to a system including a hydrogen demand facility, comprising:
A hydrogen supply characterized by comprising display control means for displaying on a screen of a display device at least the amount of hydrogen produced by each hydrogen production facility and the amount of hydrogen used by each hydrogen demand facility. Management device.   The display control means further displays, on the screen, the amount of hydrogen produced by each hydrogen production facility of the present day and the amount of hydrogen used by each hydrogen demand facility of the present day. The hydrogen supply management device according to Item 1.   The display control means further displays, on the screen, an item which enables setting or changing of a hydrogen transportation route connecting each hydrogen production facility and each hydrogen demand facility. Hydrogen supply management device as described.   The computing means uses at least meteorological information indicating weather in a certain area, and information indicating a demand for electricity or heat in each hydrogen demand facility, and an estimated amount of hydrogen produced by each hydrogen production facility on the next day, The hydrogen supply management device according to claim 1, wherein the hydrogen consumption management device calculates the expected usage amount of hydrogen used by each hydrogen demand facility on the next day. At least one hydrogen production facility for producing hydrogen from water or hydrocarbons, at least one transport vehicle for transporting hydrogen produced by the hydrogen production facility, and at least one for utilizing hydrogen transported by the transport vehicle A hydrogen supply management method applied to a system including a hydrogen demand facility, comprising:
The computing means computes the predicted amount of hydrogen produced by each hydrogen production facility on the next day and the expected amount of hydrogen used by each hydrogen demand facility on the next day,
The display control means uses the calculation result of the calculation means to at least the predicted production amount of hydrogen produced by each hydrogen production facility of the next day, the predicted usage amount of hydrogen used by each hydrogen demand facility of the next day, and A hydrogen supply management method, comprising: displaying on a screen of a display device information indicating a hydrogen transport route connecting a hydrogen production facility and each hydrogen demand facility.

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