The present application claims the priority based on Japanese Patent Application No. 2018-175597 filed on Sep. 20, 2018, the disclosure of which is hereby incorporated by reference in its entirety.
The present disclosure relates to a community system that uses hydrogen and a construction method of constructing the community system.
Japanese Patent Application Publication No. 2013-74760 discloses a community system that supplies a house group with electric power using a fuel cell.
Meanwhile, a community system allowing efficient use of the facility that uses hydrogen has conventionally been desired.
According to one aspect of the present disclosure, a community system that uses hydrogen is provided. The community system comprises: a hydrogen source; a hydrogen storage storing hydrogen supplied from the hydrogen source; an FC power generating facility with a fuel cell that generates electric power using hydrogen supplied from at least one of the hydrogen source and the hydrogen storage; and multiple house groups each of which includes multiple houses that use electric power supplied from the FC power generating facility and hydrogen supplied from at least one of the hydrogen source and the hydrogen storage. The FC power generating facility is located at a position facing all of the multiple house groups, or a position facing all of the multiple house groups and a planned site where a new house group is to be built.
The FC power generating facility 100 includes a fuel cell system 110 and a secondary cell 120. The FC power generating facility 100 generates electric power with the fuel cell system 110 using hydrogen and supplies the generated electric power to the outside. Further, the FC power generating facility 100 accumulates redundant electric power in the secondary cell 120. The fuel cell system 110 is also simply called a “fuel cell.”
Each of the four house groups 200a to 200d shown in
The following appliances are applicable as the hydrogen using facility 214, for example.
(1) A kitchen appliance that uses hydrogen gas.
(2) A hydrogen suction appliance used by a human for suction of hydrogen gas.
(3) A hydrogen water using appliance that uses hydrogen water.
The kitchen appliance that uses hydrogen may be a hydrogen grill for cooking using hydrogen gas or a refrigerator in which the freshness of vegetables is maintained with hydrogen gas supplied to a vegetable compartment, for example. The hydrogen grill is a cooking appliance for roasting food materials by combusting hydrogen gas. By the use of the hydrogen grill, steam wraps around food materials to roast the food materials with the steam. As a result, the food materials are roasted with heat quickly to allow cooking of the food materials without letting moisture or flavors in the food materials get away. By doing so, it becomes possible to maintain the textures or flavors of the food materials as they are. The refrigerator that uses hydrogen gas makes use of the properties of hydrogen of achieving an anti-oxidation effect that reduces active oxygen when hydrogen is used in the form of hydrogen gas. More specifically, the oxidation of vegetables is suppressed to maintain freshness by spraying hydrogen gas on the vegetables.
The hydrogen suction appliance used by a human for suction of hydrogen gas also makes use of the anti-oxidation effect of hydrogen. More specifically, when hydrogen gas is sucked into a human, active oxygen in the body of the human is reduced. Active oxygen is known to have a strong oxidizing effect that oxidizes and damages DNA, causing arterial sclerosis, muscle weakness, or aging. Suction of hydrogen gas into a human allows reduction in the occurrences of such types of degradation.
The hydrogen water using appliance that uses hydrogen water may be a hydrogen water dispenser for generation and supply of hydrogen water for drinking, a hydrogen bath, or a refrigerator in which the freshness of vegetables is maintained with hydrogen water supplied to a vegetable compartment, for example. These hydrogen water using appliances also make use of the anti-oxidation effect of hydrogen.
When hydrogen is supplied to the house group 200 in the form of liquid hydrogen, the hydrogen using facility 214 may be an air conditioner or a refrigerator using the latent heat of liquid hydrogen. More specifically, liquid hydrogen absorbs a large amount of latent heat when it is vaporized. Using this latent heat allows cooling of a coolant in an air conditioner or a refrigerator. This achieves efficient use of the latent heat of liquid hydrogen.
As described above, the hydrogen using facility 214 is installable in various forms on the house 210 to allow use of hydrogen in various forms. Further, the provision of the facilities 212 and 214 that use hydrogen in the house group 200 allows contribution to carbon reduction through use of hydrogen.
Each house 210 in the house group 200 is connected to the hydrogen tank 220 provided to that house group 200 through a pipeline 240, and receives supply of hydrogen through the pipeline 240. The pipeline 240 connects the multiple house groups 200 to each other, and connects each house group 200 and the FC power generating facility 100 to each other. For electric power supply, each house group 200 and the FC power generating facility 100 are connected to each other through a power transmission line 260.
Hydrogen may pass through the pipeline 240 in various forms such as hydrogen gas, liquid hydrogen, methane produced from hydrogen gas, and methyicyclohexane (MCH). These types of gas or liquid all function as fuel containing hydrogen and will be called “hydrogen-containing fuel” accordingly. In this specification, the term “hydrogen” is also used as a term meaning the hydrogen-containing fuel. The pipeline 240 is generally feasible as piping for passage of the hydrogen-containing fuel. Using methane as the hydrogen-containing fuel allows piping for city gas to be used as the pipeline 240, making it possible to construct the pipeline 240 easily. While not shown in the drawings, the pipeline 240 is provided with various types of units prepared according to demand such as a valve, a pump, a compressor, a pressure accumulator, a converter for the hydrogen-containing fuel, a pressure gage, a thermometer, and a flow meter, for example.
The multiple solar panels 250 installed on the house group 200 include a power generating unit that generates electric power using sunlight, and a hydrogen producing unit that produces hydrogen via electrolysis of water using the electric power generated by the power generating unit. The electric power generated by the solar panels 250 may be consumed by electrical appliances in the house group 200, or may be accumulated in the secondary cell 230 in the house group 200 or the secondary cell 120 of the FC power generating facility 100. The hydrogen produced by the solar panels 250 may be consumed by the hydrogen using facility 214 in the house group 200, or may be stored in the hydrogen tank 220 in the house group 200.
As described above, two energy forms, electric power and hydrogen, are available as energy using hydrogen. Energy in the form of electric power is suitable for short-period keeping of the energy, and energy in the form of hydrogen is suitable for long-period keeping of the energy. The reason for this is as follows. Electric power is more easily available and thus more suitable for short-period keeping than hydrogen. Hydrogen has less loss during keeping and is thus more suitable for long-time keeping than electric power. The energy management system 400 preferably performs proper management on the keeping of energy in the form of electric power and in the form of hydrogen in consideration of such characteristics of electric power and hydrogen and in consideration of electric power demand and hydrogen demand.
The amount of electric power and the amount of hydrogen generated and produced by the multiple solar panels 250 in the house group 200 are allocated to the multiple houses 210 in that house group 200. For example, the amount of hydrogen produced by the multiple solar panels 250 in one house group 200 may be allocated uniformly to the multiple houses 210 belonging to that house group 200, or may be allocated in response to an area occupied by each house 210. The amount of produced hydrogen allocated to each house 210 increases hydrogen possession at that house 210. The amount of hydrogen used by the hydrogen using facility 214 or the hydrogen supply nozzle 212 in each house 210 reduces hydrogen possession at that house 210. The energy management system 400 is responsible for management of such hydrogen possession. Electric power generated by the solar panels 250 is managed in the same way. As described above, the provision of the hydrogen tank 220 and the solar panels 250 in the house group 200 makes the house group 200 itself available as a hydrogen buffer to allow efficiency increase in the use of hydrogen. This applies to electric power in the same way.
One hydrogen tank 220 as a hydrogen storage may be provided in one house group 200. In this case, hydrogen possession at each house 210 in that house group 200 is stored in one hydrogen tank 220 in that house group 200. By doing so, hydrogen possession at each house 210 in the house group 200 is to be stored in one hydrogen tank 220 in that house group 200, making it possible to manage hydrogen possession at each house 210 easily. Alternatively, one house group 200 may be provided with multiple hydrogen tanks 220 allocated to corresponding houses 210 in that house group 200, and hydrogen possession at each house 210 in that house group 200 may be stored in the hydrogen tank 220 allocated to that house 210. By doing so, hydrogen possession at each house 210 is to be stored in the hydrogen tank 220 allocated to that house 210, making it possible to manage hydrogen possession at each house 210 easily.
In the illustration of
The hydrogen station 300 includes a hydrogen tank 320 as a hydrogen storage, and a hydrogen dispenser 310 for filling the fuel cell vehicle FCV with hydrogen. The hydrogen tank 320 is connected through the pipeline 240 to the multiple house groups 200, to the factory 500 with a hydrogen producing device 510, and to the ammonia-hydrogen converting facility 600. The hydrogen dispenser 310 is one type of hydrogen filler for filling the fuel cell vehicle FCV with hydrogen.
The fuel cell vehicle FCV is preferably a large-sized vehicle such as a bus located in the community. The large-sized fuel cell vehicle FCV includes a hydrogen tank of a large capacity and produces a large output from a fuel cell, and is hence used effectively as a hydrogen source or a power source at a time of disaster. In order to function as a power supply, the fuel cell vehicle FCV is preferably provided with an external power feeder for supplying electric power to the outside. The fuel cell vehicle FCV is particularly preferably located at a public installation such as a public office, a hospital, or a school in the community. This makes it possible to offer a hydrogen source or a power source promptly to the public installation at the time of disaster.
The energy management system 400 has the function of managing hydrogen and electric power in the community system shown in
The factory 500 includes the hydrogen producing device 510, and a hydrogen tank 520 as a hydrogen storage. The hydrogen producing device 510 is a device that produces hydrogen using waste heat in the factory 500, for example. Alternatively, the hydrogen producing device 510 may be configured as a device that separates hydrogen from by-product gas produced through a steelmaking process or a chemical process performed in the factory 500. The hydrogen tank 520 in the factory 500 is connected to the pipeline 240. Making the hydrogen producing device 510 produce hydrogen using waste heat in the factory 500 and using the produced hydrogen in the community system allows effective use of the waste heat in the factory 500, making it possible to increase efficiency in the use of hydrogen and energy in the community system. This similarly applies to the case of using hydrogen in by-product gases from the factory 500.
A process of producing hydrogen in the factory 500 to be used in the community may be performed in a shutdown period of the factory 500. This allows efficient use of waste heat or by-product hydrogen in the shut-down period of the factory 500. Hydrogen may be produced in this way not only in the factory 500 but also in a different commercial and industrial installation. The “commercial and industrial installation” mentioned herein has a wide meaning covering a commercial installation and an industrial installation. The hydrogen producing device 510 in the factory 500 corresponds to a hydrogen producing device that produces hydrogen using waste heat generated in a commercial and industrial installation or produces hydrogen from by-product gas produced in the commercial and industrial installation. Using the hydrogen producing device 510 in this way allows effective use of waste heat or by-product gas in the commercial and industrial installation, making it possible to increase efficiency in the use of hydrogen and energy in the community system.
The ammonia-hydrogen converting facility 600 includes an ammonia tank 610, a hydrogen tank 620, and an ammonia-hydrogen converter 630. The ammonia tank 610 stores ammonia supplied from an ammonia transport vessel ATV staying at a harbor PT, for example. The ammonia transport vessel ATV transports ammonia imported from a foreign country, for example, to the harbor PT. Ammonia may be transported from the ammonia transport vessel ATV to the ammonia tank 610 using a tank truck. However, using a pipeline achieves the transport more easily. If the tank truck is used for transporting ammonia, the ammonia-hydrogen converting facility 600 is not required to be arranged at the harbor PT. Meanwhile, due to the strongly irritating odor of ammonia, the ammonia-hydrogen converting facility 600 is preferably arranged away from the house group 200 as much as possible.
The decomposition of ammonia in an ammonia-hydrogen converting process requires a heat source as it is an endothermic reaction. Thus, heat resulting from combustion of ammonia is generally used as the heat source. Alternatively, waste heat from the factory 500 may be used as the heat source in the ammonia-hydrogen converting process. In this case, piping for carrying a waste heat supply medium is preferably placed between the factory 500 and the ammonia-hydrogen converting facility 600, because it allows production of hydrogen through the effective use of the waste heat in the community system.
Hydrogen produced by the ammonia-hydrogen converter 630 is accumulated in the hydrogen tank 620. The hydrogen tank 620 is connected to the pipeline 240. In other words, hydrogen produced by the ammonia-hydrogen converter 630 is supplied to other facilities in the community system through the pipeline 240.
The ammonia-hydrogen converter 630 may supply the pipeline 240 with a mixed gas of hydrogen including ammonia. Generally, ammonia of a certain amount is left after the ammonia decomposing process performed by the ammonia-hydrogen converter 630. In this regard, to increase the purity of hydrogen, an ammonia removing process is generally performed after the ammonia decomposing process. In this ammonia removing process, adjusting a process parameter so as to leave a tiny amount of ammonia unremoved allows for preparation of the mixed gas containing the tiny amount of ammonia mixed into hydrogen. This mixed gas is prepared by a simple method of controlling the ammonia removing process performed by the ammonia-hydrogen converter 630, making it possible to prepare the hydrogen-ammonia mixed gas easily. In preparation for supply of the hydrogen-ammonia mixed gas through the pipeline 240, ammonia is preferably removed from the mixed gas with an ammonia filter, for example, before a hydrogen using facility in the community system uses hydrogen supplied through the pipeline 240.
An ammonia concentration in the mixed gas is preferably set in a range of 2 ppm or more and 100 ppm or less, for example, and preferably in a range of 2 ppm or more and 50 ppm or less. The ammonia concentration of 2 ppm is at a level at which the odor of ammonia is detectable sufficiently and easily by a human. The ammonia concentration of 50 ppm is at a level at which the odor of ammonia is emitted strongly. The ammonia concentration of 100 ppm is at a level at which the odor of ammonia is emitted more strongly but the toxicity of ammonia does not cause an excessively adverse effect to a human body. In consideration of these, setting a lower limit of the ammonia concentration at 2 ppm makes the odor of ammonia detectable by a human in the case of leakage of the mixed gas, thereby facilitating detection of leakage of the mixed gas. Setting an upper limit of the ammonia concentration at 100 ppm may cause emission of a strong odor of ammonia in the case of leakage of the mixed gas. However, ammonia at this concentration is not so high as to cause an excessively adverse effect to a human body due to the toxicity of ammonia. To emit the odor of ammonia sufficiently while the ammonia concentration is controlled at a sufficiently low level, the ammonia concentration is still preferably set in a range of 2 ppm or more and 50 ppm or less.
In
As described above, the community system shown in
The pieces of information V1 to V6 about hydrogen amounts are related to each other as follows:
V1=V2+V3−V4+V5+V6 (1)
The pieces of information V1 to V6 about hydrogen amounts have the following meanings:
(1) Current hydrogen residual amount V1
The current hydrogen residual amount V1 is hydrogen possession at a corresponding house 210 at the present time.
(2) Last-month-end hydrogen residual amount V2
The last-month-end hydrogen residual amount V2 is hydrogen possession at the corresponding house 210 at the end of the last month.
(3) Hydrogen production amount V3
The hydrogen production amount V3 is an increase in hydrogen possession at the corresponding house 210 in a period from the beginning of the current month to the present time. For example, the hydrogen production amount V3 is an amount allocated to the corresponding house 210 out of the amount of hydrogen produced by the solar panels 250 as a hydrogen producing device in the house group 200 including the corresponding house 210. In each house group 200, allocation information indicating a way of allocating the amount of hydrogen produced by the solar panels 250 in that house group 200 to each house 210 is set in advance in the management database 420.
(4) Hydrogen consumption amount V4
The hydrogen consumption amount V4 is the amount of hydrogen consumed by the corresponding house 210 in the period from the beginning of the current month to the present time. The hydrogen consumption amount V4 is the sum of the amount of hydrogen consumed through the hydrogen supply nozzle 212 and the amount of hydrogen consumed by the hydrogen using facility 214 at the corresponding house 210.
(5) Hydrogen purchase amount V5
The hydrogen purchase amount V5 is the amount of hydrogen purchased from the outside by the corresponding house 210 in the period from the beginning of the current month to the present time.
(6) Hydrogen sale amount V6
The hydrogen sale amount V6 is the amount of hydrogen sold to the outside by the corresponding house 210 in the period from the beginning of the current month to the present time. A difference between the hydrogen sale amount V6 and the hydrogen purchase amount V5 (V6−V5) corresponds to a hydrogen transfer amount transferred from each house 210.
Each house 210 may purchase or sell hydrogen using a management device provided at each house 210, or using an application program installed by a resident of each house 210 on a smartphone or a personal computer.
The energy management system 400 updates the current hydrogen residual amount V1 corresponding to hydrogen possession at each house 210 using the amount of produced hydrogen or consumed hydrogen, thereby allowing management of increase or decrease in hydrogen at each house 210. The energy management system 400 reflects, in the current hydrogen residual amount V1 corresponding to hydrogen possession at each house 210, a hydrogen transfer amount (V6−V5) transferred from the same house 210, making it possible to facilitate use of hydrogen at each house 210 to a greater extent. When hydrogen is transferred from one house 210, hydrogen of the amount of the transfer (V6−V5) may actually be moved to the hydrogen tank 220 provided in the house group 200 including that house 210, or only a hydrogen ownership may be handed over without actually moving hydrogen. Each of these ways allows efficient use of hydrogen in the community system.
A hydrogen amount may be managed in a similar way to that shown in
As described above, the energy management system 400 adjusts production and consumption of hydrogen and electric power in the community system, thereby allowing hydrogen and electric power to be used smoothly, allowing efficiency increase in the use of hydrogen and electric power, and allowing contribution to carbon reduction. Further, the provision of the solar panels 250 as a hydrogen producing device and the hydrogen tank 220 in the house group 200 itself allows the house group 200 to function as a buffer for hydrogen and electricity.
(1) The house groups 200a to 200d in the community system of
(2) The FC power generating facility 100 is buried underground.
Each of the house groups 200e to 200h in
In the community system of
In the community system shown in
The community system according to each of the foregoing embodiments includes the FC power generating facility 100, the house group 200, the hydrogen filler such as the hydrogen station 300, the energy management system 400, and the facilities 500 and 600 each including the hydrogen producing device. This allows construction of a local system achieving efficient use of hydrogen and electric power by means of relatively small investment on an area to cover the community system. As a result, the value of this community system as a brand rises to bring a significant advantage to that area and residents in that area. Further, this community system uses hydrogen and solar energy as main energy sources, making it possible to provide CO2-free life to the residents. Each house 210 in the house group 200 is provided with the fuel cell vehicle FCV as a standard facility, making it possible to provide the residents with CO2-free mobility. Meanwhile, some of the installations or facilities described in each of the embodiments are omissible.
(1) According to one aspect of the present disclosure, a community system that uses hydrogen is provided. The community system comprises: a hydrogen source; a hydrogen storage storing hydrogen supplied from the hydrogen source; an FC power generating facility with a fuel cell that generates electric power using hydrogen supplied from at least one of the hydrogen source and the hydrogen storage; and multiple house groups each of which includes multiple houses that use electric power supplied from the FC power generating facility and hydrogen supplied from at least one of the hydrogen source and the hydrogen storage. The FC power generating facility is located at a position facing all of the multiple house groups, or a position facing all of the multiple house groups and a planned site where a new house group is to be built.
In this community system, because the FC power generating facility is located at a position facing all of the multiple house groups, the FC power generating facility is arranged to be easily available for the multiple house groups. Further, this arrangement allows efficiency increase in the use of equipment, compared to an arrangement in which the FC power generating facility is provided for each house group.
(2) In the foregoing community system, the FC power generating facility may be located at a substantially central position among the multiple house groups, or a substantially central position among the multiple house groups and the planned site where the new house group is to be built.
In this community system, because the FC power generating facility is located at a substantially central position among the multiple house groups, the FC power generating facility is arranged to be more easily available for the multiple house groups.
(3) In the foregoing community system, at least some of the multiple houses may include a hydrogen using facility.
In this community system, the provision of the hydrogen using facility to the house allows contribution to carbon reduction through use of hydrogen.
(4) In the foregoing community system, the multiple house groups may be connected to each other through a pipeline for passage of hydrogen.
In this community system, because the multiple house groups are connected to each other through the pipeline, efficiency increase in the use of hydrogen is allowed in the multiple house groups.
(5) According to a different aspect of the present disclosure, a construction method of constructing a community system is provided. The community system comprises a hydrogen source, a hydrogen storage storing hydrogen supplied from the hydrogen source, an FC power generating facility with a fuel cell that generates electric power using hydrogen supplied from at least one of the hydrogen source and the hydrogen storage, and multiple house groups each of which includes multiple houses that use electric power supplied from the FC power generating facility and hydrogen supplied from at least one of the hydrogen source and the hydrogen storage. In this construction method, the FC power generating facility is located at a position facing all of the multiple house groups, or a position facing all of the multiple house groups and a planned site where a new house group is to be built.
According to this method, because the FC power generating facility is located at a position facing all of the multiple house groups, the FC power generating facility is arranged to be easily available for the multiple house groups. Further, this arrangement allows efficiency increase in the use of equipment, compared to an arrangement in which the FC power generating facility is provided for each house group.
(6) In the foregoing construction method, the FC power generating facility may be located at a substantially central position among the multiple house groups, or a substantially central position among the multiple house groups and the planned site where the new house group is to be built.
According to this method, because the FC power generating facility is located at a substantially central position among the multiple house groups, the FC power generating facility is arranged to be more easily available for the multiple house groups.
(7) In the foregoing construction method, at least some of the multiple houses may include a hydrogen using facility.
According to this method, the provision of the hydrogen using facility to the house allows contribution to carbon reduction through use of hydrogen.
(8) In the foregoing construction method, the multiple house groups may be connected to each other through a pipeline for passage of hydrogen.
According to this method, because the multiple house groups are connected to each other through the pipeline, efficiency increase in the use of hydrogen is allowed in the multiple house groups.
The present disclosure is feasible in various aspects such as a community system, a management device and a management method for managing the community system, a construction method of constructing the community system, and a hydrogen production method employed in the community system, for example.
The disclosure is not limited to any of the embodiment and its modifications described above but may be implemented by a diversity of configurations without departing from the scope of the disclosure. For example, the technical features of any of the above embodiments and their modifications may be replaced or combined appropriately, in order to solve part or all of the problems described above or in order to achieve part or all of the advantageous effects described above. Any of the technical features may be omitted appropriately unless the technical feature is described as essential in the description hereof. The present disclosure may be implemented by aspects described below.
Number | Date | Country | Kind |
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2018-175597 | Sep 2018 | JP | national |