JP6005503B2 - Hydrogen power supply system - Google Patents

Description

  Embodiments described herein relate generally to a hydrogen power supply system.

  Countermeasures against global warming due to the depletion of fossil fuels and the release of carbon dioxide into the atmosphere are being promoted in various industrial sectors, but the impact on transportation is particularly great. As an alternative to conventional internal combustion engine vehicles driven by fossil fuels, electric vehicles (EVs) that drive motors with storage batteries and fuel cell vehicles (Fuel Cell Vehicles) that drive motors via fuel cell power generation using hydrogen : FCV) is being studied.

  In both cases, the challenge for introduction is the enhancement of energy supply equipment to replace the gas station. It is desirable to produce and supply electric power and hydrogen as fuel based on renewable energy represented by sunlight, wind power, geothermal heat, etc. as an energy source that does not depend on fossil fuels. It cannot be said that the facilities are in place.

  In addition, electric vehicles and fuel cell vehicles have so far been separately prepared for development and introduction, including the energy supply infrastructure. It is desirable to be able to provide facilities that can provide power and hydrogen with high efficiency.

  In addition, the issue of renewable energy is that the output is not stable, and it is expected that the energy supply to the vehicle will never be carried out continuously. It is necessary to absorb fluctuations.

  For this purpose, an energy storage facility having a capacity as large as possible is required. If the gap between demand and supply cannot be absorbed in an area where renewable energy can be supplied, it will be necessary to exchange power with the existing power system. It is important to reduce the load on the grid. For this reason, the role of equipment capable of converting and storing energy at high speed and large capacity is significant.

  Until now, technologies related to hydrogen supply to vehicles and infrastructure for supplying electric energy have been proposed, but these technologies are all power supply technologies for power outages and load leveling. It is not a technology for supplying both.

JP 2003-95612 A Japanese Patent Laid-Open No. 2003-61251

  Regarding energy supply to electric vehicles and fuel cell vehicles using renewable energy represented by sunlight, wind, geothermal, etc., renewable energy represented by sunlight, wind, geothermal, etc., as an energy source that does not depend on fossil fuels. Although it is desirable to use energy, the output of most renewable energy is not stable, and it is difficult to use it as an energy supply means for an automobile that is always in operation.

  For electric vehicles, in order to solve the unstable output of renewable energy, a desk lamp equipped with a power storage system such as a secondary battery can be considered, but the secondary battery is used as a short-cycle output control buffer. In many cases, it has a capacity as a function.

  Therefore, when assuming long-term independence such as one day to several days in the event of a power failure or disaster, a large amount of energy storage is required. However, in systems with storage batteries such as secondary batteries, including aspects such as operation rate It is difficult to cope with large capacity.

  Hydrogen stations that supply hydrogen produced by water electrolysis using renewable energy to fuel cell vehicles are gradually being installed, including demonstration tests.

  In order to cope with the unstable output of the hydrogen station as well, the output is stabilized using the grid commercial power supply and hydrogen production is performed. In this case, output adjustment by grid power is necessary, and as a self-supporting station, Not satisfied.

  Electric vehicles and fuel cell vehicles are also being introduced to the market at the same time. However, when the introduction time actually overlaps, facilities that supply energy to both parties with high efficiency are provided without waste of facilities. It is desirable to be able to do it.

  The problem to be solved by the present invention is to provide a hydrogen power supply system capable of supplying energy stably and efficiently independently to both electric vehicles and fuel cell vehicles using renewable energy. There is to do.

Hydrogen power supply system of the embodiment comprises renewable energy generation units, the power storage unit, water electrolysis unit, the hydrogen storage unit, hydrogen generation unit, thermal storage units, power supply units, the hydrogen supply unit, the management unit. The renewable energy power generation unit generates power using renewable energy. The power storage unit stores a part of the generated power . Water electrolysis unit by electrolysis of water by power stored by a charge reservoir unit to produce a hydrogen. The hydrogen storage unit stores hydrogen produced by the water electrolysis unit . Hydrogen generation unit for generating electric power using the hydrogen that is stockpiled hydrogen storage unit. Thermal storage unit stores the heat generated during power generation in at least one of the renewable energy unit and hydrogen generation unit, supplies heat to the water electrolysis unit. The power supply unit supplies at least one of the power stored in the power storage unit, the power supplied from the external power system, and the power supplied from the renewable energy power generation unit to the supply target. The hydrogen supply unit supplies hydrogen or a medium containing hydrogen stored in the hydrogen storage unit to a supply target. The management unit monitors the supply / demand situation of power, hydrogen, and heat in each unit, and controls the operation of each unit so as to compensate for future shortages based on the monitored supply / demand situation.

  According to the present invention, an electric / hydrogen combined stand system that can supply energy to hydrogen vehicles and fuel cell vehicles in a stable and highly efficient manner using renewable energy is constructed. be able to.

It is a figure which shows the structure of the hydrogen power supply system of 1st Embodiment. It is a figure which shows the structure of the hydrogen power supply system of 2nd Embodiment.

Hereinafter, embodiments will be described in detail with reference to the drawings.
(First embodiment)
FIG. 1 is a diagram illustrating a configuration of a hydrogen power supply system according to the first embodiment.
As shown in FIG. 1, the hydrogen power supply system 10 of the first embodiment includes a power supply unit 11, a hydrogen supply unit 12, a renewable energy power generation unit 13, a power storage unit 14, a water electrolysis unit 15, and a water supply unit 16. , A hydrogen storage unit 17, an oxygen storage unit 18, a hydrogen power generation unit 19, a water recovery unit 20, a heat storage / heat exchange unit 21 as a heat storage unit, an external power system connection unit 22, a hydrogen replenishment unit 23, a management unit 24, and the like. .

  The power supply unit 11 supplies the power stored in the power storage unit 14, the power supplied from the external power system connection unit 22, or the power supplied from the renewable energy power generation unit 13 to a supply target (such as an electric vehicle).

  The hydrogen supply unit 12 supplies hydrogen or a medium containing hydrogen stored in the hydrogen storage unit 17 to a supply target (such as a fuel cell vehicle). That is, the hydrogen supply unit 12 supplies a part of the hydrogen stored in the hydrogen storage unit 17 directly to a supply target, that is, a fuel cell vehicle.

  The renewable energy power generation unit 13 generates power using at least one renewable energy among renewable energy such as sunlight, solar heat, wind power, geothermal heat and the like. In addition, tidal power or the like may be used as renewable energy. The power storage unit 14 stores a part of the power generated by the renewable energy power generation unit 13.

  As the water electrolysis unit 15, for example, an alkaline electrolysis apparatus, an electrolysis apparatus using a solid polymer membrane cell, or an electrolysis apparatus using a solid oxide cell can be applied. The water electrolysis unit 15 produces hydrogen and oxygen by electrolyzing the water supplied by the water supply unit 16 with the electric power stored by the power storage unit 14.

  The water supply unit 16 supplies water for electrolysis (purified water) to the water electrolysis unit 15. The water supply unit 16 is supplied with purified water from the outside. The hydrogen storage unit 17 stores the hydrogen produced by the water electrolysis unit 15.

  The oxygen storage unit 18 stores the oxygen produced by the water electrolysis unit 15. Oxygen accumulated in the oxygen storage unit 18 may be used for external purposes such as medical treatment and aquaculture, and may be used again for power generation in the hydrogen power generation unit 19 together with hydrogen.

  The hydrogen power generation unit 19 generates power using hydrogen stored in the hydrogen storage unit 17. As the hydrogen power generation unit 19, in addition to various types of fuel cells such as a solid polymer type and a solid oxide type, a generator using an internal combustion engine can be applied. The water recovery unit 20 recovers water generated during power generation.

  The heat storage / heat exchange unit 21 manages heat generated during power generation in the renewable energy power generation unit 13 and heat absorbed by the water electrolysis unit 15 during hydrogen production.

  Specifically, the heat storage / heat exchange unit 21 includes a heat storage tank 21a that stores the heat generated by the renewable energy power generation unit 13 and the hydrogen power generation unit 19 during power generation, and the water electrolysis unit that stores the heat stored in the heat storage tank 21a. 15 and a supply mechanism 21 b that supplies the hydrogen storage unit 17.

  The heat storage / heat exchange unit 21 stores heat generated during power generation in the renewable energy power generation unit 13 in the heat storage tank. When the water electrolysis unit 15 produces hydrogen, the heat stored in the heat storage tank 21a is stored. The supply mechanism 21 b supplies the water electrolysis unit 15 and the hydrogen storage unit 17.

  The external power system connection unit 22 manages power exchange with an external power system. When the external power system connection unit 22 cuts off the connection with the external power system, the power for operating (operating) the unit itself is generated by hydrogen stored in the hydrogen storage unit 17 or the power storage unit 14. The power line is switched so as to cut off the connection with the external power system in response to the power supply from.

  The hydrogen replenishment unit 23 considers itself that hydrogen as a base for power generation is insufficient, and obtains hydrogen obtained by, for example, biomass reforming from the outside through a tank lorry or a pipeline and stores it in the hydrogen storage unit 17. That is, the hydrogen supply unit 23 supplies hydrogen or a medium for storing hydrogen from the outside.

  That is, the hydrogen power supply system 10 of the first embodiment is for at least two types of next-generation vehicles, that is, a power supply unit 11 that supplies power to an electric vehicle and a hydrogen supply unit 12 that supplies hydrogen to a fuel cell vehicle. And a fuel supply unit.

  The renewable energy power generation unit 13 generates power using renewable energy such as sunlight, solar heat, wind power, and geothermal heat. The electric power generated by the renewable energy power generation unit 13 is used for water electrolysis in the water electrolysis unit 15 except for the amount consumed by the power supply unit 11 and the amount necessary for power storage in the power storage unit 14. Hydrogen and oxygen are produced.

  Hydrogen produced in the water electrolysis unit 15 is stored (accumulated) in the hydrogen storage unit 17. Oxygen produced by the water electrolysis unit 15 is stored (accumulated) in the oxygen storage unit 18.

The management unit 24 monitors each unit to be monitored, grasps the balance of electricity, hydrogen, and heat (supply / demand balance), and controls the operation of each unit according to a change in the supply / demand balance.
That is, the management unit 24 monitors the supply / demand situation (storage quantity or production quantity and supply quantity) of electric power, hydrogen, and heat in each unit, and the storage quantity or production quantity predicted to be deficient in the future based on the monitored supply / demand situation. Control the operation of each unit to make up for the shortage.

  For example, when considering electric power as an example, the management unit 24 monitors the amount of electric power demand in the electric power supply unit 11 and the amount of electric power supplied from the renewable energy power generation unit 13, and the difference between them (the demand-supply balance) is When a preset threshold value is exceeded, the operation of each unit is controlled so as to compensate for the shortage of power.

  When the difference between the amount of power demand in the power supply unit 11 and the amount of power supplied from the renewable energy power generation unit 13 exceeds the threshold, the management unit 24 means that the demand amount of power greatly exceeds the amount of supply. In this case, the amount of hydrogen stored in the preceding hydrogen storage unit 17 is increased while performing control to increase the amount of power generated by the hydrogen power generation unit 19. In this way, the power generation by the hydrogen power generation unit 19 compensates for the shortage of power with respect to the increase in demand.

  The water recovery unit 20 recovers water generated at the time of power generation using hydrogen, and returns to the water supply unit 16 again. The management unit 24 controls the water supply unit 16 as necessary when the amount of supplied water is insufficient during operation. Thereby, the water supply unit 16 replenishes purified water from the outside.

Here, the outline | summary operation | movement of the hydrogen power supply system of this embodiment is demonstrated.
In the present embodiment, the management unit 24 constantly monitors the supply and demand situation of power and water, and controls the operation of each unit so as to maintain the supply and demand balance.

  For example, the electric power obtained from the renewable energy power generation unit 13 is converted into hydrogen by the water electrolysis unit 15 and stored in the hydrogen storage unit 17 except for power required for charging the electric vehicle and maintaining the system itself. When the electric power is required more than the power received from the renewable energy power generation unit 13, the shortage is supplied by the hydrogen power generation unit 19 such as a fuel cell.

  Further, when hydrogen is supplied to the fuel cell vehicle, a required amount of hydrogen is supplied from the hydrogen storage unit 17 via the hydrogen supply unit 12. Thereby, the electric power by the renewable energy with a big fluctuation | variation can be utilized efficiently.

  Furthermore, when the power generated by the renewable energy power generation unit 13 becomes surplus, the surplus power is used to increase the hydrogen filling pressure, thereby increasing the energy capacity of the hydrogen supply unit 12 and the power supply unit 11. It can be increased.

  In addition, when it is determined that the hydrogen storage in the hydrogen storage unit 17 is sufficient, it is also possible to sell power by sending an excess of the input from the renewable energy power generation unit 13 to an external power system.

  In actual system operation, the amount of power received by the system, the amount of power supplied from the system, and the temporal change in the amount of hydrogen stored are quantified to some extent, based on past results and future predictions regarding the weather and vehicle usage. Predictive.

  In this system, the management unit 24 determines the operation of each unit in the system and the amount of power exchanged from an external power system based on the temporal change in the amount of power and the amount of hydrogen storage predicted quantitatively to some extent.

  Then, the difference between the operation of each unit in the system determined by the management unit 24, the amount of power exchanged from the external power system, and the change in the actual operation status is obtained, and the supply / demand balance set in advance is determined. By comparing and operating each unit so as to increase or decrease the hydrogen or electric power so as to meet the future supply and demand amount by comparing with the threshold value, the entire system can be operated efficiently.

  In order to minimize the operating cost, it is desirable to minimize the amount of power received from the external power system and maximize the amount of power transmitted from the system to the external power system.

  In addition, this system is capable of independent operation without power supply from an external power system in principle, but when there is no power reception from the renewable energy power generation unit 13, it can be An external power system connection unit 22 for switching so that power for operating the unit is obtained by power generation from stored hydrogen and power feeding from an attached power storage unit 14 in preparation for disconnection from the system. Provided. As a result, the system can be operated independently even in an emergency.

  Furthermore, the hydrogen replenishment unit 23 replenishes hydrogen obtained by reforming biomass from the outside, so that no power is received from the renewable energy power generation unit 13 and the connection with the external power system is cut off. Even if the operation continues, both hydrogen and electric power can be continuously supplied.

  Subsequently, the operation (hydrogen power supply method) of the hydrogen power supply system of the first embodiment will be described.

  In the hydrogen power supply system 10 of the first embodiment, heat generated during power generation by the renewable energy power generation unit 13 or the hydrogen power generation unit 19 is recovered by the heat storage / heat exchange unit 21 in order to increase the energy efficiency in the system. Then, it is utilized for the electrolysis reaction of water in the water electrolysis unit 14 that performs an endothermic reaction and the hydrogen supply from the hydrogen storage unit 17.

  In addition, the hydrogen power supply system 10 is connected to an external power system via an external power system connection unit 22, and the power obtained by the renewable energy power generation unit 13 is used as a demand ( In the case of exceeding the energy supply to the electric vehicle and the fuel cell vehicle + hydrogen storage), the power stored in the power storage unit 14 is provided to the external system.

  Conversely, when the demand for power supplied from the power supply unit 11 to the electric vehicle exceeds the amount of power that can be supplied from the renewable energy power generation unit 13 and the hydrogen power generation unit 19, the external power system connection unit is connected to the external power system connection unit. The required amount of electric power is introduced through 22.

  Further, when the hydrogen storage amount is insufficient, or when hydrogen or a hydrogen storage medium can be supplied from outside the system, the management unit 24 supplies the hydrogen or the hydrogen storage medium from the outside via the hydrogen supply unit 23. 17 is introduced.

  That is, the management unit 24 monitors the power generation amount and heat storage amount in each unit, the hydrogen storage amount, the current value, gas flow rate, water flow rate, etc. in each line, so that the optimum operation of power is performed inside and outside. Adjust each input and output (operation control).

  The management unit 24 schedules (plans) the operation schedule in units of days and weeks based on the prediction of the energy supply amount and frequency to the electric vehicle and the fuel cell vehicle, and adjusts the difference from the actual usage status. The system can be operated with high efficiency.

Furthermore, minimum and a settable range received power amount from the external power system, a power amount to be supplied to the power system from the unit when the maximum, the autonomy maximum system with renewable energy measures It is possible to reduce operating costs and environmental impact.

  As described above, according to the first embodiment, the management unit 24 generates the power generation amount in the renewable energy power generation unit 13, the hydrogen storage amount in the hydrogen storage unit 19, and the supply target (electric vehicle, fuel cell vehicle). Based on the results of power supply and hydrogen supply and preset prediction values, the operation of the water electrolysis unit 14 and the hydrogen power generation unit 19, the operation of the heat storage / heat exchange unit 21, and the amount of power exchanged from the external power system Since each unit is operated and controlled, the power generation output using renewable energy and the hydrogen stored in the hydrogen storage unit 19 can be used stably and highly efficiently for electric vehicles and fuel cell vehicles. It is possible to build a hydrogen and electric power supply stand that can supply energy independently.

  As a result, it is possible to supply energy to both hydrogen vehicles and fuel cell vehicles in a stable and highly efficient manner using renewable energy.

(Second Embodiment)
FIG. 2 is a diagram illustrating a configuration of the hydrogen power supply system according to the second embodiment. In FIG. 2, the same components as those in the first embodiment (FIG. 1) are denoted by the same reference numerals, and the description thereof is omitted.

  In the second embodiment, a method of using heat will be described. The heat generated during operation of the renewable energy power generation unit 13 and the hydrogen power generation unit 19 is temporarily stored in the heat storage tank 21a, and then heat is generated such as electrolysis of water in the water electrolysis unit 15 and release of hydrogen in the hydrogen storage unit 17. The efficiency of the entire system can be further increased by supplying the reaction to the reaction that requires. In addition, about the calorie | heat amount stored in the heat storage tank 21a, it can take out as warm water as needed.

  On the contrary, when the amount of heat required in the system of this system is larger than the amount of heat stored, a part of the hydrogen stored in the hydrogen storage unit 17 is burned or the current taken out from the power storage unit 14 It is also possible to compensate by performing heating.

  Therefore, in the second embodiment, as shown in FIG. 2, the water supply unit 16 and the heat storage / heat exchange unit 21 are connected by a pipeline, and the hot water from the heat storage / heat exchange unit 21 is supplied to the water electrolysis unit 15 or The hydrogen storage unit 17 can be supplied.

  As described above, in addition to the hot water, there may be a case where the water electrolysis unit 15 or the hydrogen storage unit 17 requires a heat amount equal to or greater than the heat storage amount. In this example, a spare heat supply unit 25 is newly added. It shall be installed in

  When the required amount of heat is greater than the amount of heat in the heat storage tank 21a, the heat supply unit 25 obtains a shortage of heat by taking out hydrogen from the hydrogen storage unit 17 and burning it, and stores the obtained amount of heat. -Obtaining a deficient amount of heat by supplying to the heat exchange unit 21.

  Further, the heat supply unit 25 obtains a shortage of heat by the heat generated by the electric power from the power storage unit 14 and supplies the obtained heat to the heat storage / heat exchange unit 21 to obtain a shortage of heat.

In the case of the second embodiment, the water supply unit 16 and the heat storage / heat exchange unit 21 are connected by a pipeline, and hot water from the heat storage / heat exchange unit 21 is supplied to the water electrolysis unit 15 and the hydrogen storage unit 17.
Here, when the amount of heat stored in the heat storage tank 21a of the heat storage / heat exchange unit 21 is smaller than the required amount of heat, in other words, the required amount of heat is larger than the amount of heat stored in the heat storage tank 21a. In this case, the management unit 24 controls the hydrogen storage unit 17 and the power storage unit 14 to supply the electric power stored in the power storage unit 14 or a part of the hydrogen stored in the hydrogen storage unit 17 to the heat supply unit 25. To do.

  As a result, the heat supply unit 25 that has been supplied with electric power or hydrogen generates heat and supplies it to the heat storage / heat exchange unit 21, so that the amount of heat more than the amount of heat stored by the heat storage / heat exchange unit 21 (insufficient) The warm water is stably supplied to the water electrolysis unit 15 and the hydrogen storage unit 17.

  According to the second embodiment, the water supply unit 16 and the heat storage / heat exchange unit 21 are connected by a pipeline, and the water supplied from the water supply unit 16 to the heat storage / heat exchange unit 21 is heated to warm water. Since it supplies to the electrolysis unit 15 and the hydrogen storage unit 17, renewable energy can be produced | generated and supplied efficiently.

  In addition, when the heat storage / heat exchange unit 21 is newly provided with a spare heat supply unit 25 to supply heat, the heat supply unit when the amount of heat to be supplied is insufficient with the predetermined heat generation amount of the heat storage / heat exchange unit 21. By supplying heat to the heat storage / heat exchange unit 21 from 25, it becomes possible to heat the water with a heat quantity equal to or greater than a predetermined heat storage quantity (supplementing the heat quantity) and supply hot water, further improving efficiency. it can.

  Although the embodiment of the present invention has been described, this embodiment is presented as an example and is not intended to limit the scope of the invention. The novel embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 10 ... Hydrogen power supply unit, 11 ... Power supply unit, 12 ... Hydrogen supply unit, 13 ... Renewable energy power generation unit, 14 ... Power storage unit, 15 ... Water electrolysis unit, 16 ... Water supply unit, 17 ... Hydrogen storage unit, 18 ... Oxygen storage unit, 19 ... Hydrogen power generation unit, 20 ... Water recovery unit, 21 ... Heat storage / heat exchange unit, 22 ... External power system connection unit, 23 ... Hydrogen supply unit, 24 ... Management unit, 25 ... Heat supply unit .

Claims (8)

A renewable energy power generation unit that generates power using renewable energy;
A power storage unit for storing a part of the generated power;
A water electrolysis unit electrolytically decomposing water to produce hydrogen by power stored by the previous SL energy storage unit,
A hydrogen storage unit for storing hydrogen produced by the water electrolysis unit;
And hydrogen generation unit for generating electric power by using hydrogen which has been stockpiled before Symbol hydrogen storage unit,
Before SL accumulates heat generated during power generation in at least one of the renewable energy unit and the hydrogen generation unit, and the heat storage unit for supplying the heat to the water electrolysis unit,
A power supply unit that supplies any one of the power stored in the power storage unit, the power supplied from an external power system, and the power supplied from the renewable energy power generation unit to a supply target;
A hydrogen supply unit that supplies hydrogen or a medium containing hydrogen stored in the hydrogen storage unit to a supply target;
A hydrogen power supply system comprising: a management unit that monitors the supply / demand situation of power, hydrogen, and heat in each unit and controls the operation of each unit to compensate for future shortages based on the monitored supply / demand situation. The heat storage unit is
A heat storage tank for storing heat generated during power generation by the renewable energy power generation unit and the hydrogen power generation unit;
The hydrogen power supply system according to claim 1, further comprising: a supply mechanism that supplies heat stored in the heat storage tank to the water electrolysis unit and the hydrogen storage unit.   The hydrogen power supply system according to claim 2, comprising a mechanism for taking out a part of heat of the heat storage tank as hot water.   When the amount of heat required is greater than the amount of heat in the heat storage tank, the amount of heat is obtained by taking out hydrogen from the hydrogen storage unit and burning it, or the amount of heat generated by the electricity from the power storage unit is insufficient. The hydrogen power supply system according to claim 2, further comprising a heat supply unit that obtains an amount of heat. The management unit is
Based on the power generation amount in the renewable energy power generation unit, the hydrogen storage amount in the hydrogen storage unit, the results of power and hydrogen supply amounts to the supply target, and preset prediction values, the water electrolysis unit and wherein determining a power transfer amount from the operation as the external electric power system of the蓄hot oil knit hydrogen generation unit, hydrogen according to any one claims 1 to 4, operational controls each unit Power supply system. Minimum and a settable range received power amount from the power system of external, the power to maximize the amount of transmitted power to the grid, the hydrogen power supply system according to any one of claims 1 to claim 5 . When interrupting the connection between the external power system, the power to operate the unit, in claim 1 to claim 6 any one having an external power system connection unit to switch the power supply from said power storage unit The hydrogen power supply system described.   The hydrogen power supply system according to any one of claims 1 to 7, further comprising a hydrogen replenishment unit that obtains the hydrogen from outside and replenishes the hydrogen storage unit.

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