JP2018116834A - High-temperature heat storage system and high-temperature heat storage method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a high-temperature heat storage system capable of performing temperature control while reducing a system loss even at high temperature, and a high-temperature heat storage method.SOLUTION: The present invention relates to a high temperature heat storage system comprising: a cell stack part 1 having operational states of a power generation mode and a water electrolysis mode; a first heat storage body 2 that is provided while facing the cell stack part 1; a compressor 5 which supplies a heat medium 9 to the cell stack part 1; a second heat storage body 4 provided in a heat medium passage that is circulated between the cell stack part 1 and the compressor 5; a switching device 7 which is provided in the heat medium passage and switches a flowing direction of the heat medium 9 with respect to the cell stack part 1; and a control part 8 which performs switching control of the switching device 7 and flow rate control of the heat medium 9.SELECTED DRAWING: Figure 1

Description

  Embodiments described herein relate generally to a high-temperature heat storage system and a high-temperature heat storage method used for a hydrogen power storage device and the like.

2. Description of the Related Art Conventionally, a hydrogen power storage device that stores hydrogen generated by electrolysis of water vapor and enables power generation using the stored hydrogen is known (see, for example, Patent Document 1).
An example of such a hydrogen power storage device will be described with reference to FIG. FIG. 4 is a diagram schematically showing a configuration of a conventional hydrogen power storage device.

  As shown in FIG. 4, the hydrogen power storage device 10 includes a power / hydrogen conversion device 11 (cell stack unit) having the functions of both a solid oxide electrolytic cell (SOEC) and a solid oxide fuel cell (SOFC). ), A hydrogen storage device 12 for storing hydrogen generated by the power / hydrogen conversion device 11, and a heat storage device 13 for storing high-temperature heat generated during power generation.

  In the power generation mode (SOFC mode), hydrogen and air (oxygen) stored in the hydrogen storage device 12 are supplied to the power / hydrogen conversion device 11 to generate power. The heat generated at this time is stored in the heat storage device 13.

  On the other hand, in the water electrolysis mode (SOEC mode), water vapor and high-temperature heat stored in the heat storage device 13 are supplied to the power / hydrogen conversion device 11, and the water vapor is electrolyzed to generate hydrogen. At this time, the generated hydrogen is stored in the hydrogen storage device 12.

  As described above, the heat storage device 13 temporarily stores heat and releases heat when necessary, thereby enabling effective use of energy. Although the heat storage temperature in the heat storage device 13 varies depending on the device, in the example of the hydrogen power storage device described above, high-temperature heat of 700 ° C. or higher is stored in the heat storage device 13.

JP 2010-232165 A

By the way, in a heat storage device in which high-temperature heat is stored, heat insulation means becomes important, and ingenuity is required even in a heat transfer system.
For example, when a heat transfer plate is used as the heat transfer method, aluminum having a high thermal conductivity has a melting point of 660 ° C., and thus cannot be used in a heat storage device having a high temperature of 700 ° C. or higher. Moreover, even if copper having a high melting point is used as the heat transfer plate, solder having a low melting point cannot be used for the connection portion, so that the thermal resistance increases and the temperature difference between the heat source and the heat storage device increases. There is a problem.

  In addition, when a heat medium is used as a heat transfer method to supply heat to the heat storage device, a heat medium having a large specific heat such as water cannot be used at a high temperature of 700 ° C. or higher, and a specific heat such as nitrogen gas is small. A heat medium is used. In this case, it is necessary to circulate a large amount of the heat medium.

In this case, a compressor for circulating the heat medium is required. However, since there is no compressor that can be operated at 700 ° C. or higher, the compressor is arranged in a room temperature region and heat is passed through the heat exchanger. It is necessary to circulate the medium. For this reason, when the efficiency of the heat exchanger is less than 100%, heat loss occurs, and furthermore, the pressure loss including the heat exchanger also increases, so the required power of the compressor also increases.
As described above, the heat transfer system using nitrogen gas or the like as a heat medium has a problem that the system loss including the heat loss and the required power increases as the temperature increases.

On the other hand, there is a radiation heat transfer method as a heat transfer method effective at high temperatures. The amount of heat transfer in this radiant heat transfer system can be expressed by the following formula 1.

  As shown in Equation 1, the amount of heat transfer in the radiant heat transfer method generally increases due to the difference of the fourth power of the temperature. Therefore, as the temperature increases, the amount of heat transfer per unit area increases rapidly and heat transfer becomes easier. . In addition, the radiant heat transfer method has an advantage that the system loss is small because no power is required.

However, since the amount of heat transfer in the radiant heat transfer system varies depending on the relationship between the temperature of the heat transfer surface and the emissivity, there is a problem that the amount of heat transfer cannot be stably controlled. For this reason, when the radiant heat transfer method is used for the heat storage device, there is a problem that it is difficult to optimally control the temperature of the cell stack and a stable heat output cannot be obtained.
As described above, since the conventional heat conduction method, heat medium circulation method, and radiant heat transfer method all have the problems described above, the development of an effective heat transfer method has been an issue.

  Embodiments of the present invention have been made to solve the above-described problems, and an object of the present invention is to obtain a high-temperature heat storage system and a high-temperature heat storage method capable of controlling the temperature with little system loss even at high temperatures. To do.

In order to solve the above-described problem, a high-temperature heat storage system according to an embodiment of the present invention includes a cell stack unit having an operation state in a power generation mode and a water electrolysis mode, and a first provided to face the cell stack unit. A heat storage body, a compressor for supplying a heat medium to the cell stack section, a second heat storage body provided in a heat medium flow path circulating between the cell stack section and the compressor, and the heat medium A switching device that is provided in a flow path and switches the flow direction of the heat medium with respect to the cell stack unit, and a control unit that performs switching control of the switching device and flow rate control of the heat medium.
Moreover, the high temperature thermal storage method which concerns on embodiment of this invention controls the temperature of a cell stack part using the high temperature thermal storage system which concerns on this embodiment, It is characterized by the above-mentioned.

  ADVANTAGE OF THE INVENTION According to this invention, even if it is high temperature, there is little system loss and the high temperature thermal storage system and high temperature thermal storage method in which temperature control is possible can be obtained.

It is an operation | movement figure in the electric power generation mode (SOFC mode) of the high temperature thermal storage system which concerns on embodiment of this invention. It is an operation | movement figure in the water electrolysis mode (SOEC mode) of the high temperature thermal storage system which concerns on embodiment of this invention. It is a figure explaining the relationship between an incident angle and a reflectance. It is the figure which showed typically the structure of the conventional hydrogen power storage apparatus.

Hereinafter, embodiments of a high-temperature heat storage system and a high-temperature heat storage method according to the present invention will be described with reference to the drawings.
In the present embodiment, an example in which the high-temperature heat storage system according to the present invention is applied to the hydrogen power storage device described with reference to FIG. 4 will be described. 1 and 2 illustrate the power / hydrogen conversion device (cell stack unit), the heat storage device, and the oxygen / air-based gas piping in the hydrogen power storage device.

[Constitution]
(Configuration of high-temperature heat storage system)
As shown in FIGS. 1 and 2, the high-temperature heat storage system of the present embodiment includes a cell stack unit 1, a first heat storage body 2 including a heat storage capsule group arranged so as to surround the cell stack unit 1, and heat In the flow path of the gas pipe 3, the compressor 5 that circulates the medium 9, the gas pipe 3 that is connected between the cell stack unit 1 and the compressor 5 and forms the heat medium flow path through which the heat medium 9 circulates. Provided between the second heat storage body 4 comprising the provided heat storage capsule group, the heat exchanger 6 that performs heat exchange of the heat medium 9 circulating in the gas pipe 3, and the compressor 5 and the heat exchanger 6. By controlling the flow rate of the heat medium 9 in the gas pipe 3 by controlling the switching valve (switching device) 7 for switching the flow path of the heat medium 9 and the compressor 5 by, for example, inverter, and controlling the switching valve 7. A control unit 8 for switching the flow direction of the heat medium 9 in the gas pipe 3. It is.

In the present embodiment, air is used as an example of the heat medium 9, but other heat medium gas may be used.
Moreover, in this embodiment, although the control part 8 uses the technique which controls the compressor 5 as an example of flow control of the heat medium 9, for example, the flow control valve etc. are provided in the gas piping 3, and the control part 8 is used. A method of controlling the flow rate of the heat medium 9 by controlling this can also be used.

  The cell stack unit 1 has functions of a solid oxide electrolytic cell (SOEC) and a solid oxide fuel cell (SOFC) (not shown). In the power generation mode (SOFC mode), the cell stack unit 1 While generating heat and generating electric power, a part of the heat is stored in the first heat storage body 2 by radiant heat transfer. On the other hand, in the water electrolysis mode (SOEC mode), water vapor is electrolyzed by the heat from the first heat storage body 2 and the second heat storage body 4 to generate hydrogen.

(Configuration of the first heat storage body 2)
The first heat storage body 2 includes a plurality of first heat storage capsules 2 a to 2 d and is disposed so as to surround the cell stack unit 1. In the example shown in FIGS. 1 and 2, rectangular first heat storage capsules 2 a to 2 d are arranged so as to face four surfaces of the rectangular cell stack portion 1.

Each of the first heat storage capsules 2a to 2d has an outer wall made of, for example, silicon carbide (SiC), and a heat storage material made of a molten salt such as sodium carbonate-potassium carbonate (Na ₂ CO ₃ —K ₂ CO ₃ ) inside. Filled.

  As described above, each of the rectangular first heat storage capsules 2a to 2d is arranged so as to be parallel to each of the four surfaces of the rectangular cell stack portion 1, thereby generating heat in the cell stack portion 1. About 90% of the quantity is stored in each first heat storage capsule 2a-2d by radiant heat transfer.

By the way, the amount of radiant heat transfer from the cell stack unit 1 to the first heat storage body 2 (first heat storage capsules 2a to 2d) is proportional to the emissivity ε as shown in Equation 1 above. And the relationship between emissivity (epsilon) and reflectance (alpha) can be shown by the following formula 2.

  Further, as shown in FIG. 3, it is known that the reflectance α generally approaches 1 when the incident angle approaches horizontal (90 °). Therefore, in order to increase the amount of radiant heat transfer from the cell stack unit 1 to the first heat storage capsules 2a to 2d, it is desirable to make the incident angle perpendicular (0 °) to the heat transfer surface.

  From this point of view, in the present embodiment, the first heat storage capsules 2a to 2d are also rectangular in accordance with the cell stack portion 1 being formed in a rectangular shape, and the heat transfer surface (that is, the first heat storage capsule). The surfaces facing the cell stack portion 1 in 2a to 2d) are arranged so as to be parallel to the respective surfaces of the cell stack portion 1.

  The shape of the first heat storage capsules 2 a to 2 d can be changed as appropriate according to the shape of the cell stack unit 1. For example, if the cell stack part 1 is cylindrical, the first heat storage capsules 2a to 2d may be formed in an annular shape and arranged concentrically on the outer periphery of the cylindrical cell stack part 1 with a gap. In any case, any shape may be used as long as the cell stack portion 1 and the first heat storage capsules 2a to 2d can be arranged to face each other.

  Moreover, in the example shown in FIG.1 and FIG.2, although the number of the 1st thermal storage capsules 2a-2d arrange | positioned is set to 4, it is not restricted to this, For example, the shape of the cell stack part 1 and required It can be appropriately increased or decreased according to the heat storage capacity.

(Configuration of second heat storage body)
The second heat storage body 4 includes a plurality of columnar second heat storage capsules 4 a to 4 d and is provided in the flow path of the gas pipe 3 between the cell stack unit 1 and the heat exchanger 6. Each of the second heat storage capsules 4a to 4d has an outer wall made of, for example, silicon carbide (SiC), and a heat storage material made of a molten salt such as sodium carbonate-potassium carbonate (Na ₂ CO ₃ —K ₂ CO ₃ ) inside. Filled.

  In addition, each of the second heat storage capsules 4a to 4d is stored by heat transfer from the air (oxygen) flowing through the gas pipe 3, but if the flow rate is increased in order to increase the heat transfer rate, pressure loss and required Power increases and system efficiency decreases. Therefore, in this embodiment, the 2nd heat storage capsules 4a-4d are made into a cylindrical shape, and coexistence of a high heat transfer rate and a low pressure loss is possible.

  Furthermore, in the example shown in FIGS. 1 and 2, the number of the second heat storage capsules 4 a to 4 d to be arranged is four, but is not limited to this, for example, the shape of the cell stack unit 1 and the necessary It can be appropriately increased or decreased according to the heat storage capacity.

In the first heat storing capsules 2a~2d and / or second heat storage capsule 4 a to 4 d, the outer wall of the material other materials, for example, can be used such as aluminum oxide (Al ₂ O _3), the heat storage Other materials can be used as the material.

[Action]
The operation of the high-temperature heat storage system configured as described above will be described separately for the SOFC mode (power generation mode) and the SOEC mode (water electrolysis mode). 1 and 2, an arrow line adjacent to the gas pipe 3 indicates the flow direction of the heat medium 9.

(SOFC mode (power generation mode))
In the SOFC mode, as shown in FIG. 1, the cell stack unit 1 is in a heat generation state, and about 90% of the heat generation amount is radiated to the first heat storage capsules 2a to 2d, and the remaining heat generation amount is The heat medium 9 circulating in the gas pipe 3 is carried to the second heat storage capsules 4a to 4d. Next, the heat medium 9 is circulated to the cell stack unit 1 through the heat exchanger 6, the switching valve 7, the compressor 5, and the heat exchanger 6.

By the way, in the 1st heat storage capsule 2a-2d, since the surface temperature changes, the amount of radiant heat transfer from the cell stack part 1 is not constant. Therefore, in this embodiment, the flow rate of the heat medium 9 is controlled by the control unit 8 so that the temperature of the cell stack unit 1 becomes a constant temperature, for example, about 750 ° C.
Thus, since the stable heat output can be obtained by controlling the temperature of the cell stack part 1 to be constant, the system efficiency of the hydrogen power storage system can be improved.

  In addition, the flow rate of the heat medium 9 made of air or the like is about 1/10 that of heat transfer using only the heat medium, and the required power of the compressor 5 and the like is small. Moreover, since the oxygen / air-based gas can be used as the heat medium 9 by reducing the flow rate, a circulation system dedicated to the heat medium such as nitrogen gas is not necessary, and the hydrogen power storage system is greatly simplified. be able to.

(SOEC mode (water electrolysis mode))
In the SOEC mode, as shown in FIG. 2, the cell stack unit 1 is in an endothermic state, and radiant heat transfer from the first heat storage capsules 2a to 2d and a high-temperature heat medium flowing from the second heat storage capsules 4a to 4d 9 is heated.

  The heat medium 9 switches the switching valve 7 as shown in FIG. 2, so that the cell stack unit 1, the heat exchanger 6, the switching valve 7, the compressor 5, the heat exchanger 6, and the second heat storage capsules 4 a to 4 d. It circulates to the cell stack part 1 through this.

  By the way, as above-mentioned, since the surface temperature of the 1st heat storage capsules 2a-2d changes, the amount of radiant heat transfer to the cell stack part 1 is not constant. Therefore, in the present embodiment, the flow rate of the heat medium 9 is controlled by the control unit 8 so that the temperature of the cell stack unit 1 becomes a constant temperature, for example, about 650 ° C. even in the SOEC mode.

  As described above, even in the SOEC mode, a stable heat output can be obtained by controlling the temperature of the cell stack unit 1 to be constant, so that the system efficiency of the hydrogen power storage system can be improved.

[effect]
As described above, according to the embodiment of the present invention, the first heat storage body 2 using the radiant heat transfer means and the second heat storage body 4 using the heat transfer means using the heat medium are used in combination. In any of the operating states of the SOFC mode and the SOEC mode, the temperature of the cell stack unit 1 can be controlled to a predetermined temperature.

  Therefore, it is possible to obtain a high temperature heat storage system and a high temperature heat storage method with little system loss even at high temperatures. Moreover, since the heat output of the cell stack part 1 can be stabilized by this, the system efficiency of a hydrogen power storage system can be improved.

  As mentioned above, although embodiment of this invention was described, this embodiment is shown as an example and is not intending limiting the range of invention. This embodiment can be implemented in various other forms, and various omissions, combinations, replacements, and changes can be made without departing from the spirit of the invention. Further, this embodiment and its modifications 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 1 ... Cell stack part, 2 ... 1st thermal storage body, 2a-2d ... 1st thermal storage capsule, 3 ... Gas piping, 4 ... 2nd thermal storage body, 4a-4d ... 2nd thermal storage capsule, 5 ... Compression , 6 ... heat exchanger, 7 ... switching valve (switching device), 8 ... control unit, 9 ... heat medium

Claims (9)

  A cell stack unit having an operation state in a power generation mode and a water electrolysis mode; a first heat storage body provided opposite to the cell stack unit; a compressor for supplying a heat medium to the cell stack unit; and the cell A second heat storage body provided in a heat medium flow path that circulates between the stack part and the compressor; and a switching device that is provided in the heat medium flow path and switches a flow direction of the heat medium with respect to the cell stack part; And a control unit that performs switching control of the switching device and flow rate control of the heat medium.   The control unit performs the switching so that the flow direction of the heat medium with respect to the cell stack unit is reversed depending on whether the operation state of the cell stack unit is the power generation mode or the water electrolysis mode. The high-temperature heat storage system according to claim 1, wherein the apparatus is switched.   The control unit controls the flow rate of the heat medium so that the cell stack unit has a constant temperature regardless of whether the cell stack unit is in the power generation mode or the water electrolysis mode. It controls, The high temperature thermal storage system of Claim 1 or Claim 2 characterized by the above-mentioned.   The first heat storage body includes a plurality of first heat storage capsules, and the heat transfer surfaces of the first heat storage capsules are arranged to be parallel to the heat transfer surfaces of the cell stack portion. The high temperature heat storage system according to any one of claims 1 to 3.   The high-temperature heat storage system according to claim 4, wherein the first heat storage capsule has a rectangular shape.   The said 2nd heat storage body consists of a some cylindrical 2nd heat storage capsule, and is arrange | positioned inside the said heat-medium flow path, The any one of Claims 1 thru | or 5 characterized by the above-mentioned. High temperature heat storage system.   The high-temperature heat storage system according to any one of claims 4 to 6, wherein the first heat storage capsule and / or the second heat storage capsule is filled with a molten salt as a heat storage material.   The high-temperature heat storage system according to claim 1, wherein the heat medium is air supplied to the cell stack unit.   The high temperature thermal storage method characterized by controlling the temperature of a cell stack part using the high temperature thermal storage system of any one of Claims 1 thru | or 8.

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