JP2022003304A - Chemical heat storage device - Google Patents

Abstract

To provide a chemical heat storage device which can inhibit loss of radiation heat from a chemical heat storage medium held in a storage container to improve heat storage efficiency during heat exchange in chemical heat storage.SOLUTION: In order to achieve the above object, a chemical heat storage device includes: a heat storage medium; a heat exchange part which conducts heat exchange between the heat storage medium and a heat medium fluid; and a storage container which stores the heat storage medium and the heat exchange part. A first heat reflection member which is disposed spaced apart from an inner wall of the storage container is provided between the heat storage medium and the storage container. The chemical heat storage device enables radiation heat occurring from the heat storage medium due to the heat exchange to return to the heat storage medium side by the first heat reflection member. Further, the first heat reflection member is disposed spaced apart from the inner wall of the storage container to inhibit absorption of reaction heat into the storage container and thereby attain further heat insulation effect.SELECTED DRAWING: Figure 1

Description

The present invention relates to a chemical heat storage device.

Since a huge amount of waste heat is generated in factories and waste incineration plants, research and development on a heat storage system that stores and uses this waste heat is proceeding from the viewpoint of energy saving and effective utilization of unused energy. Has been done. In particular, chemical heat storage using the chemical reaction of a substance has a much higher heat storage density than actual heat storage or latent heat storage, and if the substance before and after the chemical reaction is stable, there is almost no heat dissipation loss, and in long-term heat storage. It is known that no heat loss occurs.

For example, in Patent Document 1, heat energy such as waste heat is stored in a chemical heat storage material that stores heat energy in the form of a chemical reaction, and the stored chemical heat storage material is stored or transferred to a place where heat energy is required. The chemical heat storage reactor to be used is disclosed.
As a specific example of chemical heat storage, Patent Document 1 describes a system using a calcium hydroxide-based heat storage material as a chemical heat storage material in order to efficiently store waste heat at a high temperature exceeding 400 ° C. When high-temperature waste heat is supplied to calcium hydroxide as a heat supply fluid, calcium oxide is generated by a dehydration reaction, and since this reaction is an endothermic reaction, it is exhibited as a heat storage action. On the other hand, when water (water vapor) is supplied as a heat receiving fluid, calcium oxide produces calcium hydroxide by a hydration reaction, and since this reaction is an exothermic reaction, it is exhibited as a heat dissipation action.
Further, in Patent Document 1, a plurality of fluid (heat supply fluid / heat receiving fluid) flow paths are alternately arranged with a plurality of chemical heat storage materials in the storage container in order to improve the efficiency of heat exchange between the chemical heat storage material and the fluid. Disclosed is an apparatus for arranging a heat receiving and radiating plate of the above along a fluid flow path.

Japanese Unexamined Patent Publication No. 2016-118315

In the conventional chemical heat storage device, waste heat is effectively utilized by selecting the chemical heat storage material and improving the heat exchange efficiency between the chemical heat storage material and the fluid. However, in order to store high-temperature waste heat exceeding 400 degrees Celsius, heat exchange is naturally performed at a high temperature, so that radiant heat loss from the holding member itself that holds the chemical heat storage material cannot be ignored.
Therefore, an object of the present invention is to provide a chemical heat storage device capable of suppressing radiant heat loss from a chemical heat storage material held in a storage container and further improving heat storage efficiency during heat exchange in chemical heat storage. It is in.

As a result of diligent studies on the above problems, it has been found that the heat storage efficiency can be improved by providing a heat reflection member for suppressing radiation between the storage container and the chemical heat storage material in the chemical heat storage device. completed.
That is, the present invention is the following chemical heat storage device.

The chemical heat storage device of the present invention for solving the above problems heats a heat storage medium to separate it into a heat storage product and a generated fluid at the time of heat storage, and reacts the heat storage product with the reaction fluid at the time of heat dissipation to generate the heat. A chemical heat storage device that generates a medium, the heat storage medium, a heat exchange unit through which the heat medium fluid passes, and heat exchange between the heat storage medium and the heat medium fluid, and the heat storage medium and the heat. It is provided with a supply port for accommodating the exchange unit and supplying the heat exchange unit from the outside with a heat medium fluid, and a storage container having a discharge port for discharging the heat medium fluid that has exchanged heat with the heat storage medium to the outside. A first heat-reflecting member is provided between the heat storage medium and the storage container, and the first heat-reflecting member is disposed apart from the inner wall of the storage container.

According to this chemical heat storage device, the radiant heat from the heat storage medium generated by the heat exchange can be returned to the heat storage medium side by the first heat reflection member. Further, by disposing the first heat reflecting member away from the inner wall of the storage container, radiant heat is suppressed from being absorbed by the storage container, and air is provided between the first heat reflecting member and the storage container. A layer is formed and a further heat insulating effect can be obtained.

Further, in one embodiment of the chemical heat storage device of the present invention, the first heat reflecting member is characterized by having a first ventilation portion.
In chemical heat storage that requires the binding and desorption of the chemical heat storage material and the generation / reaction fluid, it is desirable to increase the degree of freedom of movement of the gas after the reaction at the same time as heat shielding. According to this feature, the movement path of the produced fluid after the reaction is formed, so that the heat storage medium and the produced gas can be separated.

Further, one embodiment of the chemical heat storage device of the present invention is characterized in that the first ventilation portion of the first heat reflection member is a slit or a hole formed in the first heat reflection member. Is.
According to this feature, it is possible to form a movement path of the produced fluid after the reaction with a simple configuration.

Further, in one embodiment of the chemical heat storage device of the present invention, a second heat reflection member is provided between the first heat reflection member and the storage container, and the second heat reflection member is the first heat reflection member. It is characterized in that it is arranged apart from both the member and the inner wall of the storage container.
According to this feature, the radiant heat emitted from the first heat reflecting member and the first ventilation portion can be returned to the heat storage medium side by the second heat reflecting member, so that the effect of heat shielding is further improved. Can be made to.

Further, in one embodiment of the chemical heat storage device of the present invention, the second heat reflecting member includes a second ventilation portion, and the second ventilation portion is the first ventilation of the first heat reflection member. It is characterized in that it is arranged so as not to overlap with the portion.
According to this feature, the radiant heat radiated from the first ventilation portion can be returned to the heat storage medium side by the second heat reflection member without passing through the second ventilation portion, so that the heat is shielded more. The effect of can be improved.

According to the chemical heat storage device of the present invention, it is possible to suppress heat release to the storage container due to radiation from the heat storage medium held in the storage container during heat storage. This makes it possible to improve the heat storage efficiency.

It is a schematic explanatory drawing which shows the structure of the chemical heat storage apparatus of the 1st Embodiment of this invention. It is a schematic explanatory drawing which shows the structure of the chemical heat storage apparatus of the 2nd Embodiment of this invention. It is a schematic explanatory drawing which shows the structure of the chemical heat storage apparatus of the 3rd Embodiment of this invention. It is a schematic explanatory drawing which shows the structure of the chemical heat storage apparatus of the 4th Embodiment of this invention.

Embodiments of the present invention will be described in detail with reference to the accompanying drawings.

[Chemical heat storage device]
The chemical heat storage device of the present invention heats a heat storage medium to separate it into a heat storage product and a generated fluid at the time of heat storage, and reacts the heat storage product with the reaction fluid at the time of heat dissipation to generate the heat storage medium. It is a device that can store waste heat generated from factories, waste incineration plants, etc. in a heat storage medium and transport it to heat demand areas that require heat.

The configuration of the heat storage device of the present invention includes a heat storage medium, a heat exchange unit through which the heat medium fluid passes, and heat exchange between the heat storage medium and the heat medium fluid, and the heat storage medium and the heat exchange unit. The heat storage medium is provided with a supply port for supplying the heat medium fluid from the outside to the heat exchange unit, and a storage container having a discharge port for discharging the heat medium fluid that has exchanged heat with the heat storage medium to the outside. A first heat reflecting member is provided between the storage container and the storage container so as to be separated from the inner wall of the storage container.

[First Embodiment]
FIG. 1 is a schematic explanatory view showing the structure of the heat storage device 1a according to the first embodiment of the present invention. The heat storage device 1a includes a heat storage medium 4 and a storage container 2 for storing a holding member 5 for holding the heat storage medium 4, and an external heat medium fluid that exchanges heat with the heat storage medium 4 inside the storage container 2. A heat exchange unit 3 through which the heat exchange unit 3 passes is provided. Further, the storage container 2 is provided with a fluid supply port 8 for supplying the heat medium fluid from the outside and a fluid discharge port 9 for discharging the heat medium fluid to the outside. Further, a first heat reflecting member 6 is arranged between the storage container 2 and the holding member 5 so as to be separated from the inner wall of the storage container 2.
Each configuration will be described in detail below.

(Heat storage medium)
The heat storage medium 4 is a chemical substance that is separated into a heat storage product and a product fluid during heating, and releases heat by the reverse reaction. For example, as heat storage products and generated fluids, calcium oxide (CaO) and water vapor (H ₂ O), calcium chloride (CaCl ₂ ) and water vapor (H ₂ O), calcium bromide (CaBr ₂ ) and water vapor (H ₂ O). ), Calcium iodide (CaI ₂ ) and water vapor (H ₂ O), magnesium oxide (Mg O) and water vapor (H ₂ O), magnesium chloride (MgCl ₂ ) and water vapor (H ₂ O), zinc chloride (ZnCl ₂ ). And water vapor (H ₂ O), strontium chloride (SrCl ₂ ) and ammonia (NH ₃ ), strontium bromide (SrBr ₂ ) and ammonia (NH ₃ ), calcium oxide (CaO) and carbon dioxide (CO ₂ ), magnesium oxide (MgO) and carbon dioxide (CO ₂ ) can be mentioned. From the viewpoint of easy handling, it is preferable that the heat storage medium 4 utilizes water vapor as the production fluid and the reaction fluid.
Further, since the chemical heat storage device in the present invention has a configuration that is particularly effective when chemically storing chemical heat at a high temperature, the heat storage medium 4 in the present invention is a heat storage product and a generated fluid capable of chemically storing chemical heat at a high temperature. , It is preferable to use a combination of calcium oxide and water vapor (400 to 500 degrees) or a combination of magnesium oxide and water vapor (300 to 400 degrees).

The structure and shape of the heat storage medium 4 in the present invention are not particularly limited, and may be powder, a molded body obtained by molding the powder, or a body in which the heat storage medium 4 is supported on a porous body.

The structure of the holding member 5 for holding the heat storage medium 4 is such that the heat storage medium 4 is held in the storage container 2 and heat exchange is possible between the heat storage medium 4 and the heat exchange unit 3. , Not particularly limited. FIG. 1 illustrates a structure in which the heat storage medium 4 is housed in one container, but the present invention is not limited to this, and for example, a configuration in which a plurality of box-shaped containers or tray-shaped containers containing the heat storage medium 4 are stacked. May be.
Further, the material of the holding member 5 is not particularly limited as long as it can withstand high temperature treatment.

(Storage container)
The storage container 2 is configured to store the heat storage medium 4, and is composed of a sealable structure. The storage container 2 has a heat exchange unit 3 through which a fluid for transferring heat between the heat storage medium 4 housed inside and the outside passes, and a heat medium fluid from the outside that exchanges heat with the heat exchange unit 3. It has a fluid supply port 8 for supplying the fluid and a fluid discharge port 9 for discharging the fluid from the heat exchange unit 3.

The heat exchange unit 3 may have any shape as long as it can transfer heat between the heat storage medium 4 housed inside the holding member 5 and the heat medium fluid from the outside. For example, the holding member 5 may have a heat exchange unit 3. It is composed of a heat exchange tube meanderingly installed inside, a double cylindrical inner cylinder portion for the holding member 5, and the like.

The fluid supply port 8 and the fluid discharge port 9 may be arranged on different surfaces with respect to the storage container 2, or may be arranged on the same surface. For example, as shown in FIG. 1, a fluid supply port 8 may be provided at the lower part of the storage container 2 and a fluid discharge port 9 may be provided at the upper part of the storage container 2 along the central axis of the storage container 2. .. Further, since the fluid supply port 8 and the fluid discharge port 9 are provided on the same surface of the storage container 2 and the fluid is supplied and discharged on one surface, the structure of the heat storage device 1a as a whole becomes compact. It is possible to expand the options for the installation location of the heat storage device 1.

Further, the storage container 2 is provided with an air opening port 10 for releasing the generated fluid generated from the heat storage medium 4 during heat storage to the atmosphere, and an air supply port 11 for supplying the reaction fluid that reacts with the heat storage product during heat dissipation. I have. In the heat storage device 1a of the first embodiment, the atmosphere opening port 10 and the air supply port 11 use the same ventilation port, but they may be provided at different positions.

The atmosphere opening 10 is configured to be opened at the time of heat storage and to discharge the generated fluid generated from the heat storage medium 4 to the outside of the storage container 2. May be good. By having the atmosphere opening 10, the generated fluid is discharged to the outside, so that it is not necessary to provide a liquid receiving tank for agglomerating and collecting the generated fluid, and the generated fluid is transferred from the heat supply area to the heat demand area. There is no need to transport it. Therefore, there are advantages such as downsizing of the device and reduction of transportation cost.

The air supply port 11 is opened at the time of heat dissipation and is configured to supply the reaction fluid to the storage container 2, and is connected to a supply unit (not shown) for supplying the reaction fluid at the time of heat dissipation.

The heat medium fluid may be a fluid having a temperature capable of supplying heat to the heat storage medium 4, and a fluid such as a gas or a liquid is preferable. Further, from the viewpoint of excellent handleability, it is particularly preferable to use a gas.

(First heat reflecting member)
The first heat reflection member 6 is provided between the storage container 2 and the heat storage medium 4, and is disposed apart from the inner wall of the storage container 2.

The first heat reflection member 6 is configured to reflect the radiant heat released from the holding member 5 that holds the heat storage medium 4 at the time of heat storage to the heat storage medium 4 side again. By providing the first heat reflecting member 6, it is possible to suppress the absorption of radiant heat into the storage container 2, and the heat storage effect is improved. Further, by disposing the storage container 2 away from the inner wall, an air layer is formed between the first heat reflecting member 6 and the storage container 2, and a further heat insulating effect can be obtained.

The specific structure of the first heat reflecting member 6 is not particularly limited as long as it is configured to reflect the radiant heat emitted from the holding member 5 toward the heat storage medium 4, and as shown in FIG. 1, for example, holding. It may have a box-shaped structure that surrounds the entire member 5 or a tubular structure that is arranged so as to surround the periphery of the holding member 5. Further, the first heat reflecting member 6 may have a configuration in which a tubular structure surrounding the holding member 5 and a structure covering either the upper or lower side of the holding member 5 are combined. Further, the first heat reflecting member 6 may have a structure having a curved surface so that heat can be effectively collected on the heat storage medium 4 side.

The first heat reflecting member 6 is made of a material capable of reflecting radiant heat. Examples of such a material include aluminum, iron, copper, brass, silver, gold, platinum, nickel, stainless steel, chromium, tungsten and the like. Examples of non-metals include quartz glass, alumina ceramics, magnesia ceramics, and refractory bricks.

Further, it is desirable to select the first heat reflecting member 6 in the present invention in consideration of the emissivity of the above material. From the relationship of reflectance = 1-emissivity, the lower the emissivity, the higher the reflectance of the material. The emissivity is a value defined in JISZ8117 as the ratio of the radiation divergence of the radiator to the radiation divergence of the black body at the same temperature as the radiator, and the emissivity measurement value is the FTIR specified in JIS R1801. It is obtained by measuring the spectral emissivity with. The emissivity is a temperature-dependent parameter.
The emissivity of the material also depends on the surface condition of the material. Since the less uneven the surface is, the lower the emissivity is exhibited, so that a metal material having a polished surface is more preferable than an oxidized surface and a rough surface.
As the first heat reflecting member 6 in the present invention, a member having an emissivity of 0.5 or less, more preferably 0.1 or less, still more preferably 0.05 or less at the temperature at the time of heat storage is used.

[Other aspects of heat storage equipment]
The following is an example of another aspect of the heat storage device.
[Second embodiment]
FIG. 2 is a schematic explanatory view showing the structure of the heat storage device 1b according to the second embodiment of the present invention.
The heat storage device 1b is configured to provide the first heat reflecting member 6 with the first ventilation portion 61 in the heat storage device 1a of the first embodiment. In chemical heat storage that requires the binding and desorption of chemical heat storage material and generation / reaction fluid, it is desirable to increase the degree of freedom of gas movement at the same time as heat shielding. According to this heat storage device 1b, since the movement path of the generated fluid after the reaction is formed, the heat storage medium and the generated fluid can be efficiently separated, and the heat exchange efficiency can be improved.

As a configuration in which the first ventilation portion 61 is provided in the first heat reflection member 6 in the heat storage device 1b of the second embodiment, as shown in FIG. 2, a configuration in which a plurality of plate-shaped members are arranged in a louver shape or , The plate-shaped member can be configured to have a slit or a hole as a vent.
In particular, the first ventilation portion 61 in the present invention preferably has a configuration in which a ventilation port is provided in the plate-shaped member. With this configuration, it is possible to induce the separation of the generated fluid from the heat storage medium with a simple configuration.

[Third Embodiment]
FIG. 3 is a schematic explanatory view showing the structure of the heat storage device 1c according to the third embodiment of the present invention.
In the heat storage device 1b of the first embodiment, the heat storage device 1c is provided with a second heat reflection member 7 outside the first heat reflection member 6, and the second heat reflection member 7 is a storage container 2. It is configured to be disposed apart from the inner wall of the above and the first heat reflecting member 6. According to this heat storage device 1c, the radiant heat emitted through the first heat reflecting member 6 or the radiant heat released from the first ventilation unit 61 can also be reflected to the heat storage medium 4 side. , The heat storage effect can be further improved.

The specific structure of the second heat reflecting member 7 is particularly limited as long as it is configured to reflect the radiant heat emitted from the holding member 5 toward the heat storage medium 4, similarly to the first heat reflecting member 6. Instead, for example, a box-shaped structure that surrounds the entire holding member 5 or a tubular structure that is arranged so as to surround the periphery of the holding member 5 may be used. Further, the second heat reflecting member 7 may have a configuration in which a tubular structure surrounding the holding member 5 and a structure covering either the upper or lower side of the holding member 5 are combined. Further, the second heat reflecting member 7 may have a structure having a curved surface so that heat can be effectively collected on the heat storage medium 4 side.

The second heat reflecting member 7 is made of a material capable of reflecting radiant heat. Examples of such a material include aluminum, iron, copper, brass, silver, gold, platinum, nickel, stainless steel, chromium, tungsten and the like. Examples of non-metals include quartz glass, alumina ceramics, magnesia ceramics, and refractory bricks.

Further, it is desirable to select the second heat reflecting member 7 in the present invention in consideration of the emissivity of the above material.
As the second heat reflecting member 7 in the present invention, a material having an emissivity of 0.5 or less, more preferably 0.1 or less, still more preferably 0.05 or less at the temperature at the time of heat storage is used.
The second heat reflecting member 7 and the first heat reflecting member 6 may be made of the same material or may be made of different materials.

[Fourth Embodiment]
FIG. 4 is a schematic explanatory view showing the structure of the heat storage device 1d according to the fourth embodiment of the present invention.
The heat storage device 1d is configured to provide a second ventilation portion 71 on the second heat reflection member 7 in the heat storage device 1c of the third embodiment. According to this heat storage device 1d, since the movement path of the generated fluid after the reaction is formed in both of the two heat reflecting members, the heat storage medium and the generated fluid are efficiently separated, and the heat exchange efficiency is improved. Can be done.

As a configuration in which the second ventilation portion 71 is provided in the second heat reflection member 7 in the heat storage device 1d of the fourth embodiment, a configuration in which a plurality of plate-shaped members are arranged in a louver shape or as shown in FIG. In addition, the plate-shaped member can be configured to have a slit or a hole as a vent.
Further, as the configuration of the second ventilation portion 71 in the present invention, as shown in FIG. 4, it is particularly preferable that the structure and arrangement do not overlap with the first ventilation portion 61. With this configuration, the radiant heat radiated from the first ventilation unit 61 can be returned to the heat storage medium 4 side by the second heat reflection member 7 without passing through the second ventilation unit 71 as it is. Therefore, the effect of heat shielding can be further improved.

The application of the chemical heat storage device of the present invention is used as a method for effectively utilizing waste heat generated from a factory, a waste incinerator, or the like. For example, the chemical heat storage device of the present invention is stored in a heat supply area where waste heat is generated, and the heat storage device is transported to a heat demand area where heat is required to dissipate heat. It can also be used as a method of storing heat in the same installation location during the time when waste heat is generated and dissipating heat during the time when heat is required, such as storing heat in the daytime and dissipating heat at night. can.

1a, 1b, 1c, 1d ... Chemical heat storage device, 2 ... Storage container, 3 ... Heat exchange section, 4 ... Heat storage medium, 5 ... Holding member, 6 ... First heat reflection member, 61 ... First ventilation section, 7 ... 2nd heat reflection member, 71 ... 2nd ventilation part, 8 ... fluid supply port, 9 ... fluid discharge port, 10 ... atmosphere opening port, 11 ... air supply port

Claims (5)

A chemical heat storage device that heats a heat storage medium to separate it into a heat storage product and a product fluid at the time of heat storage, and reacts the heat storage product with the reaction fluid to generate the heat storage medium at the time of heat dissipation.
With the heat storage medium
A heat exchange unit through which the heat medium fluid passes and exchanges heat between the heat storage medium and the heat medium fluid.
A storage having a supply port for storing the heat storage medium and the heat exchange section and supplying the heat medium fluid from the outside to the heat exchange section, and a discharge port for discharging the heat medium fluid that has exchanged heat with the heat storage medium to the outside. With a container,
A chemical heat storage device characterized in that a first heat reflection member is provided between the heat storage medium and the storage container, and the first heat reflection member is disposed apart from the inner wall of the storage container. The chemical heat storage device according to claim 1, wherein the first heat reflection member has a first ventilation portion. The chemical heat storage device according to claim 2, wherein the first ventilation portion is a slit or a hole formed in the first heat reflection member. A second heat-reflecting member is provided between the first heat-reflecting member and the storage container, and the second heat-reflecting member is separated from both the first heat-reflecting member and the inner wall of the storage container. The chemical heat storage device according to any one of claims 1 to 3, wherein the chemical heat storage device is provided. The second heat reflecting member includes a second ventilation portion, and the second ventilation portion is arranged so as not to overlap with the first ventilation portion of the first heat reflection member. The chemical heat storage device according to claim 4.

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