JP2021173510A - Warming instrument heat storage method - Google Patents

Abstract

To easily improve heat storage efficiency of a warming instrument having a heat storage material enclosed in a mat type container.SOLUTION: A mat 1 for disaster-time use formed by enclosing a latent heat storage material composition 21, so colored as to increase absorption of the sunlight, in a transparent mat type container 11 is arranged at a predetermined position 52 of a solar cooker 51 put on the market, and exposed to the sunlight. The mat 1 for disaster-time use stores heat in the latent heat storage material composition 21 as the sunlight collected through the solar cooker 51 is transmitted through the mat type container 11 and absorbed directly by the latent heat storage material composition 21.SELECTED DRAWING: Figure 2

Description

The present invention relates to a heat storage tool heat storage method for storing heat in a latent heat storage material for a heat storage tool in which a heat storage material is sealed in a mat-shaped container.

For example, Patent Document 1 discloses a heating device that can easily heat a sleeping futon like a hot water bottle. This warming tool covers a container or bag containing a latent heat storage material with a cloth bag of a color having a high sunlight absorption rate, or a container or bag of a color (for example, black) having a high sunlight absorption rate. It is constructed by enclosing a latent heat storage material. The heating tool is housed in a casing and stores heat in a latent heat storage material. The casing is provided with a rectangular cross-sectional shape of a space for storing a heating tool, a transparent plate is attached to be openable / closable or detachable, and the surface of the space is covered with a reflector.

For example, Patent Document 2 discloses a heating tool in which a latent heat storage material is sealed in a mat-like container having a black surface.

For example, in Patent Document 3, a latent heat storage material containing a colorant having a pigment that develops a color that promotes absorption of sunlight (for example, black) is formed of a resin material having a transparent surface and transmitting sunlight. A heating device enclosed in a mat-shaped container is disclosed. In this technology, when the mat-shaped container is exposed to sunlight, the latent heat storage material efficiently absorbs the heat generated by sunlight.

Utility Model Registration No. 3165721 Japanese Unexamined Patent Publication No. 2019-155000 Japanese Unexamined Patent Publication No. 2020-12804

However, the conventional heating tool has the following problems. That is, the heat collecting tool described in Patent Document 1 has a color in which a container or bag containing a latent heat storage material or a cloth bag covering the container or bag containing a latent heat storage material has a high solar absorption rate. It was colored with and absorbed the energy of sunlight. Therefore, the latent heat storage material transfers the energy absorbed by the container or bag or the cloth bag, and stores heat in order from the portion in contact with the container or bag, and it takes a long time to store heat. In addition, the casing for storing the heating equipment is a special product, and it was highly expected that it would be difficult to obtain it in the event of a disaster or the like.

Further, the heating tool described in Patent Document 2 has a black mat-like container, and has a latent heat time for the same reason as the heating tool in Patent Document 1. Further, Patent Document 2 only discloses a method of placing the heat collecting tool alone in the sun to store heat in the latent heat storage material, and there is room for improvement in the heat storage method of the heat collecting tool.

Further, in the heating tool described in Patent Document 3, a latent heat storage material to which a colorant colored in a color that easily absorbs sunlight is added is sealed in a mat-like container having a transparent surface, and the latent heat is latent. The heat storage material directly absorbs the energy of sunlight and stores heat. However, Patent Document 3 only discloses a method in which the heat collecting tool is placed alone in the sun to store heat in the latent heat storage material, and there is room for improvement in the heat storage method of the heat collecting tool.

The present invention has been made to solve the above-mentioned problems, and is used to easily improve the heat storage efficiency in a heat storage tool heat storage method for storing heat in a heat storage material for a heat storage tool in which a heat storage material is sealed in a mat-shaped container. The purpose is to provide a technology that can be used.

One aspect of the present invention has the following configuration. (1) About a heating tool in which a heat storage material is enclosed in a mat-shaped container A heat collecting tool is a heat storage method for storing heat in the heat storage material, wherein the mat-shaped container is made of a transparent bag body. The heat storage material is colored in a color that promotes the absorption of sunlight. It is characterized by being placed and exposed to sunlight.

In the heat storage method of a heat storage tool having the above configuration, a heat storage tool formed by enclosing a heat storage material colored in a color that promotes absorption of sunlight in a transparent mat-shaped container is placed at a predetermined position of a commercially available solar bacca, and sunlight is generated. Expose to. The energy of sunlight is collected in the heating device via the solar bacca, passes through the mat-like container, and is directly absorbed by the heat storage material. Therefore, according to the heat storage method for the heating tool having the above configuration, it is possible to easily store the heat storage material for the heating tool by using a commercially available solar bacca that is easily available.

(2) In the heat collecting tool heat storage method according to (1), the solar ucca includes a panel portion for collecting heat from the sunlight at the predetermined position, and a surface of the panel portion located on the predetermined position side is included. It is preferably formed with a glossy mirror surface.

In the heat storage method of the heat storage tool having the above configuration, sunlight can be efficiently collected in the heat storage tool through the panel portion formed by the mirror surface, so that the heat storage time for storing heat in the heat storage material can be shortened.

(3) In the heat storage method according to (1) or (2), the heat collecting tool is placed in the predetermined position in a state where the warming tool is placed in a first transparent member made of a bag body made of a transparent material. It is preferable to arrange it in.

In the heat storage method of the heating tool having the above configuration, an air layer is formed between the first transparent member and the heating tool, so that when the heating tool is exposed to sunlight, it convects on the surface of the heating tool by wind or the like. Prevents the occurrence of. Therefore, the heat storage material of the heat collecting tool is less likely to take away heat from the outside air during heat storage, and can efficiently store heat.

(4) In the heat storage method for heating equipment according to any one of (1) to (3), the heating equipment is arranged at a predetermined position on a second transparent member made of a bag made of a transparent material. It is preferable to put the sorakukka and expose it to the sunlight.

According to the heat storage method of the heating tool having the above configuration, by forming an air layer between the second transparent member and the heating tool, when the solar bacca in which the heating tool is arranged at a predetermined position is exposed to sunlight, Prevents convection from occurring on the surface of the heating equipment due to wind or the like. Therefore, the heat storage material of the heat collecting tool is less likely to take away heat from the outside air during heat storage, and can efficiently store heat.

(5) In the heat collecting tool heat storage method according to any one of (1) to (3), the solar racker in which the warming tool is arranged at a predetermined position so as to form an air layer around the warming tool. It is preferable to expose the heat collecting tool to the sunlight while covering the surface with a third transparent member made of a sheet made of a transparent material.

According to the heat storage method of the heating tool having the above configuration, the solar racker in which the heating tool is arranged at a predetermined position is covered with a third transparent member, and an air layer is formed around the heating tool to arrange the heating tool at a predetermined position. Prevents convection from occurring on the surface of the heating equipment due to wind, etc. when the Sorakka is exposed to sunlight. Therefore, the heat storage material of the heat collecting tool is less likely to take away heat from the outside air during heat storage, and can efficiently store heat.

(6) In the heat storage method for heating equipment according to any one of (1) to (5), the heating equipment is placed in the predetermined position in a state where the heating equipment is put in a metal container filled with water. It is preferable to do so.

According to the heat storage method of the heating tool having the above configuration, the water filled in the metal container is heated and the heated water is used as a medium to store the heat in the heat storage material of the heating tool. Heat can be stored uniformly in the heat storage material.

(7) In the heat storage tool heat storage method according to any one of (1) to (6), it is preferable that a display unit indicating the heat storage state of the heat storage material is provided on the surface of the mat-shaped container. ..

Anyone can easily determine whether or not the heat storage material has reached the melting point based on the heat storage state indicated on the display unit in the heat storage method for the heat collecting tool having the above configuration.

According to the present invention, it is possible to realize a technique capable of easily improving the heat storage efficiency in a heat storage tool heat storage method for storing heat in a heat storage material for a heat storage tool in which a heat storage material is sealed in a mat-shaped container.

It is a figure which shows the mat for the time of disaster used for the heat storage method of the heating tool of this embodiment. It is a figure which shows the use example of the mat for disasters used in the heat storage method of the heating tool of this embodiment. It is a figure which shows typically the constituents of the heat storage material composition used for the mat for disasters shown in FIG. It is a figure explaining the heat storage method. It is a table which shows the test condition of the 1st heat storage performance evaluation test. It is a graph which shows the result of the 1st heat storage performance evaluation test. It is a table which shows the test condition of the 2nd heat storage performance evaluation test. It is a graph which shows the result of the 2nd heat storage performance evaluation test. It is a table which shows the test condition of the 3rd heat storage performance evaluation test. It is a graph which shows the result of the 3rd heat storage performance evaluation test. It is a figure explaining the 1st modification of the heat storage method. It is a figure explaining the 2nd modification of the heat storage method. It is a figure explaining the 3rd modification of the heat storage method.

Hereinafter, an embodiment in which the heat storage method of the heat collection tool that stores heat in the heat storage material of the heat collection tool is embodied will be described in detail with reference to the attached drawings. This embodiment discloses, for example, a heat storage method for storing heat in a heat storage material of a heat collecting mat used in the event of a natural disaster.

<About mats for disasters>
FIG. 1 is a diagram showing a disaster mat 1 used in the heat storage method of the heating tool of the present embodiment. The disaster mat 1 of the present embodiment is a disaster mat for warming up. The disaster mat 1 is formed by enclosing the latent heat storage material composition 21 in a mat-shaped container 11 made of a mat-shaped transparent bag body. The disaster mat 1 is an example of a “warming tool”. The latent heat storage material composition 21 is an example of a “heat storage material”.

As the latent heat storage material composition 21, a material having a performance of keeping the temperature around the mat 1 for a disaster such as in a bed at 30 ° C to 40 ° C is used. If the temperature around the disaster mat 1 such as in the bed is kept at 30 ° C to 40 ° C, the user is less likely to cause low-temperature burns even if he / she directly touches the disaster mat 1. The disaster mat 1 may be about the size of a hot water bottle or an electric pad, or it may be large enough to cover the bed. You can warm your favorite parts such as your legs, abdomen, and lower body.

The latent heat storage material composition 21 is a mixture containing the latent heat storage material as a main component. The latent heat storage material composition 21 is blended with a colorant colored in a color that promotes the absorption of sunlight, and is colored in a color that promotes the absorption of sunlight. In the present embodiment, the colorant colored in black is added, and the latent heat storage material composition 21 is colored in black.

The mat-shaped container 11 in which the latent heat storage material composition 21 is sealed is made of a transparent material. Therefore, sunlight passes through the transparent mat-shaped container 11 and is directly absorbed by the latent heat storage material composition 21. The mat-shaped container is preferably a resin material in consideration of heat resistance, weather resistance, and reactivity with the latent heat storage material composition 21. The material of the mat-shaped container 11 is, for example, PVC (polyvinyl chloride), PP (polypropylene), PE (polyethylene), PET (polyethylene terephthalate).

The latent heat storage material contained in the latent heat storage material composition 21 has a supercooling function. The supercooling function is a function of developing a supercooled state in which when the melt of the latent heat storage material is cooled, it does not solidify at a temperature lower than the solidification temperature and maintains a liquid state. The mat-shaped container 11 is sealed with a metal piece 31 for releasing the supercooled state of the latent heat storage material. The metal piece 31 is pressed or bent and operated from the outside of the mat-shaped container 11 to release the supercooled state of the latent heat storage material.

When the latent heat storage material composition 21 begins to undergo a phase change from a liquid to a solid, the latent heat associated with solidification is released from the latent heat storage material to the surroundings, and the temperature rises. The temperature of the latent heat storage material composition 21 decreases when the phase change from liquid to solid is completed.

The disaster mat 1 is provided with a display unit 41 indicating the heat storage state of the latent heat storage material composition 21 on the surface of the mat-shaped container 11. The display unit 41 is, for example, a sticker or a sheet that allows the surface temperature level of a general-purpose product to be confirmed by color, and is attached to the surface of the mat-shaped container 11. The temperature of the mat-shaped container 11 is substantially the same as that of the latent heat storage material composition 21 of the contents. Therefore, the heat storage state of the latent heat storage material can be confirmed from the display state of the display unit 41.

The display unit 41 may be formed by coloring the mat-like container 11 with a paint, dye, or the like that allows the surface temperature level of a general-purpose product to be confirmed by color. The details of the latent heat storage material composition 21 will be described later.

<Examples of using mats for disasters>
FIG. 2 is a diagram showing an example of use of the disaster mat 1 used in the heat storage method of the heating tool of the present embodiment. The disaster mat 1 is used when warmth is required. The disaster mat 1 is used, for example, in a disaster shelter in winter when the heating equipment is not perfect.

In use, first, as shown in FIG. 2A, heat is stored in the latent heat storage material composition 21 of the mat 1 for disasters by using Sorakka 51. The heat storage method of the disaster mat 1 will be described later. Even if the heat storage is completed, the latent heat storage material maintains the supercooling function until the metal piece 31 is operated, and does not dissipate heat.

As shown in FIG. 2B, in the disaster mat 1 that stores heat in the latent heat storage material, for example, the user operates the metal piece 31 from the outside of the mat-shaped container 11 before going to bed to cover the latent heat storage material. Release the supercooling function. As a result, the latent heat storage material of the mat 1 for disasters begins to dissipate heat. The disaster mat 1 is put between the mattress 13 laid on the cardboard bed 12 and the comforter 14, and warms the inside of the bed with the heat released from the latent heat storage material. The inside of the bed is heated to around 34 ° C., which is a comfortable bed temperature, for example.

The disaster mat 1 can be released from the supercooled state by operating the metal piece 31. Therefore, the user can start heat dissipation to the latent heat storage material at any time, not only before going to bed.

The disaster mat 1 not only warms the inside of the bed, but also applies it to the user's feet and abdomen as shown in FIG. 2 (c), thereby locally locating the part where the user needs warming. Can be warmed up. As described above, the disaster mat 1 can be used repeatedly by absorbing energy such as sunlight again in the latent heat storage material after heat dissipation and storing the heat.

Although not shown in FIG. 2 or the like, when the heat insulating material is laminated on the lower surface 11b of the mat-shaped container 11, the heat released from the latent heat storage material is on the lower surface 11b side of the mat-shaped container 11. It can be suppressed from being released from. Therefore, heat can be dissipated more effectively to the upper surface 11a side of the mat-shaped container 11 to be warmed.

As described above, the disaster mat 1 of the present embodiment can efficiently collect the energy of sunlight by using the solar bacca 51 to store the latent heat storage material and can be used repeatedly without using a power source. Therefore, the mat 1 for disasters can be expected to improve the evacuation environment by appropriately warming the bedding and the like to smoothly induce sleep even in an evacuation center where the heating equipment is not perfect in winter.

<Latent heat storage material composition>
FIG. 3 is a schematic view showing the constituent components of the latent heat storage material composition 21. The latent heat storage material composition 21 contains the latent heat storage material 23, which is an inorganic salt hydrate, as a main component, and contains two types of additives 28 (melting point adjusters) for adjusting the state or physical properties of the latent heat storage material 23 in the present embodiment. 24, colorant 25) is blended, and the physical properties are adjusted to a melting temperature of 30 to 58 ° C. The latent heat storage material 23 is an inorganic salt hydrate containing at least one of an acetate or a sulfate, and heat storage or heat dissipation thereof is performed by utilizing the inflow and outflow of latent heat accompanying a phase change.

Of the two types of additives 28, the first additive is a colorant having a pigment that develops a color that promotes absorption of sunlight (for example, black, a dark color such as brown that is infinitely similar to black). 25. The second additive, which is an additive 28 different from the colorant 25, is a melting point adjusting agent 24 that adjusts the melting temperature of the latent heat storage material composition 21.

When the latent heat storage material composition 21 is in the liquid phase state, the colorant 25 is dispersed in the melt of the latent heat storage material 23, and when the latent heat storage material composition 21 is in the solid phase state, the colorant 25 Is dispersed among the particles of the latent heat storage material 23, and the entire latent heat storage material composition 21 is colored black by the colorant 25.

Explaining by giving a specific example, the latent heat storage material 23 of the embodiment is sodium acetate trihydrate (CH ₃ COONa · 3H ₂ O) which is a kind of acetate. The physical characteristics of sodium acetate trihydrate alone are a hydration number of 3, a molecular weight of [g / mol] of 136.08, a melting point of about 58 ° C., and a solid substance that is easily soluble in water at a temperature lower than the melting point.

In addition to sodium acetate trihydrate, the latent heat storage material 23 made of inorganic salt hydrate is, for example, sodium sulfate decahydrate (Na ₂ SO ₄・ 10H ₂ O), which is a kind of sulfate. Even if it is a mixture containing two or more kinds, or a heat storage material containing mixed crystals as a main component, such as in the first case or in the second case where a mixture of sodium acetate trihydrate and sodium sulfate decahydrate is used. good. The physical characteristics of sodium sulfate decahydrate alone are a solid substance having a hydration number of 10, a molecular weight of [g / mol] 322.21, a melting point of 32.38 ° C., and a temperature lower than the melting point, which is soluble in water. However, in the first case, since the melting point of sodium sulfate decahydrate alone is 32.38 ° C., which is near the lower limit of the melting temperature of the desired latent heat storage material composition 21 of 30 to 58 ° C., the latent heat storage material composition The use of 21 may be restricted.

The colorant 25 is a liquid carbon dye containing carbon as a main component, and does not chemically react with the latent heat storage material 23 (sodium acetate trihydrate) and the melting point adjusting agent 24 which is a substance of sugar alcohols described later. It is a substance with properties. Further, the colorant 25 is a non-hazardous substance, non-toxic, highly safe, has excellent heat resistance, and is a dye that can be colored in a stable state without deterioration even in a use environment exposed to direct sunlight. The colorant 25 may be a powdery dye in addition to the liquid dye as in the present embodiment, and its properties are particularly limited as long as it is a dye that can color the entire latent heat storage material composition 21. is not it.

Further, unlike the latent heat storage material 23, the colorant 25 does not have heat storage characteristics, and therefore is added in a range of more than 0 wt% and 1 wt% or less. If the amount of the colorant 25 added is within this range, the latent heat storage material composition 21 to which the colorant 25 is added is significantly lower than the heat storage amount of the latent heat storage material 23 alone, even when compared in the same volume. Can be suppressed. In addition, if the colorant 25 is blended in the latent heat storage material composition 21 in such an added amount, the entire latent heat storage material composition 21 is uniformly colored black, which is the color of the pigment of the colorant 25. This is because it can be sufficiently colored.

The melting point adjusting agent 24 is a substance containing at least a substance belonging to sugar alcohols mainly used as a food additive and having a physical property of generating negative heat of dissolution by dissolution with the latent heat storage material 23. Sugar alcohol is a type of sugar produced by reducing the carbonyl group of aldose and ketose, and dissolves in water. In this embodiment, glycerin, which can serve as both a melting point lowering agent and a thickener, is used as the melting point adjusting agent 24. Glycerin is added to a sodium acetate trihydrate having a melting point of about 58 ° C. in the range of 10 wt% or more and 30 wt% or less. Within this range, the latent heat storage material composition 21 to which glycerin is added can adjust the melting point to about 40 ° C., and the hardness at the time of solidification is relaxed to a softness that can be deformed according to an external force.

Instead of glycerin, a melting point adjusting agent and a thickener may be individually blended in the latent heat storage material 23. For example, xylitol (C ₅ H ₁₂ O _{5 ) or the like is used as a melting point adjuster, and erythritol (C 4} H ₁₀ O ₄ ), mannitol (C ₆ H ₁₄ O ₆ ), gellan gum (gellan) or the like is used as a thickener. Gum) (also known as gellan, polysaccharide S-60 [abbreviation: PS-60]) or the like may be used.

Here, the definition of the above-mentioned "substance having physical properties that generate negative heat of change" will be described. As described above, the latent heat storage material composition 21 is composed of a latent heat storage material 23 made of sodium acetate trihydrate as a main component and a melting point adjusting agent 24. When the melting point adjusting agent 24 is dissolved in the latent heat storage material 23, the melting point adjusting agent 24 absorbs heat from the outside and causes a heat absorption reaction. It is defined as "a substance having physical properties that generate heat of dissolution".

In addition to the above-exemplified erythritol, xylitol, and mannitol, examples of "substances having physical properties that generate negative heat of change" include sorbitol (C ₆ H ₁₄ O ₆ ) and lactitol (C ₁₂ H ₂₄ O). There are "substances belonging to sugar alcohols" such as _11). Further, calcium chloride hexahydrate _{(CaCl 2 · 6H 2 O)} , magnesium chloride hexahydrate _{(MgCl 2 · 6H 2 O)} , belongs to the potassium chloride (KCl), "the chloride such as sodium chloride (NaCl) There is a "substance". In addition, it also corresponds to the case where at least one or more of the substances corresponding to the above-mentioned "substances belonging to sugar alcohols" are contained, and the case where at least one or more of the substances corresponding to the above-mentioned "substances belonging to chlorides" are contained. do. Further, there is also a mixture of any of the substances corresponding to the above-mentioned "substances belonging to sugar alcohols" and any of the substances corresponding to the above-mentioned "substances belonging to chlorides".

In the present embodiment, as described above, the latent heat storage material 23 which is the main component of the latent heat storage material composition 21 is sodium acetate trihydrate. Sodium acetate trihydrate is a physical property that is particularly likely to cause a supercooling phenomenon among the latent heat storage materials of the inorganic salt hydrate type. Therefore, a metal piece 31 is added to the latent heat storage material composition 21 in order to release the supercooled state of the sodium acetate trihydrate.

The size and number of the metal pieces 31 can be arbitrarily set as long as they do not affect the performance of the latent heat storage material 23. Considering the operability of the metal piece 31, it is preferable to provide one piece having a size that can be operated by hand.

Instead of the metal piece 31, an overcooling inhibitor may be added to the latent heat storage material 23. The anti-supercooling agent is, for example, anhydrous disodium hydrogen phosphate (Na ₂ HPO ₄ ).

<About heat storage method>
FIG. 4 is a diagram illustrating a heat storage method. As shown in FIG. 4 (a), the disaster mat 1 is put in the transparent bag 61, and as shown in FIG. 4 (b), the mouth of the transparent bag 61 is closed. As a result, an air layer 62 is formed between the transparent bag 61 and the disaster mat 1, and the inflow and outflow of heat is restricted. The transparent bag 61 is a transparent member made of a bag body made of a transparent material and can transmit sunlight. The transparent bag 61 is an example of the "first transparent member".

As shown in FIG. 4 (c), the disaster mat 1 placed in the transparent bag 61 is arranged at a predetermined position 52 in which the ingredients of the solar bacca 51 are installed.

Sorakka 51 is a commercially available product that is relatively easy to obtain. Therefore, for example, the Sorakukka 51 can be stockpiled and handed to the disaster victim as a set of the disaster mat 1 and the Sorakukka 51 in the event of a disaster. In addition, Sorakka 51 is convenient because it can also be used for cooking foodstuffs.

The Sorakka 51 is formed by assembling a cardboard 53. Therefore, the Sorakka 51 can be folded into a small size and stored when not in use, and is less likely to get in the way in, for example, an evacuation center where the living space is limited. In addition, since the corrugated cardboard Sorakka 51 is lightweight, anyone can easily handle it.

The Sorakka 51 includes a plurality of panel portions 55 so as to surround the predetermined position 52. The panel portion 55 is oriented three-dimensionally with respect to the predetermined position 52 so that the energy of the sunlight can be collected at the predetermined position 52 without changing the direction of the solar backer 51 according to the movement of the sun. .. The shapes, positions, and orientations of the plurality of panel portions 55 may be different from those of the present embodiment.

In each panel portion 55, the inner surface 55a located on the inner side (predetermined position 52 side) is formed of a glossy mirror surface. The inner surface 55a is an example of a "face". For example, the inner surface 55a is formed by sticking a thin aluminum sheet 54 on the surface of the cardboard 53. As a result, the solar bacca 51 has a high reflection efficiency of sunlight at each panel portion 55, and can efficiently collect sunlight at a predetermined position 52. The surface of the predetermined position 52 may also be formed with a glossy mirror surface. According to this, the sunlight transmitted through the disaster mat 1 is reflected at the predetermined position 52, and is again incident on the disaster mat 1 to store heat in the latent heat storage material 23.

The Sorakka 51 is installed outdoors or indoors in a sunny place, for example, with the predetermined position 52 in which the disaster mat 1 is arranged facing south. At this time, it is advisable to fix the sorakukka 51 so that the sorakukka 51 does not fall down due to wind or the like. The sunlight not only directly irradiates the disaster mat 1 arranged at the predetermined position 52, but also reflects off the inner surface 55a of the panel portion 55 and indirectly irradiates the disaster mat 1.

Moreover, the inner surface 55a of the panel portion 55 is formed of a glossy mirror surface. Therefore, the sunlight reaches the disaster mat 1 with almost no energy loss when reflected by the inner surface 55a. Therefore, the disaster mat 1 can obtain the same energy as the sunlight directly hitting the mat 1 from the sunlight reflected on the inner surface 55a.

Further, the disaster mat 1 is obtained by enclosing the latent heat storage material composition 21 colored in black in a transparent mat-like container 11, and the surface is black. Therefore, the disaster mat 1 can easily collect the energy of sunlight. The disaster mat 1 is put in a transparent bag 61. However, since the transparent bag 61 is made of a transparent material, sunlight passes through the transparent bag 61 and reaches the surface of the mat 1 in the event of a disaster with almost no energy loss.

Therefore, the surface of the mat 1 for disasters is black and it is easy to collect the energy of sunlight, and the energy of sunlight is collected by using the solar accca 51. When exposed to sunlight while being placed at position 52, heat can be efficiently collected from sunlight.

The sunlight that reaches the surface of the disaster mat 1 passes through the transparent mat-shaped container 11 and enters the latent heat storage material composition 21. The latent heat storage material 23, which is the main component of the latent heat storage material composition 21, is a colorless and transparent sodium acetate trihydrate like water at room temperature. The black colorant 25 is widely dispersed in the liquid latent heat storage material 23. Therefore, the sunlight transmitted through the mat-shaped container 11 is absorbed by the colorant 25 dispersed in the latent heat storage material 23, and travels between the latent heat storage materials 23. Therefore, sunlight is stored in latent heat while directly absorbing energy not only in the latent heat storage material 23 existing in the portion in contact with the mat-shaped container 11 but also in the latent heat storage material 23 existing in the center or bottom of the mat-shaped container 11. Proceed through the material composition 21. Therefore, in the latent heat storage material composition 21, the latent heat storage material 23 receives a large amount of sunlight and can efficiently store heat.

By adjusting the installation position and orientation of the Sorakka 51 according to the position and altitude of the sun, the sunlight can be efficiently applied to the mat 1 for disasters. According to this, in the disaster mat 1, the latent heat storage material 23 continues to efficiently absorb the energy of sunlight, and the heat storage time is shortened.

However, in the Sorakka 51, the orientation of the inner surface 55a of the panel portion 55 is three-dimensionally different from the predetermined position 52. Therefore, after the user installs the Sorakka 51 in the south direction, it is necessary to change the direction of the Sorakka 51 according to the movement or altitude of the sun until the heat storage of the latent heat storage material is completed. The mat 1 can store heat in the latent heat storage material 23. That is, since the disaster mat 1 only needs to store heat up to a temperature exceeding the melting point of the latent heat storage material 23, it is not necessary to diligently change the orientation of the sorakukka 51 as in the case of cooking foodstuffs.

The disaster mat 1 is placed in a transparent bag 61, and an air layer 62 is formed between the mat 1 and the transparent bag 61. Therefore, even if the wind blows when the disaster mat 1 is exposed to sunlight, the disaster mat 1 is not exposed to the wind and is not deprived of heat. Therefore, the disaster mat 1 can efficiently store heat in the latent heat storage material composition 21 in the transparent bag 61.

The display color of the display unit 41 of the disaster mat 1 changes according to the surface temperature of the mat-shaped container 11. Therefore, the user can easily confirm whether or not the heat storage is completed by looking at the display color of the display unit 41. When the user confirms that the heat storage is completed based on the display unit 41, the user removes the disaster mat 1 from the saw racker 51, and folds and cleans the saw racker 51.

When the disaster mat 1 is used, the disaster mat 1 is taken out from the transparent bag 61 and the metal piece 31 is operated. Since the mat-shaped container 11 is transparent, even if the latent heat storage material composition 21 is colored black, the user can use the metal piece in the liquid latent heat storage material composition 21 from the outside of the mat-shaped container 11. 31 is easy to find and easy to operate.

When the metal piece 31 is operated, the latent heat storage material 23 of the disaster mat 1 solidifies and starts heat dissipation. Since the latent heat storage material composition 21 contains glycerin that acts as a thickener, the latent heat storage material 23 is soft even if it solidifies. Therefore, the disaster mat 1 that has started heat dissipation from the latent heat storage material 23 is deformed according to the shape of the user's foot, for example, when the user's foot is placed on it, and for example, the user's foot. When applied to the abdomen, it can be transformed to wrap around the abdomen. As described above, the disaster mat 1 is soft even after heat dissipation, and is comfortable to use.

When the heat is stored again in the disaster mat 1 used in this way, the user reassembles the solar accca 51 and stores the heat in the used disaster mat 1 in the same manner as described above. For example, even if the Sorakka 51 is repeatedly used in an evacuation site and damaged, since it is made of cardboard 53, anyone can easily repair it with an adhesive tape or the like. Further, by using a commercially available product for the sorakukka 51, it is easy to replace the damaged sorakukka 51 with another sorakukka 51.

<About heat storage performance evaluation test>
The inventors conducted the first to third heat storage performance evaluation tests in order to confirm the performance of the heat storage method using Sorakka. The disaster mat 1 is used for heating and warming purposes. Therefore, the 1st to 3rd heat storage performance evaluation tests were conducted under the winter weather environment (December to March). Each test will be described.

<About the first heat storage performance evaluation test>
The first heat storage performance evaluation test is a test for confirming the absorption of water depending on the type of sorakkakka. In the test, the heating performance of commercially available Sorakukka, which is about the same price, was confirmed using water colored in black. The test conditions are shown in FIG.

As shown in FIG. 5, Specimen A and Specimen B were used as Sorakka. The test body A is a commercially available solar furnace (trade name "eco-solar cooker", manufacturer name "earth cardboard", model number "0131", size "505 x 520 x 525") with a matte finish on the surface of the panel portion. Specimen B is a commercially available solar furnace (trade name "cardboard solar cooker", manufacturer name "Kyowa cardboard", model number "Ver.9.3") with a mirror-finished panel surface, size "360 x 740 x 370". ).

The first heat storage performance evaluation test was conducted on different days for the test body A and the test body B, but the installation location (concrete ground) and the installation direction (south south) of the test body A and the test body B were the same. .. In the first heat storage performance evaluation test of the test body A, a transparent container containing black water in which water was colored black was placed at a predetermined position of the test body A. The initial water temperature of black water was 17 ° C. The inventors measured the water temperature, outside air temperature, humidity, and amount of solar radiation of black water every 30 seconds. The average outside air temperature was 19 ° C., the average humidity was 32% RH, and the average amount of solar radiation was 276 W / m ² . Also in the first heat storage performance evaluation test of the test body B, a transparent container containing black water in which water was colored black was placed at a predetermined position of the test body B. The initial water temperature of black water was 18 ° C. The inventors measured the water temperature, outside air temperature, humidity, and amount of solar radiation of black water every 30 seconds. The average outside air temperature was 16 ° C., the average humidity was 42% RH, and the average amount of solar radiation was 247 W / m ² . The reason why black water is used is that the sodium acetate trihydrate, which is the main component of the latent heat storage material composition 21, is transparent water close to water, and is colored black by adding the colorant 25. Is. The test results are shown in FIG. The vertical axis of FIG. 6 indicates the water temperature (° C.), and the horizontal axis indicates the time.

As shown by the dotted line in FIG. 6, it took about 3 hours and 30 minutes for the black water temperature of the black water to reach the target water temperature of 42 ° C. On the other hand, as shown by the solid line in FIG. 6, it took about 2 hours for the black water temperature of the test body B to reach the target water temperature of 42 ° C. The reason why the target water temperature was set to 42 ° C. is that the melting point of the latent heat storage material composition 21 was taken into consideration.

Despite the fact that the average outside air temperature of the test body B is 3 ° C lower than that of the test body A and the average amount of solar radiation is 29 W / m ² less, it takes about 1 hour and 30 minutes for the black water temperature to reach the target water temperature. It was short. Therefore, it was found that the heat storage efficiency of Sorakka was better when the panel portion was mirror-finished than when the panel portion was matte-finished. Further, the latent heat storage material can store heat in a range exceeding the melting point. As shown in the shaded area X in the figure of FIG. 6, the test body B can store heat in a range where the water temperature exceeds the target water temperature, but the test body A can store heat without the water temperature exceeding the target water temperature. Can not. Therefore, it was found that the test body B was superior to the test body A in the heat storage performance.

In addition, the inventors installed the test body B in which the transparent container containing black water was placed at a predetermined position in the same installation place and orientation as above in the sunny weather in December, and started the test. The water temperature could be reached to 46 ° C. in about 30 minutes.

<About the second heat storage performance evaluation test>
The second heat storage performance evaluation test is a test for confirming the effect of the difference in the object colored in black on the heat storage performance. The test conditions are shown in FIG.

In the second heat storage performance evaluation test, the test piece B was used. Sample D in which black water was put in a transparent glass bottle and sample E in which clear water was put in a black glass bottle were placed at predetermined positions of the test body B. In Sample D, the black colorant 25 described above was put into water to generate black water. Specimen B was installed toward the south. The initial water temperature of Sample D and Sample E was about 20 ° C. The inventor measured the outside air temperature, humidity, amount of solar radiation, and water temperature every 30 seconds. The average outside air temperature was 10.2 ° C., the average humidity was 41% RH, and the average amount of solar radiation was 447 W / m ² . The test results are shown in FIG. The vertical axis of FIG. 8 shows the water temperature (° C.) and the humidity (% RH), and the horizontal axis shows the elapsed time (hours: minutes) from the start of the test.

As shown by the dotted line in FIG. 8, it took about 43 minutes for the water temperature of the sample E to reach the target water temperature of 42 ° C. On the other hand, as shown by the solid line in FIG. 6, it took about 40 minutes for the water temperature of the sample D to reach the target water temperature of 42 ° C. Therefore, it is better to make the latent heat storage material composition black and put it in a transparent container to heat the latent heat storage material composition than to heat the latent heat storage material composition in a container colored in black. It was found that the material itself can be heated directly, so heat can be stored efficiently.

<About the 3rd heat storage performance evaluation test>
The third heat storage performance evaluation test is a test for confirming the effect on the temperature rise performance when the heat storage material is covered with a transparent member. The test conditions are shown in FIG.

In the third heat storage performance evaluation test, the test piece A was used. Sample F in which a transparent container containing black water was placed in a transparent plastic bag and Sample G in which a transparent container containing black water was not placed in a transparent plastic bag were placed at predetermined positions of the test piece A. The third heat storage performance evaluation test was conducted on different days for sample F and sample G, but the installation location (concrete-covered ground) and installation orientation (south south) of the test body A were the same. For Sample F and Sample G, the outside air temperature, humidity, amount of solar radiation, and water temperature were measured every 20 minutes.

In the third heat storage performance evaluation test of sample G, the initial water temperature was 21 ° C., the average outside air temperature was 11 ° C., the average humidity was 43% RH, and the average amount of solar radiation was 226 W / m2. In the third heat storage performance evaluation test of Sample F, the initial water temperature was 17 ° C., the average outside air temperature was 19 ° C., the average humidity was 32% RH, and the average amount of solar radiation was 276 W / m ² . The test results are shown in FIG. The vertical axis of FIG. 10 shows the water temperature (° C.), and the horizontal axis shows the elapsed time (hours: minutes) from the start of the test.

As shown by the dotted line in FIG. 10, in the sample G, the maximum water temperature was 30 ° C., and the difference between the initial water temperature and the maximum temperature was 9 ° C. On the other hand, as shown by the solid line in FIG. 10, in Sample F, the maximum water temperature was 42 ° C., and the difference between the initial water temperature and the maximum temperature was 25 ° C. Therefore, although there are some differences in weather conditions, it was found that the amount of temperature rise from the initial water temperature is larger in the case with the transparent plastic bag than in the case without the transparent plastic bag, and the heat storage efficiency is improved.

As described above, the heat storage tool heat storage method of the present embodiment is a disaster mat 1 in which the latent heat storage material composition 21 colored in a color that promotes the absorption of sunlight is enclosed in a transparent mat-shaped container 11. Is placed at a predetermined position 52 of a commercially available solar storage 51 and exposed to sunlight. The energy of sunlight is collected in the mat 1 for disasters via the solar bacca 51, passes through the mat-shaped container 11, and is directly absorbed by the latent heat storage material composition 21. Therefore, according to the heat storage method of the heating tool of the present embodiment, the latent heat storage material composition 21 of the mat 1 for disaster can be easily stored by using the commercially available Sorakka 51 which is easily available.

The present invention is not limited to the above embodiment, and can be appropriately modified without departing from the gist thereof. For example, the display unit 41 shown in FIG. 1 may be omitted.

For example, in the embodiment, the heating tool is a disaster mat 1 used in a shelter life due to a natural disaster, but the heating tool is, for example, an outdoor heating mat used outdoors such as camping. As long as it is a product that warms up by utilizing heat radiation from the latent heat storage material composition of the present invention, it is not limited to the embodiment and may be anything.

In the above embodiment, as shown in FIG. 4 (c), the disaster mat 1 is placed in the transparent bag 61 and placed at a predetermined position 52 of the saw racker 51. On the other hand, for example, as shown in FIG. 11, the disaster mat 1 and the transparent bag 71 are placed in the transparent bag 71 by directly arranging the disaster mat 1 at a predetermined position 52 and putting the saw racker 51 in the transparent bag 71. An air layer 72 may be formed between the two. The transparent bag 71 is a transparent member made of a bag body made of a transparent material and can transmit sunlight. The transparent bag 71 is an example of the “second transparent member”. The disaster mat 1 may be put in the transparent bag 61, and the sorakukka 51 may be put in the transparent bag 71. The transparent bag 71 may be a transparent box.

Further, for example, as shown in FIG. 13, a disaster mat 1 is arranged at a predetermined position 52 of the assembled Sorakkakka 51, and the panel opening of the Sorakkakka 51 is a sheet 91 formed of a transparent material such as a food wrap film. By covering with, an air layer may be formed around the mat 1 for disaster. Then, the Sorakka 51 may be installed so as to face approximately south, and the mat 1 for disaster may be exposed to sunlight. The sunlight passes through the sheet 91 and can reach the inner surface 55a of the disaster mat 1 and the solar bacca 51. The sheet 91 is an example of the "third transparent member". The disaster mat 1 may be placed in the transparent bag 61, and the panel opening of the solar bacca 51 may be covered with the sheet 91. Even when the air layer is formed as shown in FIGS. 11 and 13, the disaster mat 1 is provided with the outside air during heat storage by preventing convection from occurring on the surface of the disaster mat 1 due to wind or the like. It is hard to lose heat and can store heat efficiently.

For example, as shown in FIG. 12, the disaster mat 1 may be placed at a predetermined position 52 of the saw racker 51 in a state of being put into a metal pot 81 filled with water 82. In this case, the water 82 of the metal pot 81 is warmed, and the warm water 82 is used as a medium to store heat in the latent heat storage material composition 21 of the mat 1 for disasters. Therefore, the disaster mat 1 can uniformly store heat in the latent heat storage material composition 21 regardless of the degree of sunlight.

The inner surface 55a of the saw racker 51 shown in FIG. 4 (c) does not have to be formed of a glossy mirror surface. For example, the inner surface 55a may be formed with a matte mirror surface.

The disaster mat 1 is not put in the transparent bag 61 shown in FIGS. 4 (a) and 4 (b), but the saw rack 5
It may be arranged at a predetermined position of 1. The transparent bag 61 may be a transparent box.

The Sorakka 51 may be made of a material other than corrugated cardboard, such as metal. However, by using a corrugated cardboard saw rack, the saw rack 51 is lightweight and inexpensive. The Sorakka 51 does not have to be an assembly type. However, by using the assembling type Sorakka 51, storage or stockpiling becomes easy.

1 Disaster mat (an example of warming equipment)
11 Mat-shaped container 21 Latent heat storage material composition (example of heat storage material)
51 Sorakka

Claims (7)

A heat storage tool in which a heat storage material is sealed in a mat-shaped container. A heat storage tool for storing heat in the heat storage material, which is a heat storage method.
The heating tool is
The mat-shaped container is made of a transparent bag body.
The heat storage material is colored in a color that promotes the absorption of sunlight.
The heating tool is placed at the predetermined position and exposed to the sunlight, as opposed to a commercially available solar bacca that condenses sunlight to cook the food material installed at the predetermined position.
A heat storage method for heating equipment. In the heat storage method for heating equipment according to claim 1,
The solar ucca includes a panel portion for collecting heat from the sunlight at the predetermined position, and the surface of the panel portion located on the predetermined position side is formed of a glossy mirror surface.
A heat storage method for heating equipment. In the heat collecting tool heat storage method according to claim 1 or 2.
With the heating tool placed in the first transparent member made of a bag made of a transparent material, the heating tool is arranged at the predetermined position.
A heat storage method for heating equipment. In the heat collecting tool heat storage method according to any one of claims 1 to 3.
Putting the sorakkakka in which the heating tool is arranged at the predetermined position in the second transparent member made of a bag body made of a transparent material and exposing it to the sunlight.
A heat storage method for heating equipment. In the heat collecting tool heat storage method according to any one of claims 1 to 3.
The heating tool is placed in a predetermined position so as to form an air layer around the heating tool, and the solar bacca is covered with a third transparent member made of a sheet made of a transparent material. To be exposed to the sunlight,
A heat storage method for heating equipment. In the heat collecting tool heat storage method according to any one of claims 1 to 5.
In a state where the heating tool is put in a metal container filled with water, the heating tool is arranged at the predetermined position.
A heat storage method for heating equipment. In the heat collecting tool heat storage method according to any one of claims 1 to 6.
A display unit indicating the heat storage state of the heat storage material is provided on the surface of the mat-shaped container.
A heat storage method for heating equipment.

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