JPH03160298A - Heat accumulation board and its production method - Google Patents

Abstract

PURPOSE:To enable recovery from deformation and to protect a vessel against drop or impact by forming a solidification part area and an unsolidification part area in a heat accumulation board formed by filling the vessel with latent heat accumulation material particles and then subjecting the vessel, to thermal pressure molding. CONSTITUTION:When latent heat accumulation material particles 2 impregnating or absorbing a latent heat accumulation material is filled in a vessel and subjected to thermal pressurization, the heating temperature at an unsolidification part is lessened, compared with the heating temperature at a solidification part or the pressure at the unsolidification part is lessened compared with the pressurization at the solidification part thus forming the unsolidification part and the solidification part. Against drop and shock, the shock is absorbed by the unsolidification part and the vessel is not damaged, in addition, the deformation of the unsolidification part can be recovered.

Description

Detailed Description of the Invention (Field of Industrial Application) The present invention relates to a heat storage board that can be used as a heat storage material by being loaded inside a floor, wall, or flower pot, or used alone as a heat storage container, and a method for manufacturing the same. (Prior Art) For purposes such as energy conservation, heat storage materials are embedded under floors, inside walls, etc.

Until now, sensible heat storage materials such as concrete and bricks have been used as heat storage materials. However, recently, latent heat storage materials, which have a larger amount of heat storage per volume than these sensible heat storage materials and can store and release heat at a constant temperature, have come into widespread use.

Latent heat storage materials utilize latent heat associated with phase changes such as between solid and liquid or between solid and solid. Esters etc. are known.

Among the latent heat storage materials, the ones exemplified above become liquid when used, so conventionally they were often used in a sealed container, but such materials have the following problems. It was occurring.

■ Latent heat storage materials undergo a large volume change during phase transition,
This leads to damage to the sealed container. ■ If the sealed container is damaged, a large amount of latent heat storage material will leak out from there, losing its heat storage effect, and the surrounding area will be contaminated by the leaked latent heat storage material. (3) Inorganic permanent latent heat storage materials are efflorescent. Due to its high moisture absorption, if the sealed container is not completely moisture-proof, it will naturally lose its heat storage ability.

Therefore, in order to solve this problem, it was considered to make a large number of latent heat storage material particles by methods such as encapsulating the latent heat storage material. In such latent heat storage material particles, the change in volume is absorbed by the voids between the particles, so the container will not be damaged, and even if one latent heat storage material particle is destroyed, the latent heat contained in it will not be damaged. Since the amount of heat storage material is small, its leakage will not immediately lead to loss of heat storage effect or contamination of the surrounding area. Moreover, with the inorganic permanent latent heat storage material mentioned above, complete moisture proofing can be achieved just by covering the area with a capsule.
The sealed container itself becomes unnecessary.

Therefore, when a container is filled with latent heat storage material particles to form a heat storage board, the advantage is that the strength of the container can be made weaker than when the latent heat storage material is directly filled into the container. .

(Problem to be Solved by the Invention) However, in the past, if the strength of the container was low, there was a possibility that the container would break when it was dropped or hit against something when it was installed on a floor or wall. However, if a container with low strength is used for carrying during construction, the heat storage board must be made so that the latent heat storage material particles are tightly packed in the container so that they do not easily move within the container. To do this, the latent heat storage material particles are pressed into the container by heating and pressurizing to maintain its strength as a heat storage board.

FIG. 13 shows a conventional heat storage board, 1 is a container, 2 is a particle of latent heat storage material, and FIG. 14 is a cross section of FIG. It is completely clogged and solidified all the way to the edges.

Like this! ! For example, as shown in Figure 15, if a board is dropped from its edges to the floor, the edges will be as hard as the center, so there will be no place to absorb the impact, and if the impact of the fall is large, it will deform. As a result, local deformation becomes large at the end, resulting in a deformed portion 3 and the container 1 being damaged, resulting in a state as shown in FIG. 16.

Note that 4 in FIG. 16 indicates the container rupture location.

Further, a drawback of the conventional example is that when the end is placed against an object, the container is locally significantly deformed, resulting in a similar state.

If it is damaged, the latent heat storage material particles 2 will spill out of the container l, making it impossible to secure a predetermined amount of heat storage. Another problem was that the deformed boards became thick and difficult to install. The present invention has been proposed in view of the above, and its purpose is to provide a heat storage board that can prevent the container from being damaged by drops or impacts, and can repair deformation even if a container with low strength is used. and its manufacturing method. (Means for Solving the Problems) The heat storage board of the present invention is a heat storage board formed by filling a container with latent heat storage material particles and molding them under heating and pressure, in which a solidified region and an unsolidified region are formed. By doing so, the above purpose is achieved.

In addition, during manufacturing, in a heat storage board made by filling a container with latent heat storage material particles impregnated with or absorbed with a latent heat storage material and heating and pressurizing the same, it is necessary to lower the heating temperature of the unsolidified part compared to the heating temperature of the solidified part. Alternatively, the unsolidified portion and the solidified portion are formed by making the unsolidified portion pressing force smaller than the solidified portion pressing force.

(Function) With the structure as described above, an unsolidified portion is provided so that the device is actively deformed when dropped or impacted, thereby preventing damage. Moreover, in this case, it functions to absorb Ii stenosis to some extent, and furthermore, since it is in an unsolidified state, if it is deformed, it can be repaired.

(Example) Embodiments of the present invention will be described below along with the drawings.

FIG. 1 shows a heat storage board of the present invention, FIG. 2 is a sectional view showing its internal structure, and FIG. 3 is a plan view.
A heat storage board formed by filling a container 1 with latent heat storage material particles 2 and heating and pressurizing the same is characterized in that a solidified portion B and an unsolidified portion C6 are formed.

That is, as mentioned above, if the central part is the solidified part B and the end part is the unsolidified part C, as shown in FIG. Part 3 is formed, but the latent heat storage materials 2 are not bonded to each other, and the latent heat storage materials 2 and the container 1 are not bonded to each other, or there are many gaps between the latent heat storage material particles and the adhesion between them is incomplete. In other words, since it is not solidified, the latent heat storage material particles 2 can easily move, so that the entire unsolidified portion C is deformed and the container 1 is not locally deformed or damaged. (See Figure 5) When forming the solidified part B and the unsolidified part C in the container l, drop impact becomes a problem especially at the corner part, so as shown in Figure 6, the corner part of the container l is left unsolidified. It may also be a solidified portion C.

Similarly, as shown in FIG. 7, if the length of the container l is the unsolidified portion C, and as shown in FIG. 8, the periphery is the unsolidified portion C, and the same effect is obtained. In addition, since the unsolidified part C has a low packing density and has gaps (spaces) between the latent heat storage material particles 2, the spaces also serve to absorb the impact of falling. Further, since the latent heat storage material particles 2 can move in the unsolidified portion C, it is also possible to restore the container l that has been manually deformed to its original shape.

Next, a method for manufacturing a heat storage board according to the present invention will be explained.

When the latent heat storage material particles 2 are manufactured by impregnating or absorbing the latent heat storage material, the latent heat storage material is attached around the latent heat storage material particles 2. When these latent heat storage material particles 2 are placed in a container 1 and heated, the latent heat storage material adhering around the latent heat storage material particles 2 melts and adheres to each other and between the container 1 and the latent heat storage material particles 2. If you cool it as it is, you can create a solidified state. (See FIG. 9) Therefore, if it is desired to create an unsolidified portion, it is possible by lowering the heating temperature so that the latent heat storage material attached around the latent heat storage material particles 2 does not melt.

Moreover, even if the latent heat storage material particles 2 are sufficiently heated, unless pressure is applied, the adhesion force between the latent heat storage material particles 2 will not be sufficient, and the latent heat storage material particles 2 can be moved with a small force.

That is, FIG. 10 shows a heat storage board in which an unsolidified part C' is formed by heating to a small extent and a solidified part B' is solidified by a large heating by the above manufacturing method. In addition, FIG. 11 shows an unsolidified part CR with a small pressure and a gap between the latent heat storage material particles 2, and a solidified part B with a high pressure.
This is a heat storage board marked #, which is designed to reduce heating and prevent adhesion between the latent heat storage material particles 2.

Furthermore, in FIG. 12, the pressure is similarly reduced to create a gap between the latent heat storage material particles 2 to reduce the adhesion force and unsolidified portion C.
This is a heat storage board in which the solidified portion Bw is formed by increasing the pressure #' and increasing the adhesive force between the latent heat storage material particles 2.

(Effects of the Invention) As described above, the heat storage board of the present invention is a heat storage board formed by filling a container with latent heat storage material particles impregnated with or absorbing a latent heat storage material and heating and pressurizing the same. It is manufactured by forming an unsolidified part and a solidified part by lowering the heating temperature of the unsolidified part or by applying a pressure force smaller than that of the solidified part, and the area of the solidified part and the area of the unsolidified part are Because of this, the unsolidified part absorbs the impact even if it is dropped or impacted, and the container will not be damaged.
There is an effect that deformation of the unsolidified portion can be repaired.

[Brief explanation of the drawing]

FIG. 1 is a perspective view of a heat storage board according to an embodiment of the present invention, with a part of the container cut away, and FIG. 2 is a perspective view of A in FIG. A
4-line sectional view, Figure 3 is a plan view of the heat storage board, Figure 4 is an explanatory diagram of the operating state showing the internal state, Figure 5 is a perspective view of the same external appearance with a portion cut away, Figure 6 FIGS. 9 to 8 are modified examples of the heat storage board, FIGS. 9 to 12 are manufacturing examples of the heat storage board, FIG. 13 is an external perspective view of the conventional example, and FIG. t-line sectional view, FIG. 15 is an explanatory diagram of the operating state of the conventional example showing the internal state,
FIG. 16 shows an external perspective view of the same as above. ■ - Container 2 - Latent heat storage material particles B - - Solidified part C - - Unsolidified part (1 other person) Figure 3 Figure 4 Figure 6 Figure 7 Figure 8 Figure 9 Figure C - Final solidification tgP (IJO Shokai Shi 1＼) B' Solidification Sweeping (jIrJ Most Powers Figure 11 C' Misaki Misaki (77 Rozuki Shi 1,) B'''' Hill ai tozu 31 (Sword U 亙人》 Figure 12) C'l side 114 and name p (KARUJ＼)・ B"Iffi and part (pressure OJ

Claims (2)

[Claims] (1) A heat storage board formed by filling a container with latent heat storage material particles and molding them under heat and pressure, characterized in that a solidified region and an unsolidified region are formed. (2) In a heat storage board formed by filling a container with latent heat storage material particles impregnated or absorbed with a latent heat storage material and heating and pressurizing the same, the heating temperature of the unsolidified part is lower than that of the solidified part, or the solidified part is heated at a lower temperature than the solidified part. A method for producing a heat storage board, characterized in that an unsolidified portion and a solidified portion are formed by applying a pressure force smaller than a pressing force to the unsolidified portion.