JP2793645B2 - Method of manufacturing heat storage board - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a method of manufacturing a heat storage board that can be loaded into a floor, a wall, or a flower pot and used as a heat storage material, or used alone as a heat storage container.

(Conventional technology) A heating apparatus using radiant heat can heat a room evenly to stimulate a warm point of a human body, so that a comfortable heating system can be configured. In recent years, a heating device having a heat storage structure added for the purpose of energy saving has come to be used. That is, heat or solar heat generated by using inexpensive midnight power, waste heat of another heat source, or the like is stored in a heat storage material, and the heat is used during heating.

As the heat storage material, a sensible heat storage material such as concrete or brick has been used. 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 been frequently used. The latent heat storage material utilizes latent heat accompanying a phase change between a solid and a liquid, between a solid and a solid, and includes, for example, hydrated salts such as calcium chloride hexahydrate, sodium sulfate decahydrate, and paraffins. Fatty acid esters and the like are known.

If this latent heat storage material is to be constructed as a heat storage board on a floor or wall, among the latent heat storage materials,
Since it becomes a liquid at the time of use, it should be sealed in a sealed container,
As shown in JP-A-63-201434, latent heat storage material particles must be prepared by the method described below and filled in a container.

In other words, each latent heat storage material particle is filled with the latent heat storage material in a resin-based microcapsule using a microencapsulation method such as an orifice method, a phase separation method, or an air suspension method, as in the past. Or, a latent heat storage material melt is absorbed by a continuous porous absorber such as activated carbon or wood chips, or a resin such as rubber is kneaded with a latent heat storage material to incorporate the latent heat storage material into a resin matrix. The polyolefin particles may be formed by impregnating the polyolefin particles with a latent heat storage material, utilizing the property of swelling when immersed in a crystalline organic heat storage material heated to the melting point or higher.

Here, as shown in FIG. 10, a latent heat storage material is absorbed or impregnated to form latent heat storage material particles 2 ', and the latent heat storage material particles 2' are put together with the granular material 3 'in a bag 1' to form a large number of latent heat storage materials. To treat the heat storage material particles 2 'in one bag 1'
Although already mentioned in JP-A-63-201433 and commonly used, the latent heat storage material particles 2 'and the powder particles 3' are filled in the bag 1 'only by filling in this manner. After moving, the following problems occurred.

(Problems to be Solved by the Invention) Due to the independent layer of air generated inside the bag 1 ', the heat conduction of the heat storage board itself deteriorates, and efficient heat storage and radiation cannot be performed.

As shown in FIG. 11, the latent heat storage material particles 2 'inside the bag body 1' are biased, and the heat storage board A 'is made uneven so that the contact with the heating element 8' and the like becomes poor, and the efficiency is also lowered. Good heat storage and heat dissipation cannot be performed.

Since the latent heat storage material particles 2 'and the granular material 3' inside the bag body move inside the bag body 1 ', the strength is weak, and when the heat storage board A' is lifted horizontally, the work breaks at the center and the work is performed. Hateful.

In order to solve this problem, it is conceivable to increase the filling amount without changing the size of the bag. However, as shown in FIG. Is not improved.

The present invention has been proposed in view of the above, and its object is to maintain a sufficient strength, and good heat storage and heat dissipation, and, furthermore, a heat storage board capable of obtaining a workable heat storage board. It is to provide a manufacturing method.

(Means for Solving the Problems) That is, according to the present invention, particles are attached to the latent heat storage material particles that have absorbed or impregnated the latent heat storage material, and after filling in the bag, the powder is formed in the bag at the time of heating and pressing. The above object is achieved by discharging the air expelled from between the latent heat storage material particles through the escape path of the air thus formed and molding.

(Action) In the case where the latent heat storage material particles and the granular material are separately put in the bag body, they move inside and the strength is inferior.
By filling as the above configuration, such a phenomenon is not caused, and sufficient strength can be obtained. In addition, since it can be formed in a flat plate shape, heat storage and radiation are good, and the strength is improved.

In addition, excess air in the bag can be easily released to the outside during heating and pressurization.

(Example) In the present invention, the latent heat storage material is absorbed or impregnated by the above-described method to form latent heat storage material particles, and powdery particles such as calcined gypsum, talc, and aluminum oxide are adhered to the surface thereof. It is characterized in that after filling it into a bag, it is heated and pressurized and molded into a desired shape, for example, a flat plate.

That is, FIG. 1 is a perspective view of a heat storage board, Figure 2 is a cross-sectional view of the C ₁ -C ₂ wire, in these figures 1 heat storage board A
1a is a seal portion thereof, 2 is a latent heat storage material particle filled in the bag 1, and a granular material 3 is adhered to the surface of the latent heat storage material particle 2. It is effective to attach the powder 3 after the impregnation.

As a method of adhering the powder 3 to the surface of the latent heat storage material particles 2, a method is used in which the latent heat storage material remains as a liquid on the surface of the impregnated latent heat storage material particles 2 using a mixer. And the latent heat storage material particles 2 may be agitated.
Is desirably uniformly attached to each latent heat storage material particle 2. Then, this was filled in the bag body 1 and the mouth of the bag was sealed, that is, the one configured as shown in FIG.
As shown in FIG. 4, it is put into a mold 4, and heated and pressed by hot plates 5 arranged vertically to perform molding.

In the above description, the bag 1 may be a cylindrical bag having both open ends or a bag having one open end. In any case, after filling, the opened portion is sealed and the bag 1 is formed into a mold 4.
Put in.

The mold 4 has a shape in which a frame for regulating four side surfaces is mounted on a plate. In other words, when pressurized, in order for the latent heat storage material particles 2 to enter into the air layer existing between the latent heat storage material particles 2 and to be filled without gaps, a frame that regulates the pressure from escaping from the upper and lower surfaces. Is necessary.

The temperature of the hot plate 5 is set to the latent heat storage material particles 2.
Must be lower than the temperature at which the material melts and higher than the temperature at which the latent heat storage material melts. In the latent heat storage material particles 2 in which polyolefin is impregnated with paraffin, it is appropriate that the temperature is about 60 to 150 ° C. and the heating time is about 30 seconds to 5 minutes.

Further, the pressurizing time needs to be at least a time capable of giving the heat amount at which the latent heat storage material in the latent heat storage material particles 2 in contact with the inside of the bag body 1 is melted. As shown in FIG. 5, each latent heat storage material particle 2 is filled without gaps, and heat conduction is good. By heating, the latent heat storage material oozing out from the latent heat storage material particles 2 in contact with the inside of the bag body 1 causes the latent heat storage material particles 2 to adhere to each other or to solidify the powder particles 3 to which the latent heat storage material particles 2 adhere. Thus, since the latent heat storage material particles 2 are indirectly fixed, the strength of the heat storage board A is increased.

As the strength, for example, width 250 mm × length 800 mm × thickness 20
Even if a load of 4 to 5 kg is applied to the center by the heat storage board A of mm, it does not buckle and it is preferable that the heat storage board A has a strength that does not hinder the work at the time of construction.

When a film in which a polyolefin is laminated on the inner surface of an aluminum foil is used as the material of the bag body 1, the polyolefin on the inner surface is melted by heating, and the latent heat storage material particles 2
Is adhered to the inner surface of the bag body 1 at least one layer, and the strength can be further increased.

FIG. 6 shows an example in which the heat storage board A constructed as described above is constructed under the floor, 6 is a floor component such as a floor finishing material, 7 is a floor component such as a joist, and 8 is a vertical component. It is an appropriate heating element interposed between the arranged heat storage boards A, and can store heat in the heat storage board A of the heating element 8.

7 to 9 show the heat storage board A having the above configuration.
1 shows a method for sealing a bag 1 according to the present invention in the case of manufacturing a bag.

That is, after the bag 1 is filled with the latent heat storage material particles 2 and the opening is simply sealed and sealed, the mold 4 shown in FIG.
In the state of being heated and pressed under pressure, the air a contained between the latent heat storage material particles 2 is expelled from between the latent heat storage material particles 2 as shown in FIG. There is a possibility that the heat accumulates between the heat storage material particles 2 and the bag body 1 and the latent heat storage material particles 2 and the bag body 1 are not bonded to each other, and the strength of the heat storage board A is reduced.

In this case, as shown in FIG. 8 and FIG. 9 along the line E ₂ -E ₂ thereof, the escape path of the air “a” expelled from between the latent heat storage material particles 2 at the time of heating / pressing molding is formed by opening the bag 1. A part or the whole of the part may be secured by leaving it as the unsealed part 11a, and the unsealed part 11a may be sealed by sealing after heat and pressure molding.

In addition, if the oozing of the latent heat storage material from the latent heat storage material particles 2 increases the amount of adhesion of the granular material 3, and if all of the ooze is absorbed by the granular material 3, the unsealed portion 11 a is left as it is and the thermal storage material is left. Board A can also be used.

Further, since the above-mentioned problem is caused by the presence of air a between the latent heat storage material particles 2 during the heating and pressing molding, the method according to the present invention employs the air a in the bag 1 before the heating and pressing molding. The same effect can be obtained by removing and sealing under reduced pressure.

In the above embodiment, a heat storage board suitable for use on floors, walls, and the like has been described. However, the present invention can also be applied to flower pots for cultivating western orchids. That is, the orchid is vulnerable to the cold and may hinder its growth during non-heating such as during the nighttime in winter. For this reason, if the heat storage board of the above configuration is appropriately combined with a flower pot or the heat storage board itself is formed into a flower pot shape, daytime, solar heat can be stored, and heat can be dissipated at night to prevent a sharp drop in temperature. .

(Effects of the Invention) As described above, according to the present invention, the particles are attached to the latent heat storage material particles that have absorbed or impregnated the latent heat storage material, and after filling in the bag body, they are heated and pressed to be molded. Since the,
In the case where the latent heat storage material particles and the granular material are simply put in the bag separately, they move inside the bag and the strength is weak, but in the present invention, there is no such, the strength is improved,
It has a desired shape, that is, a flat plate shape, has good heat storage and heat dissipation, and has an effect of being easy to work without breaking at the center during work.

[Brief description of the drawings]

FIG. 1 is a perspective view of a heat storage board according to an embodiment of the present invention,
Figure 2 is C ₁ -C ₂ cross-sectional view taken along a line Id, in FIG. 3 is a first diagram D ₁ -
FIG. 4 is a cross-sectional view before heating as a cross-section along the line D _2, FIG.
FIG. 5 is a sectional view of a molded heat storage board of the present invention, and FIG.
FIGS. 7 to 9 are explanatory views of a working example of the present invention, FIGS. 7 to 9 are process explanatory views of a bag sealing method, and FIGS. 10 to 12 are explanatory views of a conventional manufacturing process. A: thermal storage board 1: bag 2: latent heat storage material particles 3: powder

Claims (1)

(57) [Claims] 1. A latent heat storage material particle having a latent heat storage material absorbed or impregnated with a granular material adhered thereto, filled in a bag, and then heated and pressurized via an air escape path formed in the bag during heating and pressurization. A method for manufacturing a heat storage board, characterized by discharging air expelled from between and molding.