JP2019196632A - Cool and heat storage floor, and living room - Google Patents

Abstract

To provide a cool and heat storage floor capable of shortening operation hours for air conditioning through keeping a room temperature in a stable condition in summer and winter seasons when air conditioning is required.SOLUTION: A cool and heat storage floor 10 comprises: a heat storage layer 14 arranged on a floor substrate material 11 and formed with a first latent heat storage material; a cool storage layer 18 arranged above the heat storage layer 14 and formed with a second latent heat storage material having a latent heat storage temperature higher than that of the heat storage layer 14; and a plate member 16 arranged between the heat storage layer 14 and the cool storage layer 18. Specifically, the heat storage layer 14 is set at a latent heat storage temperature around 20°C and the cool storage layer 18 is set at a latent heat storage temperature around 27°C. Flooring 19 is arranged on the cool storage layer 18. The heat storage layer 14 is a sheet-shaped heat storage sheet formed by dispersing, in resin, the first latent heat storage material, and the cool storage layer 18 is a sheet-shaped cool storage sheet formed by dispersing, in resin, the second latent heat storage material having a latent heat storage temperature higher than that of the heat storage layer 14.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a cold storage thermal floor and a living room provided with the cold storage thermal floor.

The indoor temperature of buildings is mainly adjusted by air conditioners (heating equipment, cooling equipment), but in recent years, the power consumption of such air conditioners has been reduced from the viewpoint of energy saving, global warming countermeasures, and running cost reduction. It is requested to do.
Therefore, there is a known technology that mitigates changes in room temperature by incorporating a latent heat storage material (PCM: Phase Change Material) that uses the latent heat generated when the substance undergoes a phase change between the solid and liquid phases into the building floor. ing.

And in patent document 1, the heat storage structure for floor heating which can continue heating for a long time with the heat which could have ensured many heat storage amounts, and was able to experience comfortable heating with the stored heat is also provided. Proposed.
This heat storage structure for floor heating is provided in a stacked state under a heat source layer so that a plurality of latent heat storage layers having different latent heat storage temperatures are lowered from the top toward the bottom. The latent heat storage is performed in each latent heat storage layer by the heat of.

Further, Patent Document 2 proposes a wooden floor material that can effectively use heat such as sunlight and indoor heating by grasping the state of the latent heat storage material.
This wood-based flooring includes at least a wood-based base material having a storage recess formed on the back surface and a latent heat storage material stored in the storage recess, and the phase change of the latent heat storage material is on the surface of the wooden flooring. A reversible first temperature indicator that changes color at the same temperature as the temperature, and a reversible second temperature indicator that changes color at the same temperature as the surface temperature of the wooden flooring when the stored latent heat storage material is in a heat release state. And material.

Japanese Patent No. 3940035 (Japanese Patent Laid-Open No. 2004-20055) Japanese Patent No. 5816477 (Japanese Patent Laid-Open No. 2013-24001)

  However, both the heat storage structure for floor heating in Patent Document 1 and the wooden flooring of Patent Document 2 are heat storage countermeasures for heating, and no countermeasures for cooling have been taken.

  An object of the present invention is to provide a cold-storage bed that can stabilize the room temperature in the summer and winter seasons when air conditioning is required and can shorten the operation time of air conditioning.

In order to solve the above problems, the invention according to claim 1 is, for example, as shown in FIG.
A heat storage layer 14 disposed on the floor base material 11 and formed of a first latent heat storage material (hereinafter referred to as a first PCM);
A cold storage layer 18 formed of a second latent heat storage material (hereinafter referred to as a second PCM) disposed above the heat storage layer 14 and having a higher latent heat storage temperature than the heat storage layer 14;
A plate 16 disposed between the heat storage layer 14 and the cold storage layer 18;
It is characterized by the cold storage heat floor 10 provided with.

According to the invention described in claim 1, the heat storage layer 14 formed of the first PCM is disposed on the floor base material 11, and the latent heat storage temperature is higher than the heat storage layer 14 above the heat storage layer 14. Since the cool storage layer 18 formed by the high second PCM is arranged, the heat of the cooling is first applied during the cooling in summer when the temperature is higher than the latent heat storage temperature of the second PCM forming the cool storage layer 18. The temperature of the floor 10 can be lowered and stored by the latent heat storage of the second PCM that forms the cold storage layer 18 to be received.
And since the heat storage layer 14 formed by the 1st PCM whose latent heat storage temperature is lower than the said cool storage layer 18 is arrange | positioned under the cool storage layer 18, the latent heat storage temperature of the 1st PCM which forms the heat storage layer 14 During cooling in summer when the temperature is higher than that, the first PCM in the liquid phase in which the heat storage layer 14 disposed below the heat storage layer 18 does not perform latent heat storage due to its own thermal resistance can also be used as the sensible heat storage material. .
In addition, during the winter heating when the temperature is lower than the latent heat storage temperature of the first PCM that forms the heat storage layer 14, the latent heat storage is not performed by the thermal resistance of the cold storage layer 18 that first receives the heat of the heating. The solid phase second PCM can also be used as a sensible heat storage material, and can be stored by raising the temperature of the floor 10 by the latent heat storage of the first PCM that forms the heat storage layer 14 disposed below the cold storage layer 18. .
Therefore, the room temperature can be stabilized during the summer and winter seasons when air conditioning is required, and the operation time of air conditioning can be shortened.
Furthermore, since the board | plate material 16 is arrange | positioned between the thermal storage layer 14 and the cool storage layer 18 arrange | positioned on the upper side, the load of the floor finishing material 19 on the cool storage layer 18 is below it via the cool storage layer 18 The plate material 16 can be reliably received.

The invention according to claim 2 is, for example, as shown in FIG.
In the cold-storage thermal floor 10 according to claim 1,
The heat storage layer 14 is set near the latent heat storage temperature 20 ° C.,
The cold storage layer 18 is set near a latent heat storage temperature of 27 ° C.

According to invention of Claim 2, since it is the thermal storage layer 14 set to the latent heat storage temperature 20 degreeC vicinity, it is below about 20 degreeC at the time of heating in winter, and by the latent heat storage of the 1st PCM which forms the thermal storage layer 14 The temperature of the floor 10 can be maintained at around 20 ° C.
In addition, since the cold storage layer 18 is set near the latent heat storage temperature 27 ° C., the temperature of the floor 10 is brought close to 27 ° C. due to the latent heat storage of the second PCM that forms the cold storage layer 18 when the cooling in the summer is about 27 ° C. or higher. Can be lowered and maintained.

For example, as shown in FIG.
In the regenerative thermal floor 10 according to claim 1 or 2,
A flooring 19 is disposed on the cold storage layer 18.

  According to the third aspect of the present invention, since the flooring 19 is disposed on the cold storage layer 18, the load of the flooring 19 on the cold storage layer 18 is applied to the plate material 16 below the cold storage layer 18. It can be received with certainty.

For example, as shown in FIG.
In the regenerative thermal floor 10 according to any one of claims 1 to 3,
The heat storage layer 14 is a heat storage sheet formed in a sheet shape by dispersing the first PCM in a resin,
The cold storage layer 18 is a cold storage sheet formed in a sheet shape by dispersing the second PCM having a higher latent heat storage temperature than the heat storage layer 14 in a resin.

  According to the invention described in claim 4, the first PCM is dispersed in a resin to form a sheet, and the second PCM having a latent heat storage temperature higher than that of the heat storage sheet 14 is dispersed in the resin. Since the cold storage sheet 18 is formed in a sheet shape, both the heat storage layer 14 and the cold storage layer 18 are thin and have low thermal resistance, and the thickness of the cold storage heat floor 10 can be reduced.

The invention according to claim 5 is, for example, as shown in FIG.
In the regenerative thermal floor 10 according to any one of claims 1 to 4,
A heat insulating material 12 is disposed under the floor base material 11.

  According to the invention described in claim 5, since the heat insulating material 12 is disposed under the floor base material 11, the lower part of the floor base material 11 is kept in a heat insulating state by the heat insulating material 12, so that it can be heated in winter. Therefore, the heat storage state by the heat storage layer 14 on the floor base material 11 can be maintained, and the cold storage state of the floor 10 by the cold storage layer 18 at the time of cooling in summer can be maintained.

The invention according to claim 6 is, for example, as shown in FIG.
In the regenerative thermal floor 10 according to any one of claims 1 to 5,
The heat storage layer 14 is laid in a specific location S on the floor of the living room 1,
The cold storage layer 18 is laid on the floor of the living room 1 in a wider range than the heat storage layer 14.

According to invention of Claim 6, since the thermal storage layer 14 is laid in the specific location S of the floor of the living room 1, the winter temperature is lower than the latent heat storage temperature of the first PCM that forms the thermal storage layer 14 The second solid phase PCM that does not perform latent heat storage due to its own thermal resistance of the cool storage layer 18 that receives the heat of the heating during heating can also be used as sensible heat storage, and the heat storage layer 14 below the cool storage layer 18 With this latent heat storage, the temperature can be stored only at a specific location S on the floor of the living room 1 by increasing the temperature.
And since the cool storage layer 18 is laid on the floor of the living room 1 in a wider area than the heat storage layer 14, during the cooling in summer when the temperature is higher than the latent heat storage temperature of the second PCM that forms the cool storage layer 18, Due to the latent heat storage of the second PCM that forms the cool storage layer 18 that first receives the heat of the cooling, the floor temperature can be lowered and stored in a wider range than the heat storage layer 14 of the living room 1.

The invention according to claim 7 is, for example, as shown in FIG.
In the living room 1 provided with the cold storage thermal floor as described in any one of Claim 1 to 6,
A ceiling cold storage layer 35 formed of a third latent heat storage material (hereinafter referred to as third PCM) having a higher latent heat storage temperature than the heat storage layer 14 of the cold storage heat floor 10 is provided below the ceiling base material 31 of the living room 1. It is arranged.

According to the invention described in claim 7, the ceiling cold storage layer 35 formed by the third PCM having a higher latent heat storage temperature than the heat storage layer 14 of the cold storage heat floor 10 is disposed under the ceiling base material 31 of the living room 1. Therefore, at the time of cooling in summer when the temperature is higher than the latent heat storage temperature of the third PCM that forms the ceiling cool storage layer 35, the cooling heat is reduced by the latent heat storage of the third PCM that forms the ceiling cool storage layer 35. The ceiling temperature of the living room 1 can be lowered to store cold.
Therefore, at the time of cooling in summer when the temperature is higher than the latent heat storage temperature of the floor cool storage layer 18 and the ceiling cool storage layer 35, the floor of the living room 1 and the floor cool storage layer 18 and the ceiling cool storage layer 35 receiving the heat of the cooling by the latent heat storage The ceiling temperature can be lowered to store cold.

The invention according to claim 8 is, for example, as shown in FIG.
In the living room 1 according to claim 7,
The ceiling cool storage layer 35 is a ceiling cool storage sheet formed in a sheet shape by dispersing the third PCM having a higher latent heat storage temperature than the heat storage layer 14 of the cold storage heat floor 10 in a resin.

  According to the invention described in claim 8, since the ceiling cold storage sheet 35 is formed in a sheet shape by dispersing the third PCM having a higher latent heat storage temperature than the heat storage layer 14 of the cold storage floor 10 into the resin, the ceiling cold storage layer is It is thin and has little thermal resistance, and the thickness of the cold storage ceiling 30 can be kept thin.

The invention according to claim 9 is, for example, as shown in FIG.
In the living room 1 according to claim 7 or 8,
The ceiling cool storage layer 35 is laid on the ceiling of the living room 1 in a wider range than the heat storage layer 14 of the cool storage heat floor 10.

According to the invention described in claim 9, the ceiling cool storage layer 35 is laid on the ceiling of the living room 1 in a wider area than the heat storage layer 14 of the cool storage floor 10, and therefore, from the latent heat storage temperature of the ceiling cool storage layer 35. However, during cooling in the summer when the temperature is high, the temperature of the ceiling of the living room 1 can be set wider than the heat storage layer 14 of the cold storage heat floor 10 by the latent heat storage of the third PCM that forms the ceiling cold storage layer 35 that receives the heat of the cooling. Can be stored cold.
Therefore, at the time of cooling in summer when the temperature is higher than the latent heat storage temperature of the floor cool storage layer 18 and the ceiling cool storage layer 35, the floor cool storage layer 18 and the ceiling cool storage layer 35 that receive heat from the cooling store the cool storage heat floor. The temperature of the floor and ceiling of the living room 1 can be lowered and stored in a wider range than the ten heat storage layers 14.

  ADVANTAGE OF THE INVENTION According to this invention, the cold storage heat floor which can aim at shortening of the operation time of air conditioning can be provided by stabilizing room temperature in the summer season and winter season in which air conditioning is required.

It is a longitudinal cross-sectional view which shows the cool storage thermal floor which concerns on this invention. FIG. 2 is a cold storage heat amount-temperature characteristic diagram of the cold storage heat bed of FIG. 1. It is a longitudinal cross-sectional view which shows a cool storage ceiling. It is a schematic plane as an example of a living room to which the present invention is applied.

Embodiments of the present invention will be described below with reference to the drawings.
(Embodiment)
First, FIG. 4 shows a schematic plane as an example of a living room to which the present invention is applied. In the floor plan of the house as shown in the figure, a specific part of the floor of the living room 1 including the living room 2, the dining room 3, and the kitchen 4 ( The cold storage heat floor 10 shown in FIG. 1 is laid in S, and the other floors are cold storage floors. The entire range W including the living room 2, the dining room 3, and the kitchen 4 of the living room 1 is provided in S. A cold storage ceiling 30 shown in FIG. 3 is laid.

Next, FIG. 1 shows a cold storage thermal floor 10 according to the present invention, and is a longitudinal sectional view taken along the line AA in FIG. 4. The cold storage thermal floor 10 is constructed on the ground as shown in the figure. On a floor base material (floor panel) 11 installed on a foundation 5 that has been placed on a base 6, a heat storage plate material (high-strength gypsum board) 13, a heat storage layer (heat storage sheet) 14, a plate material (discarding) Plywood) 16, a cold storage layer (cold storage sheet) 18, and a floor finish (flooring) 19 are laid in order.
In the illustrated example, the floor is the first floor of the building, but it may be the floor of the second floor or more.

That is, the floor panel 11 which is a floor base material has a face material 11c pasted on the upper surface of a frame constituted by vertical and horizontal saddle materials 11a and auxiliary crosspieces 11b, and the lower surface material 11c below the face material 11c. And the heat insulating material 12 is filled in the space part inside the auxiliary | assistant crosspiece 11b. The thickness of the floor panel 11 is about 90 mm.
A heat storage plate 13 is laid on the face material 11 c of the floor panel 11.

The heat storage plate 13 is a high-strength gypsum board that is harder than general gypsum board and has a high heat storage property. The thickness of the high-strength gypsum board 13 is about 9.5 mm.
A heat storage layer 14 is laid on the high-strength gypsum board 13.

The heat storage layer 14 is formed by the first PCM set at a latent heat storage temperature of about 20 ° C., and is formed by a heat storage sheet formed in a sheet shape by dispersing the first PCM in a resin. The thickness of the heat storage sheet 14 is about 7.2 mm.
The heat storage sheet 14 is housed in a plurality of grid frame-shaped sections surrounded by vertical and horizontal long materials 15 attached to the upper surface of the high-strength gypsum board 13. The thickness of the heat storage plate 13 is about 8 mm.

PCM uses latent heat when a substance undergoes a phase change from a solid phase to a liquid phase, or from a liquid phase to a solid phase. When the temperature of the solid phase PCM rises and reaches its melting point, PCM starts melting and absorbs heat of fusion from the outside. Conversely, when the temperature of the PCM in the liquid phase drops and reaches the freezing point, solidification begins and the heat of solidification is released to the outside. Such heat transfer is used.
As PCM, for example, normal paraffin or inorganic hydrate which is a heat storage material is impregnated into a carrier which is a porous material such as calcium chloride hydrate or porous silica.

A plate material 16 is laid on the heat storage sheet 14.
The plate material 16 is a discarded plywood having a thickness of about 12 mm.

Here, the cold storage floor adjacent to the cold storage heat floor 10 employs a floor panel 21 having a thickness of about 120 mm as a floor base material installed on the foundation 5 via the pedestal 6. In the floor panel 21, a face material 21c is affixed to the upper surface of a frame made up of vertical and horizontal saddle members 21a and auxiliary bars (not shown), and the lower part 11c and the auxiliary bars are below the face material 21c. The inner space is filled with a heat insulating material 22.
An adjusting material 17 having a thickness of about 30 mm is disposed along the stepped portion of the end of the floor panel 11 adjacent to the thick floor panel 21 having a thickness of about 120 mm. A high strength is provided along the adjusting material 17. The ends of the gypsum board 13, the long material 15 and the plate material 16 are aligned.
Thereby, the throwing plywood 16, the adjusting material 17, and the face material 21c of the floor panel 21 are continuously flat.

  Then, the cold storage layer 18 is laid on the discarded plywood 16, the adjustment material 17, and the face material 21 c of the floor panel 21.

The cold storage layer 18 is formed of the second PCM set at a latent heat storage temperature of about 27 ° C., and is formed of a cold storage sheet formed in a sheet shape by dispersing the second PCM in a resin. The thickness of the cold storage sheet 18 is about 6 mm.
The cold storage sheet 18 is laid on the entire surface of the floor of the living room 1 shown in FIG. 4 on the discarded plywood 16, the adjusting material 17, and the face material 21 c of the floor panel 21.
A floor finishing material 19 is laid on the cold storage sheet 18.

The floor finish 19 is a flooring having a thickness of about 6 mm.
The flooring 19 is laid on the cold storage sheet 18 over the entire floor of the living room 1 of FIG.

  FIG. 2 is a cold storage heat quantity-temperature characteristic diagram of the cold storage heat floor 10 as described above. As shown in the figure, the room temperature in winter and summer is stabilized by the cold storage heat, and the room temperature is set to 18 to 29 ° C. throughout the year without using air conditioning as much as possible. Can be maintained.

As described above, according to the embodiment, the heat storage sheet 14 that forms the heat storage layer formed by the first PCM is arranged on the floor panel 11, and the latent heat storage temperature is higher than the heat storage sheet 14 from the heat storage sheet 14. The cool storage sheet 18 forming the cool storage layer formed by the second high PCM is disposed.
Therefore, at the time of cooling in summer when the temperature is higher than the latent heat storage temperature of the second PCM of the cold storage sheet 18, the temperature of the floor 10 is lowered by the latent heat storage of the second PCM of the cold storage sheet 18 that first receives the heat of the cooling. Can be stored cold.

And the thermal storage sheet | seat 14 formed of 1st PCM whose latent heat thermal storage temperature is lower than the said cold storage sheet 18 is arrange | positioned under the cold storage sheet 18. As shown in FIG.
Therefore, during the summer cooling when the temperature is higher than the latent heat storage temperature of the first PCM of the heat storage sheet 14, the liquid phase in which the heat storage sheet 14 disposed below the cold storage sheet 18 does not perform latent heat storage due to its own thermal resistance. The first PCM in the state can also be used as a sensible heat storage material.

Further, during heating in winter when the temperature is lower than the latent heat storage temperature of the first PCM of the heat storage sheet 14, a solid phase that does not perform latent heat storage due to its own thermal resistance of the cold storage sheet 18 that first receives the heat of the heating. The second PCM can also be used as a sensible heat storage material, and can be stored by raising the temperature of the floor 10 by the latent heat storage of the first PCM of the heat storage sheet 14 disposed below the cold storage sheet 18.
As described above, the room temperature can be stabilized during the summer and winter seasons when air conditioning is required, and the operation time of air conditioning can be shortened.

  Furthermore, since the plate material 16 is disposed between the heat storage sheet 14 and the cold storage sheet 18 disposed thereabove, the load of the flooring 19 laid on the cold storage sheet 18 is lowered via the cold storage sheet 18. The plate material 16 can be reliably received.

In addition, since the heat storage sheet 14 is set near the latent heat storage temperature 20 ° C., the temperature of the cold storage floor 10 is set to about 20 ° C. due to the latent heat storage of the first PCM of the heat storage sheet 14 during heating in winter. Can be raised and maintained.
In addition, since the cold storage sheet 18 is set near the latent heat storage temperature 27 ° C., the temperature of the entire floor including the cold storage floor 10 is increased by the second PCM latent heat storage of the second storage heat storage sheet 18 when the cooling in the summer is about 27 ° C. or higher. The temperature can be lowered to around 27 ° C. and maintained.

  As a result of the above, as shown in the cold storage heat quantity-temperature characteristic diagram of the cold storage thermal floor 10 shown in FIG. 2, the room temperature in winter and summer is stabilized by the cold storage heat, and the room temperature is kept at 18 to 29 ° C. throughout the year without using air conditioning as much as possible. Can be maintained.

That is, during cooling in the summer, generally, the cold air accumulates in the lower layer, and the cooling operation time used when moving up is short. A relatively thin cold storage sheet 18 can be arranged to stabilize the room temperature at about 24 to 29 ° C.
In addition, during heating in winter, since the heating operation time is longer than the cooling operation time in summer, the heat storage sheet 14 having a thickness of about 7.2 mm is disposed on the lower layer side of the cold storage sheet 18 on the floor, Can be stabilized at about 18 to 22 ° C.

  Then, a heat storage sheet 14 having a thickness of about 7.2 mm formed by dispersing PCM in a resin and a sheet having a latent heat storage temperature higher than that of the heat storage sheet 14 are dispersed in the resin to form a sheet. Further, since the cold storage sheet 18 has a thickness of about 6 mm, both are thin and have little thermal resistance, and the thickness of the cold storage heat floor 10 can be kept thin.

Further, the load of the flooring 19 laid on the cold storage sheet 18 can be reliably received by the plate material 16 below the cold storage sheet 18.
In addition, the cool storage sheet 18 and the flooring 19 may be integrated. That is, the cold storage sheet 18 and the flooring 19 may be bonded at a factory, or the cold storage sheet 18 may be integrally formed with the flooring 19 itself.

  Moreover, since the heat insulating material 12 is arrange | positioned under the floor panel 11, the downward direction of the floor panel 11 is hold | maintained in the heat insulation state with the heat insulating material 12, and at the time of heating in winter, by the thermal storage sheet | seat 14 on the floor panel 11 The heat storage state can be maintained, and the cold storage state of the floor 10 by the cold storage sheet 18 during cooling in summer can be maintained.

That is, since the heat storage plate (high-strength gypsum board) 13, the heat storage sheet 14, and the cold storage sheet 18 are provided on the indoor side of the face material 11c in the floor panel 11 provided with the heat insulating material 12 on the opposite side to the room, Once the heat is transferred from the indoor side to the heat storage plate 13, the heat storage plate 13, the heat storage sheet 14, and the cold storage sheet 18 can store heat or store cold, so in the heat storage sheet 14 and the cold storage sheet 18. A situation in which only a narrow range on the indoor side acts to store heat is less likely to occur. Therefore, the heat storage / cold storage effect of the heat storage sheet 14 and the cold storage sheet 18 can be enhanced, and the heat storage / cold storage effect can be sufficiently exhibited.
As a result, the power consumption of the air conditioner can be reduced, contributing to energy saving, global warming countermeasures, running cost reduction, and the like.

Moreover, since the heat insulating material 12 is provided in the floor panel 11 on the opposite side to the room | chamber interior of the surface material 11c, it becomes difficult to receive the influence of the cool air and warm air from the opposite side to a room by this heat insulating material 12.
Further, when the heat is dissipated, the heat insulating material 12 makes it difficult to dissipate heat to the opposite side of the room, so that more heat stored / cold in the heat storage sheet 14, the cold storage sheet 18 and the heat storage plate 13 is dissipated to the indoor side. can do.

  Moreover, since the heat storage board 13 is attached to the indoor side surface of the face material 11c in the floor panel 11, and the flooring 19 is located on the indoor side of the heat storage sheet 14 and the cold storage sheet 18, a high-strength gypsum board which is a heat storage board 13 can be used as a fixed base for fixing the flooring 19.

Moreover, since the part in which the heat storage sheet 14 is stored is surrounded by a plurality of long materials 15 attached to the indoor side surface of the high-strength gypsum board 13, the storage space for the heat storage sheet 14 is used as the high-strength gypsum board 13. And a plurality of long materials 15 and a flooring 19. As a result, a storage space for the heat storage sheet 14 can be secured, and the heat storage sheet 14 can be reliably surrounded and protected.
Furthermore, since the flooring 19 is supported by the high-strength gypsum board 13 through the long material 15, the flooring 19 is supported from the high-strength gypsum board 13 at intervals of a plurality of long materials 15 minutes. Can do. Thereby, the flooring 19 can be reliably fixed to the high-strength gypsum board 13 via the long material 15 while ensuring a storage space for the heat storage sheet 14.

Further, since the heat storage plate 13 and the heat storage sheet 14 are provided in the space formed by utilizing the difference in thickness between the floor panel 11 and the floor panel 21, the difference in thickness between the floor panel 11 and the floor panel 21 is provided. The step which arises can be used effectively.
Furthermore, since the thick floor panel 21 is comprised including the heat insulating material 22, it can acquire a high heat insulation effect. Furthermore, since such a floor panel 21 is provided adjacent to the floor panel 11 of the cold storage thermal floor 10 having a high heat storage effect, both floor panels 11 and 21 can contribute to alleviating changes in room temperature. become.

  Moreover, since the face material 11c of the floor panel 11 is a floor base material constituting the floor of the building frame, the heat storage / cold storage effect can be sufficiently exerted on the indoor side of the face material 11c that is the floor base material. Possible heat storage layers 14 and cold storage layers 18 can be formed. As a result, changes in the room temperature can be mitigated.

  Moreover, since the heat storage sheet 14 is laid in the specific part S of the floor of the living room 1, the cold storage sheet that receives the heat of the heating at the time of heating in winter when the temperature is lower than the latent heat storage temperature of the PCM of the heat storage sheet 14 The solid phase second PCM that does not perform latent heat storage due to its own thermal resistance can also be used as sensible heat storage, and the latent heat storage of the first PCM of the heat storage sheet 14 disposed below the cold storage sheet 18 Only the specific part S of the floor of 1 can raise temperature and can store heat.

  Since the cool storage sheet 18 is laid on the entire floor of the living room 1, the cooling heat sheet 18 first receives the heat of the cooling during the summer cooling when the temperature is higher than the latent heat storage temperature of the second PCM of the cool storage sheet 18. By the latent heat cold storage of the second PCM of the cold storage sheet 18, the temperature of the entire floor of the living room 1 can be lowered to store cold.

  Next, FIG. 3 shows the regenerator ceiling 30, and the regenerator ceiling 30 is arranged under the ceiling base material (high-strength gypsum board) 31 as shown in the entire range W of the living room 1. A ceiling cold storage sheet) 35 and a ceiling finishing material (ordinary hard plaster board) 36 are laid in order.

That is, the high-strength gypsum board 31 that also serves as a heat storage plate material with a ceiling base material is a bottom surface of a vertical and horizontal crosspiece 32 fixed to the face material 42 of the wall panel 41 and the core material (not shown) continuous from the cold storage floor described above. Is attached. The heat insulating material 33 is laid on the vertical and horizontal crosspieces 32, the heat insulating material 43 is filled on the outer wall side of the face material 42 of the wall panel 41, 45 is a beam material, and 47 is an outer wall material. The thickness of the high-strength gypsum board 31 is about 12.5 mm.
A ceiling cold storage layer 35 is laid under the high-strength gypsum board 31.

The ceiling cold storage layer 35 is formed of the third PCM set near the latent heat storage temperature 27 ° C., similarly to the cold storage sheet 18 of the cold storage heat floor 10, and the third PCM is dispersed in resin to form a sheet. It is formed by the ceiling cold storage sheet formed in the. The thickness of the ceiling cold storage sheet 35 is about 6 mm.
The ceiling regenerator sheet 35 is laid over the entire ceiling of the living room 1 in FIG. 4 under the high-strength gypsum board 31.
A ceiling finishing material 36 is laid under the ceiling cold storage sheet 35.

The ceiling finishing material 36 is a normal hard gypsum board having a thickness of about 9.5 mm.
The ordinary hard plaster board 36 is laid under the cold storage sheet 35 over the entire ceiling surface (the entire range W) of the living room 1 of FIG.
Thus, it becomes the cold storage ceiling 30 of a semi-incombustible specification.
The cold storage sheet 35 and the normal hard gypsum board 36 may be integrated. That is, the cold storage sheet 35 and the normal hard gypsum board 36 may be bonded at the factory, or the cold storage sheet 35 may be integrally formed on the normal hard plaster board 36 itself.

As described above, according to the embodiment, the ceiling cold storage sheet 35 that forms the ceiling cold storage layer formed by the third PCM having a higher latent heat storage temperature than the heat storage sheet 14 of the cold storage heat floor 10 below the ceiling base material 31 of the living room 1. Is arranged.
Therefore, at the time of cooling in summer when the temperature is higher than the latent heat storage temperature of the third PCM forming the ceiling cool storage sheet 35, the cooling heat is transferred to the ceiling of the living room 1 by the latent heat storage of the third PCM of the ceiling cool storage sheet 35. The temperature can be lowered to store cold.

As a result, during the cooling in summer when the temperature is higher than the latent heat storage temperature of the floor cold storage sheet 18 and the ceiling cold storage sheet 35, the latent heat storage of the floor cold storage sheet 18 and the ceiling cold storage sheet 35 that receives the heat of the cooling causes Both floor and ceiling temperatures can be lowered to store cold.
As described above, the room temperature can be stabilized during the summer season when cooling is required, and the cooling operation time can be shortened.

  Moreover, because the ceiling cold storage sheet 35 having a thickness of about 6 mm is formed by dispersing the third PCM, which has a higher latent heat storage temperature than the heat storage sheet 14 of the cold storage floor 10, into a sheet, the ceiling cold storage layer is thin. There is little heat resistance and the thickness of the cool storage ceiling 30 can be suppressed thinly.

Further, since the ceiling cold storage sheet 35 is laid on the entire surface of the ceiling base material 31, the cooling heat is received during the cooling in summer when the temperature is higher than the latent heat storage temperature of the third PCM of the ceiling cold storage sheet 35. By the latent heat storage of the third PCM of the ceiling cool storage sheet 35, the temperature of the ceiling surface of the living room 1 can be lowered to store cold.
Therefore, at the time of cooling in summer when the air temperature is higher than the latent heat storage temperature of the floor cool storage sheet 18 and the ceiling cool storage sheet 35, the first PCM and the third PCM of the floor cool storage sheet 18 and the ceiling cool storage sheet 35 that receive the heat of the cooling. By sensible heat storage of PCM, the temperature of the entire floor and ceiling of the living room 1 can be lowered and stored.

  Further, since the heat insulating material 33 is disposed on the vertical and horizontal crosspieces 32 to which the high-strength gypsum board 31 as the ceiling base material is attached, the heat insulating material 33 insulates the ceiling base material (high-strength gypsum board) 31 from above. The cold storage state of the cold storage ceiling 30 by the ceiling cold storage sheet 35 can be maintained during cooling in the summer.

That is, since the heat storage plate material (high-strength gypsum board) 31 and the ceiling cold storage sheet 35 are provided on the indoor side of the cold storage ceiling 30 provided with the heat insulating material 33 on the opposite side to the room, it receives heat from the indoor side. Once the heat is transmitted to the heat storage plate 31, it can be stored in both the heat storage plate 31 and the cold storage sheet 35, so that only the narrow range on the indoor side of the ceiling cold storage sheet 35 acts to store heat. Is less likely to occur. Therefore, the cold storage effect of the ceiling cold storage sheet 35 can be enhanced, and the cold storage effect can be sufficiently exhibited.
As a result, the power consumption of the air conditioner can be reduced, contributing to energy saving, global warming countermeasures, running cost reduction, and the like.

Further, since the heat insulating material 33 is provided on the opposite side of the cold storage ceiling 30 to the room, the heat insulating material 33 makes it less likely to be affected by warm air from the opposite side of the room.
Further, when the heat is dissipated, the heat insulating material 33 makes it difficult to dissipate heat to the opposite side of the room, so that more heat stored in the ceiling cold storage sheet 35 and the heat storage plate 31 can be dissipated to the indoor side.

  Further, since the heat storage plate 31 is attached to the indoor side surface of the cold storage ceiling 30 and the ordinary hard gypsum board 31 is located on the indoor side of the ceiling cold storage sheet 35, the high-strength gypsum board 31 that is a heat storage plate is It can be used as a fixing base for fixing the hard gypsum board 31.

(Modification)
In the above embodiment, the floor base material is a floor panel and the ceiling base material is a ceiling panel. However, the present invention is not limited to this, and the floor base material and the ceiling base material may be plate materials. .
In the embodiment, the cold storage layer is provided on the entire surface (entire range) of the floor and the ceiling. However, the cold storage layer may be provided in a range wider than at least the heat storage layer, and the range in which the cold storage layer is provided is not limited to the entire surface of the floor and ceiling. .
Furthermore, the thickness dimension etc. of each structural member of a cool storage thermal floor and a cool storage ceiling are also arbitrary, Of course, it can change suitably also about a specific detailed structure.

1 Living room S Specific place on the floor of the living room 10 Cold storage thermal floor 11 Floor base material (floor panel)
12 Heat insulation material 13 Heat storage plate material (high-strength gypsum board)
14 Heat storage layer (heat storage sheet)
15 Long material 16 Board material (Discarded plywood)
17 Adjustment material 18 Cold storage layer (cool storage sheet)
19 Floor finish (flooring)
21 Floor material (floor panel)
22 Heat insulating material 30 Cold storage ceiling 31 Ceiling base material (heat storage plate material, high-strength gypsum board)
32 Bar material 33 Heat insulation material 35 Cold storage layer (cool storage sheet)
36 Ceiling finish (ordinary hard plaster board)
41 Wall materials (wall panels)
42 Face material 43 Heat insulation material 45 Beam material 47 Exterior wall material

Claims (9)

A heat storage layer disposed on the floor base material and formed of the first latent heat storage material;
A cold storage layer disposed above the heat storage layer and formed of a second latent heat storage material having a higher latent heat storage temperature than the heat storage layer; and
A plate material disposed between the heat storage layer and the cold storage layer;
A cold storage heat floor characterized by comprising. In the cold-storage heat storage floor according to claim 1,
The heat storage layer is set near a latent heat storage temperature of 20 ° C.,
The cold-storage bed is characterized in that the cold-storage layer is set near a latent heat storage temperature of 27 ° C. In the cold-storage thermal floor according to claim 1 or 2,
A cold storage heat floor, wherein flooring is disposed on the cold storage layer. In the cold-storage heat storage floor according to any one of claims 1 to 3,
The heat storage layer is a heat storage sheet formed in a sheet shape by dispersing the first latent heat storage material in a resin,
The cold storage layer is a cold storage sheet formed in a sheet shape by dispersing the second latent heat storage material having a higher latent heat storage temperature than the heat storage layer in a resin. In the cold storage heat storage floor according to any one of claims 1 to 4,
A cold storage heat floor, wherein a heat insulating material is disposed under the floor base material. In the cold-storage heat storage floor according to any one of claims 1 to 5,
The heat storage layer is laid in a specific place on the floor of the living room,
The cold storage heat floor is laid on the floor of the living room in a wider range than the heat storage layer. In a living room provided with the cold storage thermal floor as described in any one of Claim 1 to 6,
A ceiling cold storage layer formed of a third latent heat storage material having a latent heat storage temperature higher than that of the heat storage layer of the cold storage heat floor is disposed under the ceiling base material of the living room. In the living room according to claim 7,
The living room characterized in that the ceiling cold storage layer is a ceiling cold storage sheet formed in a sheet shape by dispersing the third latent heat storage material having a higher latent heat storage temperature than the heat storage layer of the cold storage floor in a resin. In the room according to claim 7 or 8,
The ceiling cold storage layer is laid on the ceiling of the living room in a range wider than the heat storage layer of the cold storage heat floor.

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