JP7057881B2 - Wall structure - Google Patents

Description

The present invention relates to a wall structure capable of adjusting the temperature in a room by a heat storage material provided inside the wall and absorbing sound generated in the room.

Conventionally, when adjusting the temperature in a room, an air conditioner such as an air conditioner is usually used. In this case, when the air conditioner is stopped, it is difficult to maintain the room temperature, and the fluctuation of the room temperature becomes large. For example, if the room is heated by heating the air conditioner and then stopped, the temperature of the room will drop. In addition, at the start of heating, the energy of the air conditioner becomes large, and energy saving cannot be achieved.

Therefore, for example, a heat storage facility as disclosed in Patent Document 1 below has been proposed. By controlling the fan, this heat storage facility can bring the air taken into the wall from the room through the intake to the heat storage body in the wall and then discharge it into the room through the discharge port. It is a thing. With such a configuration, heat energy can be stored and the stored heat energy can be released into the room to adjust the temperature in the room, and energy saving can be achieved.

Further, in a house or the like, in addition to the above-mentioned problem of room temperature adjustment, there is a problem of sound generated indoors. Various proposals have been made to solve this problem, such as installing a soundproofing material on the wall.

In this way, the problem of room temperature adjustment and the problem of sound in the room are solved by individual methods. Therefore, there is a problem that the cost becomes large, and it is desired to solve it.

Japanese Unexamined Patent Publication No. 10-169028

The present invention has been made in view of such a problem, and its main purpose is a wall capable of adjusting the room temperature with energy saving and absorbing sound generated in a room with a simple configuration. To provide the structure.

The wall structure according to the present invention for achieving the above object includes a heat insulating material, a heat storage material, and a perforated plate having a large number of through holes, and the heat insulating material is provided from the inside of the wall toward the indoor side. The heat storage material and the perforated plate are arranged in this order, and the interior and the inside of the wall are communicated through the through hole. The heat storage material is provided for each of the upper and lower shelves provided in the wall. Are provided along the width direction of the wall and are provided with a gap between the perforated plate and the heat insulating material, and the shelf materials extend in the width direction of the wall and are provided in the thickness direction of each other. It has a pair of horizontal pieces arranged at intervals and a connection piece for connecting the pair of horizontal pieces to each other, and each of the heat storage materials straddles the pair of horizontal pieces and each stage. It is characterized in that it is installed with a gap between the heat storage materials in the above, and the distance between the heat storage materials adjacent to each other along the width direction of the wall can be changed in each stage.

Further, the wall structure according to the present invention includes a heat insulating material formed of a sound absorbing material, a heat storage material, and a perforated plate having a large number of through holes, and the heat insulating material is provided from the inside of the wall toward the indoor side. A wall structure in which the material, the heat storage material, and the perforated plate are arranged in this order, and the inside of the room and the inside of the wall are communicated through the through hole. A plurality of the heat storage materials are provided along the width direction of the wall and are provided with a gap between the heat storage materials and the perforated plates . It has a pair of horizontal pieces arranged at intervals and a connection piece for connecting the pair of horizontal pieces to each other, and each of the heat storage materials straddles the pair of horizontal pieces and is in each stage. The heat storage materials are installed with a gap between them, and the distance between the heat storage materials adjacent to each other along the width direction of the wall can be changed at each stage, and the heat storage materials and the heat insulating material come into contact with each other. Therefore, a gap is not formed between the heat storage material and the heat insulating material.

Further, the wall structure according to the present invention is characterized in that the distance between the heat storage materials can be changed by being detachably provided at a predetermined position of the shelf material.

Further, in the wall structure according to the present invention, a plurality of slide pieces slidable along the width direction of the wall are erected on the pair of horizontal pieces, and the heat storage material is fixed to the upper surface of the slide pieces. Moreover, the interval can be changed by sliding the slide piece .

Further, in the wall structure according to the present invention, instead of or in addition to being able to change the distance between the heat storage materials adjacent to each other in each stage, in the upper region in the wall, the wall is attached to the shelf material. The arrangement density of the plurality of heat storage materials provided along the width direction of the shelf material is the arrangement density of the plurality of heat storage materials provided on the shelf material along the width direction of the wall in the lower region below the upper region. It is characterized by being denser than.

Further, in the wall structure according to the present invention, the two perforated plates are arranged so as to overlap each other, and an opening is formed by overlapping the through hole of one perforated plate and the through hole of the other perforated plate. It is characterized in that the degree of opening of the opening is adjusted by sliding one or both perforated plates along the width direction of the wall.

According to the wall structure according to the present invention, the interior and the inside of the wall are communicated with each other through a through hole of a perforated plate, and a heat storage material is provided in the wall. Therefore, heat can be stored in the heat storage material, and the stored heat can be released into the room. In addition to this, since the distance between adjacent heat storage materials can be appropriately changed, it is possible to absorb sound having a frequency corresponding to the distance dimension. In this way, it is possible to absorb the sound generated in the room by utilizing the structure for adjusting the room temperature using the heat storage material.

Further, according to the wall structure according to the present invention, the interior and the inside of the wall are communicated with each other through the through holes of the perforated plate, and a heat storage material is provided in the wall. Therefore, heat can be stored in the heat storage material, and the stored heat can be released into the room. In addition to this, since the distance between adjacent heat storage materials can be appropriately changed, it is possible to absorb sound having a frequency corresponding to the distance dimension. Further, since the heat insulating material is formed of a material capable of absorbing sound, the sound absorbing effect can be further improved. Further, since the heat insulating material is formed of a sound-absorbing material, it is not necessary to form a gap between the heat storage material and the heat insulating material, and compactification can be achieved.

Further, according to the wall structure according to the present invention, the distance between adjacent heat storage materials can be easily adjusted by attaching the heat storage material to the shelf material or removing the heat storage material from the shelf material.

Further, according to the wall structure according to the present invention, the distance between adjacent heat storage materials can be easily adjusted by sliding each heat storage material.

Further, according to the wall structure according to the present invention, the arrangement density of the heat storage material arranged in the upper region in the wall is denser than the arrangement density of the heat storage material arranged in the lower region in the wall. Sound generated in the vicinity can be effectively absorbed.

Further, according to the wall structure according to the present invention, the opening degree of the opening can be adjusted by sliding the perforated plate, so that the frequency can be adjusted according to the opening degree of the perforated plate with a simple configuration. Can absorb sound.

It is a schematic front view which shows Example 1 of the wall structure of this invention. It is a schematic plan view of the wall structure of FIG. It is a schematic vertical sectional view of the wall structure of FIG. It is a schematic front view of a perforated plate used for the wall structure of FIG. 1, (a) shows a state where an opening formed by overlapping through holes is open, and (b) shows a state where an opening is closed. There is. It is a schematic front view which shows Example 2 of the wall structure of this invention. It is a schematic vertical sectional view of the wall structure of FIG. It is a schematic front view which shows Example 3 of the wall structure of this invention, and it shows by omitting a part. It is a schematic vertical sectional view of the wall structure of FIG.

Hereinafter, specific examples of the wall structure of the present invention will be described in detail with reference to the drawings.

1 to 3 are views showing the first embodiment of the wall structure of the present invention, FIG. 1 is a schematic front view, FIG. 2 is a schematic plan view, and FIG. 3 is a schematic vertical sectional view. The wall structure 1 of this embodiment includes a heat insulating material 2, a heat storage material 3, and a perforated plate 4, which are arranged in the order of the heat insulating material 2, the heat storage material 3, and the perforated plate 4 from the inside of the wall toward the indoor side. Will be done. Here, a case where the wall structure 1 of the present embodiment is applied to the wall partitioning the outside and the inside of the wall of the room will be described.

The heat insulating material 2 is formed in a plate shape having a substantially quadrangular front view, and is provided by being fitted into each space formed in a frame shape by a pillar material 5 and a cross member (not shown) which are structural frames of a building. Will be. The material of the heat insulating material 2 is not particularly limited, but it is preferably formed of a material capable of absorbing sound. For example, sound-absorbing materials include glass wool and rock wool. Here, the heat insulating material 2 is formed in a plate shape, but is not limited to this, and may be, for example, a bag filled with a fibrous heat insulating material. At this time, the fibrous heat insulating material is preferably a sound-absorbing material such as glass wool or rock wool.

A heat storage material 3 is arranged in front of the heat insulating material 2. In this embodiment, a plurality of heat storage materials 3 are provided for each of the shelf materials 6 provided in the upper and lower multiple stages (six stages in the illustrated example) in the wall. Each shelf material 6 of this embodiment is configured to include an upper support portion 7 and a lower support portion 8 arranged apart from each other in the vertical direction (wall height direction).

The upper support portion 7 has horizontal pieces 9 and 9 arranged apart from each other in the front-rear direction (wall thickness direction), and a connection piece 10 connecting the front and rear horizontal pieces 9 and 9 to each other. The front and rear horizontal pieces 9 and 9 are rod-shaped and arranged along the left-right direction (the width direction of the wall), and they are connected by a plurality of connecting pieces 10. Each connection piece 10 is rod-shaped and arranged along the front-rear direction. At this time, the plurality of connection pieces 10 are arranged so as to be spaced apart from each other along the left-right direction.

A plurality of grooves 11 that open downward are formed in the horizontal piece 9 on the front side of the upper support portion 7. The plurality of grooves 11 are formed in the front horizontal piece 9 so as to be separated from each other along the left-right direction. In this embodiment, a plurality of grooves 11 are formed in the horizontal piece 9 on the front side at equal intervals in the left-right direction. Each groove 11 that opens downward is formed so as to open forward and backward. A plurality of recesses 12 that open downward are formed in the horizontal piece 9 on the rear side of the upper support portion 7. The plurality of recesses 12 are formed in the lateral piece 9 on the rear side so as to be separated from each other along the left-right direction. In this embodiment, a plurality of recesses 12 are formed in the horizontal piece 9 on the rear side at equal intervals in the left-right direction. Each recess 12 that opens downward is also formed so as to open forward. Each groove 11 and each recess 12 are arranged so as to correspond to each other in the front-rear direction in a state where the front and rear horizontal pieces 9 and 9 are connected by the connection piece 10.

On the other hand, the lower support portion 8 has a configuration in which the upper support portion 7 is turned upside down. That is, in the same manner as the upper support portion 7, the front and rear horizontal pieces 13 and 13 arranged along the left-right direction are connected to each other by a plurality of connection pieces 14 separated from each other along the left-right direction, and the front horizontal piece is connected. A plurality of grooves 15 are formed in the 13 and a plurality of recesses 16 are formed in the lateral piece 13 on the rear side corresponding to the plurality of grooves 15 in the front-rear direction. Each groove 15 is formed so as to be vertically open upside down from the groove 11 of the upper support portion 7, and is formed so as to be open forward and rearward. Further, each recess 16 is formed so as to open upward and open forward, which is upside down from the recess 12 of the upper support portion 7.

The upper support portion 7 and the lower support portion 8 respectively project forward from the pillar material 5 of the building, and the lateral pieces 9 and 13 on the rear side are fixed to the pillar material 5 with nails or the like. At this time, the upper support portion 7 and the lower support portion 8 are arranged apart from each other in the vertical direction. Further, in the state of being connected to the pillar member 5, the groove 11 of the upper support portion 7 and the groove 15 of the lower support portion 8 are arranged vertically corresponding to each other, and the recess 12 and the lower portion of the upper support portion 7 are arranged. The recess 16 of the side support portion 8 is arranged vertically and vertically so as to correspond to each other. In this way, each shelf material 6 is attached to the pillar material 5 in the wall, and at that time, the vertically adjacent shelf materials 6, 6 are arranged vertically separated from each other.

A plurality of heat storage materials 3 are provided on each shelf material 6. Each heat storage material 3 contains a latent heat storage agent in a hollow container, and is formed in a plate shape having a substantially quadrangular side view. Here, the latent heat storage agent is one that repeatedly melts and solidifies to store heat and dissipate heat, and conventionally known ones are used.

As shown in FIG. 3, in each stage, the four corners of the heat storage material 3 are supported by the shelf material 6. Specifically, the front upper corner portion and the rear upper corner portion of the heat storage material 3 are inserted into the groove 11 of the upper support portion 7 and the recess 12 of the upper support portion 7, respectively, and the front lower corner portion and the rear side of the heat storage material 3 are inserted. The lower corner portion is inserted into the groove 15 of the lower support portion 8 and the recess 16 of the lower support portion 8, respectively. As described above, since the upper and lower grooves 11 and 15 of the shelf material 6 are formed by opening forward and backward, the heat storage material 3 is formed in the upper and lower grooves 11 and 15 of the shelf material 6 from the front of the shelf material 6. It can be pushed backward while being passed through and inserted into the upper and lower recesses 12 and 16 of the shelf material 6. Therefore, each heat storage material 3 is detachably provided at a predetermined position of the shelf material 6. In this way, a plurality of heat storage materials 3 are provided along the left-right direction on each of the shelf materials 6, and a plurality of heat storage materials 3 are provided at equal intervals in the left-right direction. At this time, each heat storage material 3 is arranged with the plate surface facing the left-right direction. Since the rear end portions of the heat storage material 3 are inserted into the upper and lower recesses 12 and 16 of the shelf material 6, a gap 17 is formed between the rear end surface of the heat storage material 3 and the front surface of the heat insulating material 2.

Two perforated plates 4, 4 are arranged in front of the heat storage material 3 so as to overlap each other. Each perforated plate 4 is formed in the shape of a substantially quadrangular front view, and has a large number of through holes 18. Each through hole 18 is an elongated hole elongated in the left-right direction, and is formed so as to penetrate in the thickness direction of the perforated plate 4. In the illustrated example, each through hole 18 is formed in a substantially oval shape in front view. The through holes 18 formed in the respective perforated plates 4 have the same shape.

The two perforated plates 4 and 4 are arranged with their plate surfaces facing in the front-rear direction, and the plate surfaces are overlapped with each other. At this time, the perforated plate 4 arranged on the front side is slidable in the left-right direction with respect to the perforated plate 4 arranged on the rear side. For example, the perforated plate 4 arranged on the front side may be configured like a sliding door. Typically, lateral members are arranged above and below the front perforated plate 4, respectively, and the upper end of the front perforated plate 4 is slidable into a groove formed by opening downward to the upper lateral member. At the same time, the lower end portion of the perforated plate 4 on the front side is slidably inserted into the groove formed by opening upward to the lower lateral member.

4A and 4B are schematic front views of the perforated plate 4 of this embodiment, in which FIG. 4A is a state in which the through holes 18 and 18 of the front and rear perforated plates 4 and 4 are overlapped with each other, and FIG. It shows a state in which the through holes 18 and 18 of the holes 4 and 4 are displaced from each other. As shown in this figure, since the perforated plate 4 on the front side is slidable as described above, the through holes 18 and 18 of the front and rear perforated plates 4 and 4 are overlapped with each other, and the front side is present. The hole plate 4 can be slid to the left so that the front and rear through holes 18 and 18 are displaced from each other. On the contrary, by sliding the front perforated plate 4 to the right from the state where the through holes 18 and 18 of the front and rear perforated plates 4 and 4 are displaced from each other, the front and rear perforated plates 4 , 4 through holes 18, 18 can be overlapped with each other. That is, the plurality of through holes 18 formed in the front and rear perforated plates 4 and 4 are formed at positions where the through holes 18 and 18 overlap or deviate from each other due to the slide of the perforated plates 4.

A plurality of openings 19 are formed by overlapping the through hole 18 of the perforated plate 4 arranged on the front side and the through hole 18 of the perforated plate 4 arranged on the rear side. Each opening 19 is formed by penetrating the through holes 18 and 18 in the front-rear direction in a substantially oval shape in front view when the through holes 18 and 18 are completely overlapped with each other, and is formed on the front side when the through holes 18 and 18 are completely displaced from each other. The through hole 18 of the perforated plate 4 is closed by the perforated plate 4 on the rear side, and the through hole 18 of the perforated plate 4 on the rear side is closed by the perforated plate 4 on the front side, so that the opening 19 is not formed. .. Therefore, the presence or absence of each opening 19 can be switched by sliding the perforated plate 4 on the front side. In this embodiment, since the perforated plate 4 on the front side is slid, not only the presence / absence of the opening 19 but also the degree of opening of the opening 19 can be adjusted. That is, a part of the through holes 18 and 18 can be overlapped with each other, and the degree of overlap can be adjusted.

The interior space and the space inside the wall are separated by the two perforated plates 4 and 4. Therefore, the inside of the room and the inside of the wall communicate with each other through the through holes 18, 18 of the front and rear perforated plates 4, 4, that is, the openings 19. On the other hand, in the state where the through holes 18 and 18 are closed, that is, in the state where the opening 19 is not formed, the inside of the room and the inside of the wall are not communicated with each other through the perforated plate 4. As described above, the heat storage material 3 and the heat insulating material 2 are provided in the wall communicating with the room. At this time, the two perforated plates 4 and 4 are arranged at intervals from each shelf material 6. That is, each heat storage material 3 is provided behind the rear perforated plate 4 with a gap 20 between the rear perforated plate 4 and the rear perforated plate 4. The gap 20 is formed between the front end surface of each heat storage material 3 and the rear surface of the perforated plate 4 on the rear side.

In the case of the wall structure 1 of the present embodiment, since the heat storage material 3 is provided in the wall communicating with the room through the opening 19 of the perforated plate 4, when the room is heated by a heating device such as an air conditioner. Can store the heat in the heat storage material 3 through the opening 19 of the perforated plate 4, and after the heating equipment is stopped, heat is transferred from the heat storage material 3 to the room through the opening 19 of the perforated plate 4. Can be released. Therefore, the room temperature can be maintained even after the heating device is stopped. Further, in the case of the wall structure 1 of the present embodiment, since the plate-shaped heat storage materials 3 are arranged at intervals in the left-right direction, air can be circulated between the adjacent heat storage materials 3 and 3. Therefore, it is possible to more effectively store heat in the heat storage material 3. Further, in the case of the wall structure 1 of the present embodiment, since the heat insulating material 2 is provided, it is possible to prevent the heat in the room from escaping to the outside.

Further, in the case of the wall structure 1 of the present embodiment, since the plate-shaped heat storage materials 3 and 3 are arranged facing each other at intervals, they are generated indoors and enter through the opening 19 of the perforated plate 4. The generated sound can be absorbed by the heat storage material 3. Further, in the shelf material 6 of each stage, the heat storage material 3 can be attached and detached to change the distance between the heat storage materials 3 and 3 adjacent to each other. It can absorb sound. Typically, when the distance between the heat storage materials 3 and 3 is large, low sound can be absorbed, and when the distance between the heat storage materials 3 and 3 is small, high sound can be absorbed. Here, in the present embodiment, in the shelf material 6 of each stage, each heat storage material 3 is detachable at a predetermined position of the shelf material 6, so that the interval between the adjacent heat storage materials 3 and 3 can be changed. can. That is, the space between the heat storage materials 3 and 3 can be increased by removing the heat storage material 3 from the shelf material 6, and the heat storage material 3 can be attached to the space where the shelf material 6 is open. The interval between can be reduced. Therefore, the spacing between the adjacent heat storage materials 3 and 3 can be easily changed. The interval between the heat storage materials 3 and 3 is changed particularly at the time of remodeling when the perforated plate 4 is removed.

Further, in the case of the wall structure 1 of the present embodiment, since the front and rear horizontal pieces 9 and 9 and the front and rear horizontal pieces 13 and 13 are used for the shelf material 6, the front and rear horizontal pieces 9 and 9 and the front and back of the shelf material 6 are used. The space above the shelf material 6 and the space below the shelf material 6 are communicated with each other through the gaps between the horizontal pieces 13 and 13. Therefore, since it is possible to secure the flow of air in the vertical direction, it is possible to effectively store heat in the heat storage material 3 and dissipate heat from the heat storage material 3. Further, in the case of the wall structure 1 of the present embodiment, the degree of opening of the opening 19 can be adjusted by sliding the perforated plate 4 on the front side to the left and right, so that the sound that can be absorbed by the perforated plate 4 can be easily obtained. Can be changed. Typically, when the degree of opening is large, low sound can be absorbed, and when the degree of opening is small, high sound can be absorbed.

Further, in the case of the wall structure 1 of the present embodiment, the heat storage material is obtained by switching the presence or absence of the opening 19 formed by the through hole 18 of the perforated plate 4 on the front side and the through hole 18 of the perforated plate 4 on the rear side. It is possible to switch between a state in which the heat stored in 3 can be dissipated into the room and a state in which the heat is not. Further, in the case of the wall structure 1 of the present embodiment, since the heat insulating material 2 is formed of a material capable of absorbing sound, the sound absorbing effect can be further enhanced.

5 and 6 are views showing the second embodiment of the wall structure of the present invention, FIG. 5 is a schematic front view, and FIG. 6 is a schematic vertical sectional view. The wall structure 1 of the second embodiment basically has the same configuration as that of the first embodiment. Therefore, in the following, the differences between the two will be mainly described, and the corresponding parts will be described with the same reference numerals.

In the first embodiment, the heat storage material 3 is detachably provided on the shelf material 6, so that the interval between the heat storage materials 3 and 3 can be changed. However, in the second embodiment, the heat storage material 3 is provided. By providing the shelf material 6 so as to be slidable along the left-right direction, the distance between the heat storage materials 3 and 3 can be changed. Specifically, it is as follows.

Each shelf material 6 of the second embodiment has a configuration in which each heat storage material 3 is placed, and connects the horizontal pieces 21 and 21 which are arranged apart from each other in the front-rear direction and the front and rear horizontal pieces 21 and 21. It has a connection piece 22 and. The front and rear horizontal pieces 21 and 21 are rod-shaped and arranged along the left-right direction, respectively, and a ridge 23 is formed so as to project upward at the upper end portion. The ridges 23 and 23 formed on the front and rear horizontal pieces 21 and 21 are formed along the left-right direction, respectively. The front and rear horizontal pieces 21 and 21 are connected to each other by a plurality of connecting pieces 22 with the ridges 23 protruding upward. Each connection piece 22 has a rod shape and is arranged along the front-rear direction. At this time, the plurality of connection pieces 22 are arranged so as to be spaced apart from each other along the left-right direction.

Each shelf material 6 is projected forward from the pillar material 5 of the building, and the lateral piece 21 on the rear side is fixed to the pillar material 5 with nails or the like. At this time, the shelf materials 6 and 6 adjacent to each other are arranged so as to be separated from each other in the vertical direction. Further, in the state of being fixed to the pillar member 5, the ridges 23 and 23 formed on the front and rear horizontal pieces 21 and 21 project upward. In this way, the shelf material 6 is provided in the wall in a plurality of upper and lower stages.

A plurality of slide pieces 24 are slidably provided on each shelf material 6. Each slide piece 24 is formed in a substantially rectangular plate shape with the front-rear direction as the longitudinal direction, and is arranged with the plate surface facing up and down. Grooves 25 that open downward are formed on the lower surface of the slide piece 24 so as to be separated from each other in the front-rear direction. The front and rear grooves 25 and 25 are formed along the left-right direction, respectively, and are open to the left and right, respectively. As shown in FIG. 6, in the slide piece 24, the ridge 23 of the front side piece 21 is inserted into the groove 25 on the front side, and the ridge 23 of the rear side piece 21 is inserted into the groove 25 on the rear side. Then, it is placed on the shelf material 6. Therefore, the slide piece 24 can slide in the left-right direction along the ridge 23 with respect to the shelf material 6. The structure in which the slide piece 24 is slidably provided on the shelf material 6 is not limited to this.

A heat storage material 3 is provided on the upper surface of each slide piece 24. At this time, the heat storage material 3 is erected and fixed along the longitudinal direction of the slide piece 24. Here, the heat storage material 3 is fixed to the slide piece 24 with an adhesive or the like, but the present invention is not limited to this, and the heat storage material 3 may be detachably provided on the slide piece 24. For example, a concave insertion portion that opens upward is formed on the upper surface of the slide piece 24, and the lower end portion of the slide piece 24 is inserted into the insertion portion. The heat storage material 3 is formed to have a front-rear length smaller than the front-rear length of the slide piece 24, and is provided at the center of the slide piece 24. Therefore, as shown in FIG. 6, a gap 17 is formed between the heat storage material 3 and the heat insulating material 2.

In the case of the wall structure 1 of the second embodiment, since each heat storage material 3 is slidably provided on the shelf material 6, the distance between the adjacent heat storage materials 3 and 3 can be changed in the shelf material 6 of each stage. As a result, the sound that can be absorbed by the heat storage material 3 can be easily changed. Typically, when increasing the distance between the heat storage materials 3 and 3, one or both of the adjacent heat storage materials 3 and 3 are slid so that the space between the heat storage materials 3 and 3 is widened. The heat storage material 3 may be removed from the shelf material 6. On the other hand, when the space between the heat storage materials 3 and 3 is to be reduced, one or both of the adjacent heat storage materials 3 and 3 are slid so that the space between the heat storage materials 3 and 3 is narrowed, and the heat storage material 3 is moved. It may be added to the shelf material 6. Since other configurations are the same as those in the first embodiment, the description thereof will be omitted.

7 and 8 are views showing the third embodiment of the wall structure of the present invention, FIG. 7 is a schematic front view without a perforated plate, and FIG. 8 is a schematic vertical sectional view. The wall structure 1 of the third embodiment has basically the same configuration as that of the first embodiment. Therefore, in the following, the differences between the two will be mainly described, and the corresponding parts will be described with the same reference numerals.

In the third embodiment, the arrangement density of the plurality of heat storage materials 3 provided in the shelf material 6 in the left-right direction in the upper region 26 in the wall is changed in the left-right direction in the lower region 27 in the wall. It is denser than the arrangement density of the plurality of heat storage materials 3 provided along the line. Specifically, it is as follows.

Each shelf material 6 of the third embodiment has a configuration in which each heat storage material 3 is placed, and connects the horizontal pieces 28, 28 arranged apart from each other in the front-rear direction and the front and rear horizontal pieces 28, 28. It has a connection piece 29. The front and rear horizontal pieces 28 and 28 are each formed in a rod shape and are arranged along the left-right direction. A plurality of recesses 30 that open upward and backward are formed in the lateral piece 28 on the front side so as to be separated from each other in the left-right direction. Further, in the lateral piece 28 on the rear side, a plurality of recesses 31 that open upward and forward are formed so as to be separated from each other in the left-right direction. That is, the lateral piece 28 on the rear side is a left-right inverted version of the horizontal piece 28 on the front side. The front and rear horizontal pieces 28 and 28 are connected by a plurality of connection pieces 29 in a state where the recesses 30 and 31 are arranged so as to correspond to each other in the front and back. Each connection piece 29 is rod-shaped and arranged along the front-rear direction. At this time, the plurality of connection pieces 29 are arranged so as to be spaced apart from each other along the left-right direction.

Each shelf material 6 is projected forward from the pillar material 5 of the building, and the lateral piece 28 on the rear side is fixed to the pillar material 5 with nails or the like. At this time, the shelf materials 6 and 6 adjacent to each other are arranged so as to be separated from each other in the vertical direction. Further, in the state of being fixed to the pillar member 5, each recess 30 of the front horizontal piece 28 opens upward and rearward, and each recess 31 of the rear horizontal piece 28 opens upward and forward. In this way, the shelf material 6 is provided in the wall in a plurality of upper and lower stages.

A plurality of heat storage materials 3 are provided on each shelf material 6. Specifically, each heat storage material 3 is inserted into the recess 30 having the front lower corner portion formed in the front horizontal piece 28 and the rear lower corner portion into the recess 31 formed in the rear horizontal piece 28. The board is placed with the board facing left and right. At this time, the heat storage material 3 may be fixed to the shelf material 6 with an adhesive or the like, or may be detachable from the shelf material 6. As shown in FIG. 8, since the heat storage material 3 is inserted into the recesses 30 and 31 formed in the front and rear horizontal pieces 28 and 28, a gap 17 is formed between the heat storage material 3 and the heat insulating material 2.

Here, the arrangement density of the plurality of heat storage materials 3 arranged on the shelf material 6 along the left-right direction is such that the upper region 26 in the wall is denser than the lower region 27 below it. This is because, typically, in the upper region 26 in the wall, the number of heat storage materials 3 arranged in the shelf material 6 in the left-right direction is changed to the shelf material 6 in the lower region 27 in the wall in the left-right direction. This means that the number is larger than the number of heat storage materials 3 arranged along the line. In other words, in the upper region 26 in the wall, the distance between the heat storage materials 3 and 3 adjacent to each other of the plurality of heat storage materials arranged along the shelf material 6 in the left-right direction is the shelf in the lower region 27 in the wall. It is narrower than the distance between the heat storage materials 3 and 3 adjacent to each other of the plurality of heat storage materials 3 arranged along the left-right direction on the material 6. The upper region 26 is preferably a region arranged at the uppermost position when the inside of the wall is divided into three equal parts in the height direction.

In the illustrated example, six shelves 6 are provided, the first and second shelves 6 from the top are arranged in the upper region 26, and the third, fourth, fifth and six shelves from the top. The second shelf member 6 is arranged in the lower region 27. The arrangement density of the plurality of heat storage materials 3 provided on each shelf material 6 of the upper region 26 is denser than the arrangement density of the plurality of heat storage materials 3 provided on each shelf material 6 of the lower region 27. Here, the interval between the adjacent heat storage materials 3 and 3 of the plurality of heat storage materials 3 arranged on each shelf material 6 of the upper region 26 is preferably an interval capable of absorbing sound of 2 to 4 kHz. The arrangement densities of the plurality of heat storage materials 3 provided on each shelf material 6 in the lower region 27 may be the same or may be different as shown in FIG. 7.

In the case of the wall structure 1 of the third embodiment, the arrangement density of the plurality of heat storage materials 3 arranged in the upper region 26 in the wall is denser than the arrangement density of the plurality of heat storage materials 3 arranged in the lower region 27. Therefore, it is possible to absorb high-pitched sounds generated near the ceiling. For example, it is possible to prevent acoustic disturbances such as flutter echoes that tend to occur near the ceiling. Since other configurations are the same as those in the first embodiment, the description thereof will be omitted.

The wall structure of the present invention is not limited to the configuration of each of the above-described embodiments, and can be appropriately changed. For example, in the first embodiment and the second embodiment, the distance between the adjacent heat storage materials 3 and 3 can be changed, but in addition to this, the heat storage material 3 is arranged as in the third embodiment. It is also good. That is, in the upper region 26 in the wall, the arrangement density of the plurality of heat storage materials 3 provided in the shelf material 6 along the left-right direction is provided in the lower region 27 in the wall along the left-right direction. It is denser than the arrangement density of the plurality of heat storage materials 3. Further, in each of the above embodiments, the gap 17 is formed between the heat storage material 3 and the heat insulating material 2, but when the heat insulating material 2 is formed of glass wool, rock wool, or the like, the gap 17 is formed. It does not have to be. Specifically, the heat storage material 3 and the heat insulating material 2 are brought into contact with each other so that a gap 17 is not formed between the heat storage material 3 and the heat insulating material 2. This is because the heat insulating material 2 formed of glass wool, rock wool, or the like plays the role of an air layer provided behind the heat storage material 3.

Further, in each of the above embodiments, the perforated plate 4 on the front side may be divided into a plurality of upper and lower portions, and each of them may independently slide left and right. In this case, the degree of opening of the opening 19 can be adjusted in each of the upper and lower regions. Further, in each of the above embodiments, the front perforated plate 4 is slidable, but the rear perforated plate 4 may be slidable, and the front and rear perforated plates 4 and 4 are independent of each other. It may be slidable. Further, in each of the above embodiments, two perforated plates 4 are used, but the present invention is not limited to this, and for example, one plate may be used. In this case, the perforated plate 4 is arranged in a fixed state without sliding. Further, in each of the above embodiments, the present invention has been applied to one of the four walls, but the present invention is not limited to this, and may be applied to, for example, two adjacent surfaces. In this case, flutter echo can be prevented more reliably. Further, in each of the above embodiments, the shelf material 6 is fixed to the pillar material 5 which is the structural skeleton of the building, but the present invention is not limited to this, and for example, the shelf material 6 is fixed to the structural skeleton other than the pillar material 5. Alternatively, a support pillar for supporting the shelf material 6 may be separately provided.

The wall structure of the present invention is suitably applied when adjusting the room temperature and absorbing the sound generated in the room with the heat storage material.

1 Wall structure 2 Insulation material 3 Heat storage material 4 Perforated board 6 Shelf material 17 Gap 18 Through hole 19 Opening 20 Gap 26 Upper area 27 Lower area

Claims (6)

A heat insulating material, a heat storage material, and a perforated plate having a large number of through holes are provided, and the heat insulating material, the heat storage material, and the perforated plate are arranged in this order from the inside of the wall toward the indoor side, and the through holes are provided. It is a wall structure in which the inside of the room and the inside of the wall are communicated with each other.
A plurality of the heat storage materials are provided along the width direction of the wall on each of the upper and lower shelves provided in the wall, and a gap is provided between the perforated plate and the heat insulating material.
The shelf material has a pair of horizontal pieces extending in the width direction of the wall and arranged at intervals in the thickness direction of the wall, and a connecting piece connecting the pair of horizontal pieces to each other.
Each of the heat storage materials straddles the pair of horizontal pieces and is installed with a gap between the heat storage materials in each stage.
A wall structure characterized in that the distance between the heat storage materials adjacent to each other along the width direction of the wall can be changed at each stage. A heat insulating material formed of a sound-absorbing material, a heat storage material, and a perforated plate having a large number of through holes are provided, and the heat insulating material, the heat storage material, and the perforated plate are provided from the inside of the wall toward the indoor side. It is a wall structure in which the interior and the inside of the wall are communicated with each other through the through holes.
A plurality of the heat storage materials are provided along the width direction of the wall on each of the upper and lower shelves provided in the wall, and are provided with a gap between the shelf material and the perforated plate.
The shelf material has a pair of horizontal pieces extending in the width direction of the wall and arranged at intervals in the thickness direction of the wall, and a connecting piece connecting the pair of horizontal pieces to each other.
Each of the heat storage materials straddles the pair of horizontal pieces and is installed with a gap between the heat storage materials in each stage.
At each stage, the distance between the heat storage materials adjacent to each other along the width direction of the wall can be changed.
A wall structure characterized in that the heat storage material and the heat insulating material come into contact with each other to form a gap between the heat storage material and the heat insulating material. The wall structure according to claim 1 or 2, wherein each of the heat storage materials is detachably provided at a predetermined position of the shelf material so that the interval can be changed. On the pair of horizontal pieces, a plurality of slide pieces that can slide along the width direction of the wall are erected.
The wall structure according to claim 1 or 2, wherein the heat storage material is fixed to the upper surface of the slide piece, and the interval can be changed by sliding the slide piece . In addition to or in addition to being able to change the spacing between the heat storage materials adjacent to each other in each stage, a plurality of the heat storage materials provided on the shelf material along the width direction of the wall in the upper region in the wall. The feature is that the arrangement density of the heat storage material is denser than the arrangement density of a plurality of the heat storage materials provided on the shelf material along the width direction of the wall in the lower region below the upper region. The wall structure according to any one of claims 1 to 4. The two perforated plates are placed one on top of the other,
An opening is formed by overlapping the through hole of one perforated plate and the through hole of the other perforated plate.
The wall structure according to any one of claims 1 to 5, wherein the degree of opening of the opening is adjusted by sliding one or both perforated plates along the width direction of the wall.

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