JP2014012965A - Flooring having heat storage function - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a flooring which has a heat storage function and which has a simple structure and strength sufficient for a floor material.SOLUTION: A flooring 1, which is used as a floor finishing material, assumes a rectangular planar shape. A plurality of recesses 2 like a shallow pan in a plan view are provided on its backside, and a heat storage sheet S, in which a plurality of bags 4 with an encapsulated gelatinous heat storage material 3 are structurally connected together, is stuck thereon. Each of the bags 4 of the heat storage sheet S is fitted into the recesses 2.

Description

  The present invention relates to a flooring having a heat storage function, and more particularly to a flooring that stores indoor heat or cold to increase thermal efficiency in air conditioning.

  2. Description of the Related Art Conventionally, floor boards (floor panels) used as floor finish materials have been disclosed that can uniformly warm or cool the entire floor surface by combining heat media. Such a floor panel is a box-structured panel made of plywood or metal plate and having a space formed inside almost the entire surface, and a liquid heat medium such as freon or brine is enclosed in the internal space. Configured. The heat medium is sealed in a container such as a bag or box made of resin and stored in the space portion.

JP 59-38530 A

  By the way, since the floor panel has a box structure in which a space is formed in the entire surface, there is a problem that the strength is insufficient as compared with a general flooring composed of various wood materials. . Further, since the liquid heat medium is sealed, the housing structure is complicated, and there is a problem that the manufacturing cost cannot be reduced. On the other hand, from the viewpoint of increasing the thermal efficiency in indoor air conditioning, it is desirable to use a heat storage material having a larger heat capacity to store indoor heat or cold.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a flooring having a heat storage function and having a simple structure and sufficient strength as a flooring material. .

  In order to solve the above-described problems, in the present invention, heat storage having a structure in which a plurality of shallow dish-shaped recesses are provided on the back surface of a flooring used as a floor finish material, and a plurality of bags encapsulating heat storage materials are connected. The heat storage material was integrated with the flooring by sticking the sheet to the back surface of the flooring. In that case, the vertical load applied to the flooring was supported by the outer peripheral portion of each recess by fitting each bag of the heat storage sheet into the recess.

  That is, the gist of the present invention is a flooring that is used as a floor finish and has a rectangular planar shape, and a shallow dish-shaped concave portion in a plan view is formed on the back surface of the flooring in the longitudinal direction of the flooring. A heat storage sheet having a structure in which a plurality of bags encapsulating gel-like heat storage materials are connected is pasted, and each bag of the heat storage sheet is fitted in a recess. It exists in the flooring which has the heat storage function characterized by this.

  According to the present invention, a heat storage sheet having a structure in which a plurality of bags encapsulating gel-like heat storage materials are connected is used, and the heat storage sheet is attached to the back of the flooring to integrate the flooring and the heat storage material. Therefore, it can be manufactured at low cost. Also, the recesses on the back surface are formed in a shallow dish shape, the recesses are arranged at a constant pitch along the length direction of the flooring, and each bag of the heat storage material is fitted into the recesses on the back surface of the flooring Since the heat storage sheet is configured and the vertical load applied to the flooring is supported by the outer peripheral portion of each concave portion, sufficient strength as a flooring can be exhibited.

It is the expansion | deployment perspective view which showed the main structural members of the flooring which concerns on this invention from the back surface side. It is the expansion | deployment perspective view which showed the main structural member of the other aspect of the flooring which concerns on this invention from the back surface side. It is the longitudinal cross-sectional view which showed partially the structure of the flooring which concerns on this invention.

  An embodiment of a flooring according to the present invention will be described with reference to the drawings. The flooring of this invention shown by the code | symbol 1 in FIGS. 1-3 is a flooring which has a heat storage function, and is used as a floor finishing material and is provided with the rectangular planar shape. The flooring 1 is composed of various wood materials such as matoa, teak, oak, oak, cherry, cypress, maple, urine. The flooring 1 is formed in a long and narrow rectangular shape, the length is about 900 to 2000 mm, the width is about 70 to 350 mm, and the thickness is about 6 to 15 mm.

  The edge of the flooring 1 is provided with a rowing portion that can be fitted to the adjacent flooring 1 (not shown). As the structure of the rowing part, a real structure or a combined structure is usually used. The rowing portion illustrated in the figure is a rowing portion that constitutes the actual construction, and includes a tenon (male ridge portion) and a mortise groove (female ridge portion). In general, since the entire floor is configured by using one kind of flooring 1 of a standard, each of the four edges of the flooring 1 is provided with either a tenon or a tenon groove. That is, in each of the two sets of parallel end edges of the flooring 1, a tenon is provided on one end edge and a tenon groove is provided on the other end edge.

  On the back surface of the flooring 1 of the present invention, in order to accommodate a heat storage material 3 described later, a plurality of shallow dish-shaped recesses 2 formed in an elongated shallow dish shape, for example, a rectangular shape in plan view, are provided. Each recessed part 2 is arrange | positioned at a fixed pitch along the length direction of the said flooring in the state which made the long side run along the width direction of the flooring 1. FIG. Specifically, for example, in the case of the flooring 1 designed to have a length of 1818 mm, a width of 303 mm, and a thickness of 12 mm, the length of the recess 2 parallel to the width direction of the flooring 1 is less than 283 mm, usually 100 to 260 mm. The width of the recess 2 parallel to the length direction of the flooring 1 is set to less than 283 mm, usually 70 to 260 mm.

  In the case of the flooring 1 having the dimensional specifications described above, 6 to 18 recesses 2 are provided on the back surface of the flooring. That is, as shown in FIG. 1, the recesses 2 are arranged along the length direction of the flooring 1 at an arrangement pitch of 101 to 303 mm, for example, so that the long sides of the rectangles are parallel to each other. Thereby, the vertical load applied to the surface of the flooring 1 can be supported by the wood portion between the recesses 2. Of course, a plurality of recesses 2 may be arranged in the width direction of the flooring 1, and a wood portion as a fulcrum in the width direction of the flooring 1 may be provided.

  Further, in order to ensure the strength of the portion corresponding to the concave portion 2 on the surface of the flooring 1, the depth of the concave portion 2 is set within a range of 2/3 or less of the thickness of the flooring 1. Specifically, in the case of the flooring 1 having the above dimensional specifications, the depth of the recess 2 is about 4 to 8 mm. In addition, the recessed part 2 can be normally formed by the cutting process by a grooving machine.

  On the back surface of the flooring 1, a heat storage sheet S having a structure in which a plurality of bags 4 in which gel-like heat storage materials 3 are enclosed is connected is attached. As shown in FIG. 1, the heat storage sheet S is configured as a single sheet. The overall shape of the heat storage sheet S is formed in a rectangle having a slightly smaller area than the shape of the back surface of the flooring 1. The heat storage sheet S is formed by superposing at least two sheets and sealing the gel-like heat storage material 3 formed in a predetermined shape by a method described later, or sandwiching at least two sheets. It is configured by overlapping and forming a plurality of pockets, and housing and storing the heat storage material 3 in these pockets.

  As the sheet constituting the heat storage sheet S, a resin sheet having a thickness of about 0.05 to 1 mm, a metal sheet, a resin / resin laminate sheet, or a resin / metal laminate sheet is used. Examples of the resin constituting the sheet include polyurethane elastomer, polyester, polyamide, polyurethane, polycarbonate, and polyethylene. Examples of the metal constituting the sheet include aluminum and copper, but aluminum is preferable because of its low cost.

  As said heat storage material 3, a gel-like thing is used from a viewpoint on the handling at the time of manufacture and construction. Examples of the gel-like heat storage material 3 include paraffin, calcium chloride hydrate, sodium sulfate hydrate, sodium thiosulfate hydrate, sodium acetate hydrate, etc. Among them, the sheet of the heat storage sheet S is deteriorated. In that case, a paraffin gel in which paraffin is fixed to an olefin-based thermoplastic elastomer is preferable because it is difficult to leak.

The viscosity of the gel-like heat storage material 3 is usually 1 to 1 × 10 ⁷ Pa · s, preferably 5 to 1 × 10 ⁵ Pa · s, preferably 15 ° C. higher than the melting point of the heat storage material. It is preferably 1 × 10 ¹ to 1 × 10 ³ Pa · s. The reason for prescribing the viscosity of the heat storage material 3 is as follows. That is, when the viscosity is less than 1 Pa · s, there arises a problem that the heat storage material 3 flows out when the sheet of the heat storage sheet S deteriorates or the sheet is accidentally damaged. Further, when the viscosity exceeds 1 × 10 ⁷ Pa · s, there is a problem that the heat conduction is deteriorated because the deformation is small and the adhesion with the surrounding member (concave portion 2) is low. In addition, melting | fusing point of the thermal storage material 3 can be measured on temperature rising conditions of 10 degrees C / min by DSC measurement (differential scanning calorimetry).

  The heat storage material 3 is filled in a dish-shaped mold in a molten state to be cooled, or formed into a sheet shape and then cut into a strip shape after cooling to form a sheet shape having a size that can be accommodated in the recess 2. It is formed into a (flat rectangular parallelepiped). From the viewpoint of increasing the amount of heat storage, it is preferable to increase the volume as much as possible. However, when the flooring 1 is constructed with a hot melt adhesive, the heat storage material 3 also rises in temperature and expands. Therefore, from the viewpoint of preventing protrusion from the recess 2 due to expansion during construction, the heat storage material 3 is formed so that its volume with respect to the inner volume of the recess 2 is 80 to 95%.

  The heat storage sheet S is attached to the back surface of the flooring 1 with each bag 4 fitted in the recess 2. That is, the heat storage sheet S is fixed to the back surface of the flooring 1 by sticking the outer peripheral portion of each bag 4 of the heat storage sheet to the wood portion around the recess 2 with an adhesive such as urethane moisture-curing melt adhesive. Is done. Thereby, the heat storage material 3 can be integrated with the flooring 1.

  By the way, in the construction of the flooring 1, a construction method using an adhesive is generally employed. In such construction, after the flooring 1 is disposed by applying an adhesive to the base material, the flooring 1 is bonded to the base material by fixing the real part of the flooring 1 with nails.

  Therefore, in the present invention, when the flooring 1 is securely bonded to the base material when constructed using an adhesive as described above, the rear surface of the flooring 1 is devised by devising the form of the heat storage sheet S. The woody part of the tree is exposed moderately. That is, in this invention, the hole 5 which exposes the wood part between the adjacent recessed parts 2 and 2 with respect to the sheet-like connection part 4b between the bags 4 and 4 which adjoin the heat storage sheet S is provided.

  Specifically, as shown in FIG. 1, in the heat storage sheet S, sheet-like connecting portions 4 b are arranged corresponding to the wood portions between the adjacent recesses 2 and 2 on the back surface of the flooring 1. The connecting portion 4b is provided with a plurality of holes 5 by punching a sheet. The hole 5 of the connecting portion 4b is a hole for exposing the wood portion of the back surface of the flooring 1 and may be an elliptical or rectangular hole in addition to the long hole illustrated in the figure. The holes may be arranged in the form of holes.

  The total opening area of the holes 5 in the sheet-like connecting part 4b is 20 to 20% of the area of the sheet-like connecting part from the viewpoint of securing the strength of the heat storage sheet S and increasing the adhesive force to the base material. 80% is set. By providing the holes 5 in the heat storage sheet S as described above, the wood portion between the recesses 2 and 2 on the back surface of the flooring 1 can be sufficiently exposed, and the adhesive force to the base material can be enhanced.

  Moreover, as shown in FIG. 2, as the heat storage sheet S, a plurality of sheets may be used. The flooring 1 illustrated in FIG. 2 is configured by adhering three heat storage sheets S formed in a rectangular shape having a length slightly shorter than the length of the flooring and less than 1/3 of the width of the flooring. It has been done. Each elongated heat storage sheet S can be produced in the same manner as the heat storage sheet S shown in FIG. 1, and is similarly attached to the back surface of the flooring 1 with each bag 4 fitted in the recess 2. In the case of the flooring 1 shown in FIG. 2, the wood portion of the back surface of the flooring 1 can be exposed between the adjacent heat storage sheets S, S by arranging the heat storage sheets S on the back surface of the flooring with a gap. It is possible to increase the adhesive strength to the base material.

  In the flooring 1 of the present invention, an elongated shallow dish-shaped concave portion 2 is formed in a predetermined arrangement by cutting on the back surface, and a heat storage sheet S in which a gel-like heat storage material 3 is enclosed is separately produced. It can manufacture by sticking the thermal storage sheet S to the said flooring back surface so that the bag 4 may be stored in the recessed part 2. FIG. Then, in the construction of the floor using the flooring 1, the flooring 1 can be finished by adhering the flooring 1 to the base material with an adhesive as in the conventional flooring.

  As described above, the flooring 1 of the present invention uses the heat storage sheet S having a structure in which a plurality of bags 4 encapsulating the gel-like heat storage material 3 are connected, and the heat storage sheet S is attached to the back surface of the flooring. By doing so, since the flooring 1 and the heat storage material 3 have a simple structure, they can be manufactured at low cost. Moreover, the recessed part 2 of the flooring 1 back surface is formed in the shape of a shallow dish, and the said recessed part is arrange | positioned at a fixed pitch along the length direction of the flooring 1, Moreover, each recessed part 2 of the flooring 1 back surface WHEREIN The heat storage sheet S is configured so that the bag 4 is fitted, and the vertical load applied to the flooring 1 can be supported by the outer peripheral portion of each recess 2, so that sufficient strength as a flooring can be exhibited.

  Furthermore, as shown in FIG. 1, the flooring 1 of this invention is provided with the hole 5 which exposes the wood part of the back of the flooring 1 in the connection part 4b between the adjacent bags 4 and 4 of the heat storage sheet S. In addition, the adhesive strength to the base material can be increased. In addition, as shown in FIG. 2, by arranging a plurality of heat storage sheets S with a gap therebetween, the wood portion of the back surface of the flooring 1 can be exposed between the adjacent heat storage sheets S, S, and the base material Adhesive strength against can be increased.

1: Flooring 2: Recess 3: Heat storage material 4: Bag 4 b: Connection part 5: Hole S: Heat storage sheet

Claims (6)

  A flooring that is used as a flooring material and has a rectangular planar shape, and a plurality of shallow dish-shaped concave portions are provided at a constant pitch along the length of the flooring on the back surface of the flooring. And a heat storage sheet having a structure in which a plurality of bags encapsulating gel-like heat storage materials are connected to each other, and each bag of the heat storage sheet has a heat storage function characterized by being fitted in a recess. Having flooring.   The flooring according to claim 1, wherein the heat storage sheet is a single sheet, and a sheet-like connecting portion between adjacent bags of the heat storage sheet is provided with a hole for exposing a wood portion between adjacent recesses.   The flooring according to claim 2, wherein the total opening area of the holes in the sheet-like connecting portion is set to 20 to 80% of the area of the sheet-like connecting portion.   The flooring according to any one of claims 1 to 3, wherein the volume of the heat storage material with respect to the inner volume of the recess is 80 to 95%.   The flooring according to any one of claims 1 to 4, wherein the heat storage sheet is composed of a laminated sheet having at least one resin layer.   The flooring according to any one of claims 1 to 5, wherein the heat storage sheet is composed of a laminated sheet having at least one metal layer.

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