JP5300351B2 - Architectural vacuum insulation board - Google Patents

Description

  The present invention relates to a heat insulating board used for a wall, a ceiling, or the like of a building, and relates to an improvement of a vacuum insulating board for a building in which a vacuum heat insulating material is covered with a synthetic resin foam and integrated.

  Conventionally, for example, a vacuum insulation board that continuously covers a core material such as glass fiber or silica powder with a film excellent in gas barrier properties, and covers and integrates a vacuum insulation material in a vacuum state with a synthetic resin foam continuously. Patent Document 1 is known as a manufacturing technique. This is achieved by adhering and fixing the vacuum heat insulating material to the continuously supplied one face material, and foaming by applying the foamed resin material to the other face material continuously supplied toward this face material. The foamed foam is covered with a vacuum heat insulating material so that it is sandwiched between the face material on one side and the face material on the other side, pressed to a certain thickness, laminated and cured, and cut into a predetermined size. I am doing so.

In addition, when using the vacuum insulation board as described above as a structural element of a heat insulation structure of a building, as a technique for forming a notch in a part of the insulation board in order to make it easy to attach to a pillar or a purlin. Patent Document 2 is also known.
JP 2005-161794 A JP 2006-90070 A

  By the way, when such a vacuum heat insulation board is used as a building application, a portion of only the synthetic resin foam is provided around the vacuum heat insulating material, and a portion of only the synthetic resin foam without the vacuum heat insulating material is attached to the fastening bracket (screw). It was used as an area to be fixed with nails. This is because when the fastening metal fitting is fixed to the vacuum heat insulating material, the vacuum sealing is impaired and the heat insulating effect of the vacuum heat insulating material is lost.

  However, in the case of a conventional architectural vacuum heat insulation board, the shape of the vacuum heat insulating material is rectangular. For example, when fixing a vacuum heat insulation board to a pillar or a purlin, a vacuum is used to secure an area for fixing a fastener. The occupation area of the vacuum heat insulating material in the surface direction of the heat insulating board (the surface in the left-right direction in FIG. 2) becomes narrow, making it difficult to effectively utilize the excellent heat insulating property of the vacuum heat insulating material. That is, when the thermal conductivity of the synthetic resin foam and the vacuum heat insulating material is compared, the vacuum heat insulating material occupies the vacuum heat insulating board in the surface direction of the vacuum heat insulating board, although the heat insulating effect is 4 to 10 times greater. Due to the small area, it was difficult to effectively utilize the excellent heat insulating property of the vacuum heat insulating material.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to make it possible to improve heat insulation performance while ensuring a sufficient fixing area for a fastener in a building vacuum heat insulation board.

In order to achieve the above object, the present invention is an architectural vacuum heat insulating board in which a vacuum heat insulating material is covered and integrated with a synthetic resin foam, and the shape of the vacuum heat insulating material is a shape in which four rectangular corners are cut off , Even if the area of the vacuum heat insulating material in the surface direction of the vacuum heat insulating board is widened, the fixing region of the clasp metal fitting is widened by making the part where the vacuum heat insulating material does not exist in the excised part into the fixing metal fixing region. It was made possible to ensure the heat insulation performance. At this time, at least four or more vacuum heat insulating materials with the four corners of the rectangle cut off are arranged so that the fixing region of the fastening metal fitting in a portion surrounded by the four vacuum heat insulating materials has a substantially rhombus shape. and it may be.

  In the vacuum insulation board for building that integrates the vacuum insulation material with synthetic resin foam, the shape of the vacuum insulation material is a shape in which the four corners of the rectangle are cut off, thereby vacuum insulation in the surface direction of the vacuum insulation board. Even if the area occupied by the material was increased, the area for securing the fasteners could be secured, and the heat insulation performance could be improved.

Embodiments of the present invention will be described with reference to the accompanying drawings.
Here, FIG. 1 is a perspective view showing an example of a building vacuum heat insulating board according to the present invention, (a) is a surface on which a vacuum heat insulating material is disposed, (b) is an opposite surface, and FIG. FIG. 3 is an explanatory view of the vacuum insulation board for construction according to the present invention and the conventional vacuum insulation board for construction, (a) is the present invention, (b) is a conventional example, FIG. 4 is an explanatory view showing an example of an implementation in which a body edge is provided on the outdoor side of the building vacuum heat insulating board according to the present invention, and FIG. 5 is an explanatory view showing an example of a manufacturing method of the building vacuum heat insulating board according to the present invention. It is.

  The vacuum insulation board for building according to the present invention relates to a heat insulating material to be enforced on a wall or a ceiling of a building, while ensuring a sufficient area for fixing a fastener (including an intermediary pillar) and a purlin to a vacuum. The area occupied by the heat insulating material can be increased to enhance the heat insulating effect. In addition, for example, when fixing a trunk edge or rafter (hereinafter referred to as a trunk edge or the like) on the heat insulation board of the present invention fixed to the outside of a pillar or purlin, the trunk edge or the like is positioned at the position shown in FIG. Thus, when fixing the trunk edge or the like using the fastener, the vacuum sealing property of the vacuum heat insulating material is not impaired.

  An example of the method for producing the architectural vacuum heat insulation board of the present invention will be described with reference to FIG. First, the vacuum heat insulating material 3 is adhered to the upper surface material 2 drawn out almost horizontally from the upper surface material roll 11 at predetermined intervals, while the hard urethane is directed toward the lower surface material 4 drawn out from the upper lower surface material roll 12. When the synthetic resin foam 5 raw material such as foam raw material is applied from the application nozzle 13, the synthetic resin foam 5 raw material is gradually foamed by the curved heater 14 in the middle of the line. Then, the vacuum heat insulating material 3 and the foamed synthetic resin foam 5 are in a face-to-face state, and the upper surface material 2 and the lower surface material 4 make the vacuum heat insulating material 3 and the synthetic resin foam 5 in a sandwich state. It is fed into the conveyor 15 and is molded to a certain thickness by applying a predetermined pressure. Then, after passing through the double conveyor 15, a board obtained by heat curing in a curing oven is cut at a predetermined location to form a vacuum heat insulation board.

  The vacuum heat insulating material 3 used in the present invention, for example, covers the periphery of a core material such as an inorganic foamed powder, silica powder, or glass fiber with a gas barrier film, and evacuates the inside in which the core material is stored. It has a structure in which the core material portion is sealed by heat-sealing and exhibits a high heat insulating effect.

  At this time, the number and arrangement of the vacuum heat insulating materials 3 adhered to the upper surface material 2 fed out from the upper surface material roll 11 are arbitrary. For example, as shown in FIG. 1, a vacuum heat insulating material in which a plurality of vacuum heat insulating materials 3 are arranged. It may be in the form of a board 1.

By the way, as shown in FIG.3 (b), the conventional form of the vacuum heat insulation board shape | molded by the above methods was that the vacuum heat insulating material 3 was a rectangular shape.
In such a vacuum heat insulating board, when there is only one vacuum heat insulating material 3, the vacuum heat insulating material 3 is disposed near the center of the board, and in a plurality of cases, the vacuum heat insulating material is disposed at a predetermined interval. The peripheral part of the material 3 has a structure of only the foamed resin foam 5, and when fixing a board such as a pillar or a purlin with a fastener, for example, the vacuum heat insulating material 3 surrounded by a broken line part in FIG. Fixing is performed using only the foamed resin foam 5 that does not exist. This is because if a hole or the like is made in the vacuum heat insulating material 3, the vacuum sealing is impaired and the heat insulating performance is lowered.

  For this reason, in the conventional structure, when each side of the vacuum heat insulating material 3 is lengthened and the area is expanded, the area to be fixed with the fastening metal fittings is narrowed, and the vacuum sealing is likely to be damaged, that is, the enforcement tends to be difficult. Therefore, it has been difficult to secure a fixing region for the fastener.

  Therefore, in the present invention, as shown in FIG. 3A, the shape of the vacuum heat insulating material 3 is a form in which four rectangular corners are cut off. As a result, even if the length of each side of the vacuum heat insulating material 3 is increased to increase the area of the vacuum heat insulating material 3 in the surface direction of the heat insulating board, it is possible to ensure a wide fixing region for the fastening bracket, An increase in the area occupied by the heat insulating material 3 improves the heat insulating effect.

By the way, in the heat insulating board in which a plurality of vacuum heat insulating materials 3 are arranged, when the interval a between the vacuum heat insulating materials 3 in the direction orthogonal to the trunk edge 7 is narrowed as shown in FIG. In the case where the outer edge 7 is provided on the outer side for enforcement, a portion where the outer edge 7 and the vacuum heat insulating material 3 overlap is generated. (Hatched part)
At this time, when the vacuum heat insulating material 3 projects outside the thickness of only the foamed resin foam 5 as shown in FIG. The load applied to the inside increases when pushed.

Therefore, in the present invention, as shown in FIG. 4, the relationship between the distance a between the vacuum heat insulating materials 3 in the direction perpendicular to the trunk edge and the width b of the trunk edge 7 is expressed as 0 <ba−20 <20 mm. By doing so, an excessive load is prevented from being applied to the inside of the vacuum heat insulating material 3, and a decrease in the heat insulating effect is prevented.
That is, in the relationship between the space a between the vacuum heat insulating materials 3 and the width b of the trunk edge 7 and the like, when ba−a <0, the occupation area of the vacuum heat insulating material 3 decreases and the heat insulating effect decreases. If b−a> 20 mm, the overlapping portion between the vacuum heat insulating material 3 and the trunk edge 7 increases, and an excessive load is applied to the inside of the vacuum heat insulating material 3.

  At this time, as shown in FIG. 1B, a mark 6 on which a fastener can be driven may be written on the bottom surface material 4 side. By this notation, when the fastening metal fitting is driven from the lower surface material 4 side, the fastening region becomes clear and can be easily implemented. Further, when the fastening metal fitting is driven in from the upper surface material 2 side, the position of the vacuum heat insulating material 3 may be marked.

  Incidentally, the architectural vacuum heat insulation board 1 according to the present invention as described above can improve the heat insulation effect as the occupied area of the vacuum heat insulation material 3 increases, but the following table is shown in FIG. It is an example at the time of comparing with the vacuum heat insulation board 1 of this invention shown, and the conventional vacuum heat insulation board 1 shown in FIG.3 (b).

As a result, the area occupied by the vacuum heat insulating material 3 with respect to the conventional vacuum heat insulating board 1 was 50 to 55%, but increased to 65 to 80% in the present invention, and the average thermal conductivity was 0.0186 W / It was confirmed that it can be improved to 0.0168 W / mK as compared with mK.
In addition, this invention is not limited to the above embodiments. What has substantially the same configuration as the matters described in the claims of the present invention and exhibits the same operational effects belongs to the technical scope of the present invention.

  As a vacuum heat insulation board for buildings, the occupation area of the vacuum heat insulation material with respect to the vacuum heat insulation board can be increased, and since the construction is easy, it is useful as a heat insulation structure for buildings.

BRIEF DESCRIPTION OF THE DRAWINGS It is a perspective view which shows an example of the vacuum heat insulation board for buildings which concerns on this invention, (a) is the surface which arrange | positioned the vacuum heat insulating material, (b) is the surface on the opposite side Sectional drawing of the vacuum insulation board for buildings concerning the present invention It is explanatory drawing for comparing with the conventional vacuum insulation board for buildings, (a) is this invention, (b) is a prior art example. Explanatory drawing which shows an example of the enforcement which provides a trunk edge etc. on the outer side rather than the vacuum heat insulation board for buildings which concerns on this invention Explanatory drawing which shows an example of the manufacturing method of the vacuum heat insulation board for buildings which concerns on this invention

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Vacuum insulation board, 3 ... Vacuum insulation material, 5 ... Synthetic resin foam, 6 ... Mark, 7 ... Body edge, etc.

Claims (2)

A vacuum insulation boards for construction of integrating over the vacuum heat insulating material of a synthetic resin foam, the shape of the vacuum insulation material, der shape rectangular corners is cut is, the vacuum of the resected portion A vacuum insulation board for buildings , wherein a portion where no heat insulating material is present is a fixing region of the fastener . At least four or more vacuum heat insulating materials with the four corners of the rectangle cut away are arranged, and the fixing region of the fastening metal fitting in a place surrounded by the four vacuum heat insulating materials has a substantially rhombus shape. The architectural vacuum heat insulation board according to claim 1.

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