CN211143374U - Heat insulation wall structure and combined house - Google Patents

Abstract

The utility model provides a can improve the heat-proof quality and can improve the thermal-insulated wall structure and the modular house of construction ease nature. In the heat insulation wall structure, a plurality of heat insulation wall panels (20) containing vacuum heat insulation materials (29) are arranged along the width direction of the panels in a mode that each surface in the thickness direction forms an outer wall surface (30b) and an inner wall surface (30a), thereby constructing a wall (30) for dividing the interior and the exterior.

Description

Heat insulation wall structure and combined house

Technical Field

The utility model relates to a thermal-insulated wall construction and use this thermal-insulated wall construction's combination formula house.

Background

Conventionally, as a wall for partitioning the interior and exterior of a building, a wall formed of a plurality of layers such as an exterior wall material, a wall base material, a heat insulating material, and an interior decorative wall material is known.

For example, patent document 1 below discloses a structure of a wall portion of a building provided with a building member formed by filling and foaming a foam heat insulating material in a space between an exterior material and an interior material except for a vacuum heat insulating material disposed between surface materials.

Documents of the prior art

Patent document

Patent document 1: japanese laid-open patent publication No. 2008-95365

SUMMERY OF THE UTILITY MODEL

Problem to be solved by utility model

However, in the wall structure described in patent document 1, it is necessary to construct a plurality of plate-like members with a wall base material or the like, and further improvement is desired.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a heat insulation wall structure capable of improving heat insulation and improving ease of construction, and a built-up house using the heat insulation wall structure.

Means for solving the problems

In order to achieve the above object, the present invention provides a heat insulating wall structure, in which a plurality of heat insulating wall panels each including a vacuum heat insulating material are arranged in a panel width direction so that each surface in a thickness direction constitutes an outer wall surface and an inner wall surface, thereby constructing a wall that partitions the interior and the exterior of a room.

Preferably, the heat-insulating wall panel is provided at a 1 st end in the panel width direction with a joining projection projecting outward in the panel width direction and extending in the panel height direction, and at a 2 nd end in the panel width direction with a joining groove opening outward in the panel width direction and extending in the panel height direction and into which the joining projection of the adjacent heat-insulating wall panel is fitted.

Preferably, the heat insulating wall panel includes a rigid foamed resin base material provided with the vacuum heat insulating material and a facing material covering the rigid foamed resin base material, wherein a 1 st end in a panel width direction of the rigid foamed resin base material has a projection provided as an inner layer constituting the joining projection divided by the facing material, a 2 nd end in the panel width direction of the rigid foamed resin base material abuts on an inner side in the panel width direction of a groove bottom portion provided in the facing material so as to divide a groove bottom of the joining groove.

Preferably, the surface material includes a metal plate, and the surface material is formed by bending so as to define the engaging protrusion and the engaging groove.

Preferably, the surface materials include a 1 st surface material on one side in the panel thickness direction and a 2 nd surface material on the other side in the panel thickness direction, which are provided at a tip of the engagement protrusion and a groove bottom of the engagement groove with a gap therebetween in the panel thickness direction.

Preferably, the rigid foam resin-based base material of at least one of the plurality of heat insulating wall panels is provided with a storage recess that is open to one side in the panel thickness direction and that stores the vacuum heat insulating material, and a storage groove that is formed deeper than the storage recess and that is open to at least one side in the panel height direction, and in which the cylindrical member on which the cable is wired is stored.

Preferably, in the rigid foamed resin base material provided with the storage groove, a box storage recess in which a wiring box is stored is provided in communication with the storage groove at a position corresponding to an opening provided in the surface material.

In order to achieve the above object, a modular house according to the present invention is characterized in that at least one of the peripheral walls is constructed using the heat insulating wall structure of the present invention.

Preferably, the modular house comprises: an upper frame holding an upper end portion of the heat insulation wall panel; a lower frame holding a lower end portion of the heat insulation wall panel; and a vertical frame that is provided in a range between the upper frame and the lower frame at the end in the longitudinal direction and that holds the end in the wall width direction of the heat insulation wall panel disposed at the outermost side in the wall width direction.

Preferably, the modular house comprises: an insulated ceiling panel held by the upper frame arranged so as to surround the periphery thereof; and a floor side heat insulating material held by the lower frame disposed so as to surround the periphery thereof.

Effect of the utility model

The heat insulating wall structure of the present invention and a built-up house using the same can improve heat insulation and improve construction easiness by adopting the structure as described above.

Drawings

Fig. 1 is a schematic perspective view schematically showing an example of a heat insulation wall structure according to an embodiment of the present invention and a built-up house using the same

Fig. 2 is a schematic cross-sectional view of the above-described modular housing.

Fig. 3(a) to 3(d) each schematically show an example of a heat insulation wall panel provided in the above-described modular house, fig. 3(a) is a partially omitted schematic front view corresponding to the arrow direction of line X1-X1 in fig. 2, fig. 3(b) is a partially omitted schematic front view corresponding to the arrow direction of line X2-X2 in fig. 2, fig. 3(c) is a partially omitted schematic front view corresponding to the arrow direction of line Y1-Y1 in fig. 2, and fig. 3(d) is a partially omitted schematic front view corresponding to the arrow direction of line Y2-Y2 in fig. 2.

Fig. 4 is a schematic exploded perspective view schematically showing an example of a heat insulation wall panel provided in the modular house.

Fig. 5(a) is a partial cross-sectional schematic cross-sectional view schematically showing an example of a heat insulation wall panel provided in the modular house, fig. 5(b) is a partial cross-sectional schematic cross-sectional view corresponding to a portion Z1 in fig. 2, and fig. 5(c) is a partial cross-sectional schematic cross-sectional view corresponding to a portion Z2 in fig. 2.

FIG. 6 is a partially sectional schematic longitudinal cross-sectional view corresponding to the direction of arrows Y1-Y1 in FIG. 2.

Description of the reference numerals

1. A modular housing; 3. a floor side heat insulating material; 6. an insulated ceiling panel; 11. an upper frame; 13. a lower frame; 14. a vertical frame; 20. 1 st insulating wall panel (insulating wall panel); 20A, No. 2 insulating wall panels (insulating wall panels); 20B, No. 3 insulating wall panels (insulating wall panels); 20C, 4 th insulated wall panel (insulated wall panel); 20D, 5 th insulating wall panel (insulating wall panel); 20a, an engagement protrusion; 20b, an engagement groove; 21. 21A, a hard foamed resin base material; 22. a protrusion; 23. a groove-side end portion (panel width direction 2 nd end portion); 24. a receiving recess; 25. a receiving groove; 26. a box receiving recess; 27. a cylindrical member; 28. a wiring box; 29. vacuum insulation material; 30. 1 st wall (wall); 30A, 2 nd wall (wall); 30a, an inner wall surface; 30b, an outer wall surface; 31. 1 st surface material (surface material); 31h, opening; 32. 2 nd surface material (surface material); 31g, 32g, and a groove bottom piece.

Detailed Description

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

In some of the drawings, a part of the detailed reference numerals denoted in other drawings is omitted.

In the following embodiments, the directions such as the vertical direction will be described with reference to the state after the construction of the heat insulating wall structure and the built-up house of the present embodiment.

Fig. 1 to 6 are schematic views showing an example of the heat insulating wall structure of the present embodiment and an example of a built-up house using the heat insulating wall panel.

As shown in fig. 1 to 3(d), in the heat insulating wall structure of the present embodiment, a plurality of heat insulating wall panels 20 each containing a vacuum heat insulating material 29 are arranged in the panel width direction so that each surface in the thickness direction constitutes an outer wall surface 30b and an inner wall surface 30a, thereby constructing a wall 30 that partitions the interior and exterior of a room. With such a configuration, the wall (1 st wall) 30 constituting the outer wall surface 30b and the inner wall surface 30a can be constructed by the heat insulating wall panel (1 st heat insulating wall panel) 20, and it is not necessary to construct a plurality of plate-like members with various kinds of base materials or the like, and ease of construction can be improved. Further, since the vacuum heat insulating material 29 is enclosed in the plurality of 1 st heat insulating wall panels 20, the thickness can be reduced and the heat insulating property can be improved.

The heat insulating wall structure is used as a wall for dividing the interior and exterior of various buildings. In the present embodiment, the heat insulating wall structure is used as the 1 st wall 30 which is at least one of the walls 30, 30A, 30B, and 30C around the modular house 1. That is, in the modular house 1 of the present embodiment, the 1 st wall 30, which is at least one of the peripheral walls 30, 30A, 30B, and 30C, is constructed using the heat insulating wall structure of the present embodiment. With such a structure, the heat insulation and ease of construction of the 1 st wall 30 of the modular house 1 can be improved.

The built-up house 1 can be temporarily and easily installed as a temporary house at an office such as a construction site or a construction site, a temporary house in a disaster area, and a temporary shop, a temporary office, a movable facility, etc. additionally installed in various places. The modular house 1 may be a portable house or a self-care temporary storage. The installation form of the prefabricated house 1 is not limited to the form of being installed as a single body, and may be a form of being stacked vertically or being installed in a horizontal direction.

In the present embodiment, as shown in fig. 3(a) to 3(d), the modular house 1 includes a plurality of types of heat insulation wall panels 20, 20A to 20F. The modular house 1 includes a 1 st insulating wall panel 20 and a 2 nd insulating wall panel 20A, the 1 st insulating wall panel 20 contains a vacuum heat insulator 29, the 2 nd insulating wall panel 20A contains a vacuum heat insulator 29 and is provided with a single wiring box 28 at a lower end side thereof. The modular house 1 further includes a 3 rd heat-insulating wall panel 20B and a 4 th heat-insulating wall panel 20C, the 3 rd heat-insulating wall panel 20B contains a vacuum heat insulator 29 therein and is provided with a plurality of (two in the drawing) wiring boxes 28 on the lower end side thereof, and the 4 th heat-insulating wall panel 20C contains a vacuum heat insulator 29 therein and is provided with a single wiring box 28 on the upper end side thereof. The modular house 1 further includes a 5 th heat-insulating wall panel 20D, a 6 th heat-insulating wall panel 20E, and a 7 th heat-insulating wall panel 20F, wherein the 5 th heat-insulating wall panel 20D includes a vacuum heat-insulating material 29 and is provided with the opening 19, the 6 th heat-insulating wall panel 20E is not provided with the vacuum heat-insulating material 29, and the 7 th heat-insulating wall panel 20F is not provided with the vacuum heat-insulating material 29 and is provided with the inlet/outlet 9. In the following, a common structure of the respective thermal insulation wall panels 20, 20A to 20F will be described by taking the 1 st thermal insulation wall panel 20 as an example.

The 1 st heat insulating wall panel 20 has a substantially square flat plate shape. The 1 st heat insulating wall panel 20 is formed in an elongated shape in the vertical direction. The panel height dimension (length dimension) of the 1 st insulating wall panel 20 may be set to an appropriate dimension according to the ceiling height of the modular house 1 in which the 1 st insulating wall panel 20 is installed, and may be approximately 1800mm to 3000mm, for example. The panel width dimension of the 1 st heat-insulating wall panel 20 in the wall width direction may be set to an appropriate dimension from the viewpoint of ease of handling, ease of construction, and the like, and may be set to approximately 300mm to 1800mm, for example. The thickness of the 1 st insulating wall panel 20 may be set to an appropriate size, for example, approximately 50mm to 120mm, from the viewpoint of heat insulation, weight reduction, and cost reduction.

In the present embodiment, the 1 st heat-insulating wall panel 20 is configured to have a joining projection 20a at the 1 st end in the panel width direction, and the joining projection 20a projects outward in the panel width direction and extends in the panel height direction. The 1 st thermal insulation wall panel 20 has a structure in which a joining groove 20b is provided at the 2 nd end in the panel width direction, the joining groove 20b being open to the outside in the panel width direction and extending in the panel height direction, and a joining protrusion 20a of the adjacent 1 st thermal insulation wall panel 20 is fitted therein. In such a configuration, the 1 st insulating wall panel 20 and 20 adjacent to each other in the panel width direction can be joined to each other by fitting the joining projection 20a into the joining groove 20b, and the occurrence of displacement in the panel thickness direction and the occurrence of a gap can be suppressed as compared with a configuration in which end faces are joined to each other by butting.

As shown in fig. 5(a), the 1 st heat-insulating wall panel 20 includes a rigid foamed resin base material 21 and facing materials 31 and 32 covering the rigid foamed resin base material 21. With such a configuration, damage and the like of the rigid foamed resin base material 21 can be suppressed by the surface materials 31 and 32.

The hard foamed resin base material 21 is provided with a protrusion 22 at the 1 st end in the panel width direction, and the protrusion 22 is provided as an inner layer constituting a joining protrusion 20a defined by surface materials 31 and 32. The groove-side end 23, which is the 2 nd end in the panel width direction, of the rigid foamed resin base material 21 abuts against the inner side in the panel width direction of the groove bottom piece portions 31g, 32g provided in the surface materials 31, 32 so as to define the groove bottom of the joining groove 20 b. In the case of such a structure, as shown in fig. 5(b), a hard foamed resin base material 21 is present in the joining projection 20a joining the 1 st heat-insulating wall panels 20 to each other and on the inner side in the panel width direction of the groove bottom of the joining groove 20 b. This can improve the heat insulation property at the joint portion, for example, compared with a structure in which the joint portion for joining the heat insulating wall panels to each other is formed only of a metal material or a structure in which a large hollow portion is provided at the joint portion.

The surface materials 31 and 32 include metal plates. With such a configuration, damage and the like to the rigid foamed resin base material 21 can be more effectively suppressed. The surface materials 31 and 32 are bent so as to define the engaging protrusion 20a and the engaging groove 20 b. In such a configuration, since the engaging protrusion 20a and the engaging groove 20b are formed by the surface materials 31 and 32 including the metal plate which are formed by bending, the strength of the engaging portion can be improved.

In addition, the surface materials 31, 32 include a 1 st surface material 31 on one side in the panel thickness direction and a 2 nd surface material 32 on the other side in the panel thickness direction which are provided at the tip of the engagement protrusion 20a and the groove bottom of the engagement groove 20b with a gap therebetween in the panel thickness direction. In such a structure, compared to a structure in which the surface material is provided over the entire surface of the tip of the joining protrusion 20a and the entire surface of the groove bottom of the joining groove 20b, the surface materials 31 and 32 including the metal plate can be prevented from becoming a thermal bridge (heat bridge), and the heat insulation can be more effectively improved.

The hard foamed resin base material 21 is a foamed (foamed) heat insulating material mainly made of a synthetic resin such as a phenol resin, a polyurethane resin, a polystyrene resin, a polyethylene resin, a polypropylene resin, or an epoxy resin. The hard foamed resin base material 21 may occupy most of the 1 st heat insulation wall panel 20, and may have a thickness of approximately 80% to 99% of the thickness of the 1 st heat insulation wall panel 20, for example.

The protrusion 22 provided at the 1 st end in the panel width direction of the rigid foamed resin base material 21 is provided so as to protrude outward in the panel width direction and extend in the panel height direction. The protrusion 22 is provided on the entire surface of the rigid foamed resin base material 21 in the panel height direction. In the present embodiment, as shown in fig. 5(a), the projection 22 is provided at the center in the panel thickness direction so as to correspond to the engagement projection 20 a. Both side surfaces in the panel thickness direction of the projection 22 are formed as substantially flat surfaces having a shape substantially parallel to each surface in the thickness direction of the 1 st heat insulation wall panel 20. Further, a distal end surface 22a of the protrusion 22 facing the outer side in the panel width direction is a substantially flat surface having a shape substantially orthogonal to both side surfaces in the panel thickness direction.

The side end surface 23a of the recessed-groove-side end 23 of the rigid foamed resin base material 21 facing outward in the panel width direction is a substantially flat surface having a shape substantially orthogonal to each surface in the thickness direction of the 1 st heat-insulating wall panel 20.

The 1 st surface material 31 and the 2 nd surface material 32 are formed in a thin plate shape from various metallic materials such as a stainless steel plate and an aluminum alloy plate. The 1 st surface material 31 and the 2 nd surface material 32 may be surface-treated steel sheets obtained by subjecting a galvanized steel Sheet (SGCC) or the like to a surface treatment such as rust prevention. The thickness of the 1 st surface material 31 and the 2 nd surface material 32 may be set to an appropriate size from the viewpoint of strength, weight reduction, and the like, and may be set to approximately 0.2mm to 3mm, or 1mm or less, for example.

In the present embodiment, as shown in fig. 5(a), the 1 st surface material 31 disposed on one side in the panel thickness direction, i.e., the indoor side, and the 2 nd surface material 32 disposed on the other side in the panel thickness direction, i.e., the outdoor side, are configured substantially similarly to each other. Further, the interior decoration layer may be provided on the surface of the 1 st surface material 31 constituting the interior wall surface 30a by appropriate painting, adhesion of a surface decoration sheet, or the like. Further, an exterior decorative layer may be provided on the surface of the 2 nd surface material 32 constituting the exterior wall surface 30b by appropriate painting, adhesion of a surface decorative sheet, or the like.

The 1 st surface material 31 and the 2 nd surface material 32 include surface plate portions 31a and 32a constituting the respective surfaces of the 1 st heat insulation wall panel 20 in the thickness direction. The surface portions 31a and 32a are provided to match the respective surfaces of the rigid foamed resin base material 21 in the thickness direction.

In the present embodiment, as shown in fig. 4 and 6, an extension piece portion 32h is provided at the lower end portion of the surface plate portion 32a of the 2 nd surface material 32, and the extension piece portion 32h extends toward the lower side than the lower end surface of the rigid foamed resin base material 21. The extension piece 32h is provided substantially entirely in the panel width direction of the surface panel portion 32 a.

The 1 st surface material 31 and the 2 nd surface material 32 are provided with end face covering pieces 31b and 32b extending from the 1 st end in the panel width direction of the surface plate portions 31a and 32a toward the center side in the panel thickness direction. The end- face covering pieces 31b and 32b are provided so as to cover the end faces of the rigid foamed resin base material 21 that face the outer sides in the panel width direction on both sides in the panel thickness direction that are continuous with the base end side of the protrusion 22, and are in contact with or close to the respective end faces.

The 1 st surface material 31 and the 2 nd surface material 32 are provided with side surface covering pieces 31c and 32c extending from the center side ends in the panel thickness direction of the end surface covering pieces 31b and 32b toward the outer sides in the panel width direction. The side surface covering pieces 31c and 32c are provided to cover both side surfaces in the panel thickness direction of the protrusion 22 of the rigid foamed resin base material 21, abut against or come close to the respective side surfaces, and define both sides in the panel thickness direction of the joining protrusion 20 a.

The 1 st surface material 31 and the 2 nd surface material 32 are provided with tip end covering pieces 31d and 32d extending from outer ends in the panel width direction of the side covering pieces 31c and 32c toward the center side in the panel thickness direction. The distal end covering pieces 31d and 32d are provided to cover both sides in the panel thickness direction of the distal end surface 22a of the protrusion 22 of the rigid foamed resin base material 21, abut against or come close to the distal end surface 22a, and define the distal end side of the joining protrusion 20 a. The dimensions of the distal end covering pieces 31d, 32d in the panel thickness direction can be set to appropriate dimensions from the viewpoint of suppressing damage to the male corner portions on both sides of the protrusion 22 of the rigid foamed resin base material 21, from the viewpoint of achieving weight reduction, and from the viewpoint of suppressing the distal end covering pieces 31d, 32d from becoming thermal bridges. In the figure, an example is shown in which the dimension of the distal end covering piece portions 31d, 32d in the panel thickness direction is set to be smaller than the dimension of the distal end surface 22a of the protrusion 22 in the panel thickness direction, and may be set to approximately 2mm to 10mm, for example. Instead of this configuration, the dimensions of the distal end covering pieces 31d, 32d in the panel thickness direction may be set to dimensions such as to cover a large half of the distal end surface 22a of the protrusion 22. In the illustrated example, the recessed portion corresponding to the thickness of the distal end covering piece portions 31d and 32d is formed at the distal end portion of the engagement protrusion 20a, but the present invention is not limited to this configuration. For example, a step portion corresponding to the thickness of the distal end covering piece portions 31d and 32d may be provided on the distal end surface 22a of the protrusion 22 so that the distal end surface of the engagement protrusion 20a is formed in a substantially flat surface shape.

The surface plate portions 31a and 32a of the 1 st surface material 31 and the 2 nd surface material 32 are provided so that the 2 nd end in the panel width direction extends outward in the panel width direction from the side end surface 23a of the rigid foamed resin base material 21. The 1 st surface material 31 and the 2 nd surface material 32 are provided with end face piece portions 31e and 32e extending from the 2 nd end in the panel width direction of the surface plate portions 31a and 32a toward the center side in the panel thickness direction. The end surface pieces 31e and 32e constitute end surfaces of the 2 nd end in the panel width direction of the 1 st heat insulation wall panel 20, and abut against or come close to the end surface covering pieces 31b and 32b of the adjacent 1 st heat insulation wall panel 20 when the joining is completed (see fig. 5 (b)).

The 1 st surface material 31 and the 2 nd surface material 32 are provided with groove side wall sheet portions 31f and 32f extending from the center side ends in the panel thickness direction of the end sheet portions 31e and 32e toward the center side in the panel width direction (the side end surface 23a side). The groove side wall pieces 31f and 32f are used to define both sides of the joining groove 20b in the groove width direction, and abut against or come close to the side surface covering pieces 31c and 32c of the adjacent 1 st heat insulation wall panel 20 when the joining is completed (see fig. 5 (b)). The 1 st heat-insulating wall panel 20 is provided at the 2 nd end in the panel width direction with a hollow portion penetrating in the panel height direction and partitioned by the groove side wall sheet portions 31f, 32f, the end face sheet portions 31e, 32e, the extension portions of the surface plate portions 31a, 32a, and the side end surface 23a of the rigid foamed resin base material 21. The hollow portion may be used as a wiring space. In addition, instead of forming such a hollow portion, a configuration may be adopted in which a protruding portion is provided at both side edges in the panel thickness direction of the groove-side end portion 23 of the rigid foamed resin base material 21.

The 1 st surface material 31 and the 2 nd surface material 32 are provided with groove bottom piece portions 31g and 32g extending from the center side ends in the panel width direction of the groove side wall piece portions 31f and 32f toward the center side in the panel thickness direction. The groove bottom piece portions 31g and 32g are provided to match the side end surfaces 23a of the rigid foamed resin base material 21 and define the groove bottom of the joining groove 20 b. The dimensions of the groove bottom pieces 31g and 32g in the panel thickness direction can be set to appropriate dimensions from the viewpoint of strength of the groove side wall pieces 31f and 32f defining the joining groove 20b, the viewpoint of weight reduction, and the viewpoint of suppressing the groove bottom pieces 31g and 32g from becoming thermal bridges. In the figure, an example is shown in which the dimensions of the groove bottom piece portions 31g, 32g in the panel thickness direction are set to be relatively small, and may be set to be, for example, approximately 2mm to 10 mm. In place of this, the dimension of the groove bottom piece portions 31g and 32g in the panel thickness direction may be set to a dimension such that a majority of the groove bottom constituting the joining groove 20b is formed. In the illustrated example, the recessed portion corresponding to the thickness of the groove bottom piece portions 31g and 32g is formed in the groove bottom of the joining groove 20b, but the present invention is not limited to this configuration. For example, a protruding portion corresponding to the thickness of the groove bottom piece portions 31g and 32g may be provided on the side end surface 23a of the rigid foamed resin base material 21 so that the groove bottom of the joining groove 20b is formed in a substantially flat surface shape.

In the present embodiment, the outline shape of the engaging protrusion 20a is formed in a substantially square shape when viewed in the panel height direction, and the engaging recess 20b is formed in a substantially square groove shape when viewed in the groove longitudinal direction. For example, the contour shape of the joining protrusion 20a may be formed in a substantially trapezoidal shape, a substantially triangular shape, a substantially U-shape, a substantially semicircular shape, or the like when viewed in the panel height direction, and may be formed in other various shapes. In this case, the engaging recessed groove 20b may be appropriately deformed according to the contour shape of the engaging protrusion 20 a.

Further, it is also possible to provide appropriate sealing members for sealing the joint portions between the 1 st insulating wall panels 20 adjacent to each other at both or one of the end portions of the 1 st insulating wall panel 20 in the panel width direction.

The 1 st surface material 31 and the 2 nd surface material 32 may be fixed to the rigid foamed resin base material 21 by a fixing member such as a screw, an appropriate adhesive, an adhesive material, or the like. In this case, for example, the end face covering pieces 31b and 32b, the end face pieces 31e and 32e, and the like may be provided with insertion holes for fasteners. Alternatively, the foamed resin material injected between the 1 st surface material 31 and the 2 nd surface material 32 is foamed and cured to form the hard foamed resin base material 21.

In the present embodiment, the example is shown in which the gaps are provided between the tip end covering piece portions 31d and 32d and between the bottom end covering piece portions 31g and 32g of the 1 st surface material 31 and the 2 nd surface material 32, respectively, but the gaps may be configured not to be provided. In this case, for example, both or one of the tip covering piece portions 31d, 32d and the bottom piece portions 31g, 32g may be formed integrally. That is, the 1 st surface material 31 and the 2 nd surface material 32 may be continuous.

Next, the different structures of the respective thermal insulation wall panels 20, 20A to 20F will be described.

As shown in fig. 5(a) to 5(c), the vacuum heat insulating material 29 is provided in the hard foamed resin base materials 21 and 21A of the 1 st to 5 th heat insulating wall panels 20 to 20D in which the vacuum heat insulating material 29 is wrapped, such that the vacuum heat insulating material 29 is located on the indoor side of the central portion in the thickness direction. With such a configuration, damage to the vacuum heat insulating material 29 and the like when an unexpected impact or the like is applied from the outdoor side can be suppressed. In the present embodiment, as shown in fig. 4 and 5(a) to 5(c), the rigid foamed resin base materials 21 and 21A are provided with the housing recess 24, and the housing recess 24 is open toward one side in the panel thickness direction that becomes the indoor side and houses the vacuum heat insulating material 29. The vacuum heat insulating material 29 can be fixed to the bottom surface of the storage recess 24 facing the panel thickness direction side by an appropriate adhesive, bonding material, or the like. The vacuum heat insulating material 29 is disposed such that one side surface thereof in the thickness direction on the indoor side is in contact with or close to the reverse surface of the 1 st facing material 31.

The vacuum heat insulating material 29 has a substantially square flat plate shape whose thickness direction coincides with the panel thickness direction. The vacuum heat insulating material 29 can be formed by externally wrapping a core material with a gas-barrier packaging material and evacuating the core material. The core material may be formed of a foam such as an open-cell polyurethane foam, a styrene foam, or a phenol foam using a material having a relatively low thermal conductivity. Alternatively, the core material may be formed of a material obtained by pulverizing various foams, and powder particles such as silica, alumina, and pearlite, or may be formed of fibers such as glass fibers, glass wool, rock wool, and cellulose fibers. Further, the various foams, powder and granular materials, and fibrous materials described above may be mixed and used as the core material. The packaging material may be a metal film having gas barrier properties. Alternatively, a laminated film (sheet) having a protective layer such as a resin film on the outer layer side, a gas barrier layer such as a metal film or a metal vapor deposition layer in the middle, and a heat-fusible layer such as a resin film having heat-fusible properties on the inner layer side (core material side) may be used as the packaging material.

The thickness of the vacuum heat insulating material 29 may be set to an appropriate size from the viewpoint of desired heat insulating performance, cost, and the like, and in the illustrated example, the thickness of the vacuum heat insulating material 29 is set to a size smaller than the thickness of the hard foamed resin base materials 21 and 21A, and may be set to approximately 5mm to 20mm, for example. In addition, the dimension of the vacuum heat insulating material 29 in the panel height direction and the dimension in the panel width direction can be set to appropriate dimensions from the viewpoint of desired heat insulating performance, cost, and the like. The vacuum heat insulating material 29 can be stored by setting the depth dimension in the panel thickness direction, the dimension in the panel height direction, and the dimension in the panel width direction of the storage recess 24 to appropriate dimensions.

In the illustrated example, a plurality of vacuum heat insulating materials 29 are provided on each of the heat insulating wall panels 20, 20A to 20D. In the illustrated example, 4 vacuum insulation materials 29 are provided in each of the 1 st, 2 nd, 3 rd and 4 th thermal insulation wall panels 20A, 20B and 20C, and two vacuum insulation materials 29 are provided in the 5 th thermal insulation wall panel 20D, but the present invention is not limited to this embodiment.

The heat insulating wall panels 20, 20A to 20D may be configured such that the vacuum heat insulating material 29 is provided so that the area occupied by the vacuum heat insulating material 29 when viewed in the panel thickness direction is 1/2 or more.

The 1 st heat insulating wall panel 20 is configured such that the vacuum heat insulating material 29 is provided so that the area occupied by the vacuum heat insulating material 29 when viewed in the panel thickness direction is approximately 80%.

The 2 nd, 3 rd, and 4 th thermal wall panels 20A, 20B, and 20C provided with the wiring box 28 on the lower end side or the upper end side are configured such that the vacuum heat insulating material 29 is provided so that the area occupied by the vacuum heat insulating material 29 when viewed in the panel thickness direction is approximately 70%.

The 5 th heat-insulating wall panel 20D provided with the opening 19 is configured such that the vacuum heat-insulating material 29 is provided so that the area occupied by the vacuum heat-insulating material 29 with respect to the area other than the opening area of the opening 19 as viewed in the panel thickness direction is approximately 50%.

Instead of being disposed so that the vacuum heat insulating material 29 is exposed to one side of the rigid foamed resin base materials 21, 21A in the thickness direction of the indoor side, the vacuum heat insulating material 29 may be disposed so as to be embedded in the layers of the rigid foamed resin base materials 21, 21A.

As shown in fig. 4, a storage groove 25 is provided in the rigid foamed resin base material 21A of the 2 nd heat insulation wall panel 20A, the storage groove 25 is formed deeper than the storage recess 24, and a cylindrical member 27 in which a cable is wired is stored in the storage groove 25. The receiving groove 25 is provided so as to be open at least on one side in the panel height direction. With such a configuration, since the cables can be routed to the cylindrical member 27 through the opening on one side in the panel height direction, large-scale processing is not required at the construction site, and the routing workability can be improved. Further, since the housing groove 25 is formed deeper than the housing recess 24 in which the vacuum heat insulating material 29 is housed, it is possible to suppress the cylindrical member 27 housed in the housing groove 25 and the vacuum heat insulating material 29 from interfering with each other.

Further, in the rigid foamed resin base material 21A of the 2 nd heat-insulating wall panel 20A, a box storage recess 26 in which the wiring box 28 is stored is provided in communication with the storage groove 25 at a position corresponding to the opening 31h provided in the facing material (1 st facing material) 31. With such a configuration, a switch (operation panel), a receptacle (plug-in connector), and the like connected to a cable routed through the cylindrical member 27 can be installed in the wiring box 28.

The storage groove 25 is provided to open toward one side in the panel thickness direction which becomes the indoor side and to extend in the panel height direction, and its 1 st end (upper end) in the groove longitudinal direction is open at the upper end face of the rigid foamed resin base material 21A. The housing groove 25 is provided such that at least a part thereof in the groove long side direction is opened at the concave bottom surface of the housing recess 24. In the present embodiment, the storage groove 25 is provided to penetrate the storage recess 24 longitudinally in the panel height direction. In the illustrated example, the storage groove 25 is provided so as to penetrate one side of the two storage recesses 24 provided with a space in the panel width direction. In addition, an example is shown in which the storage groove 25 is provided so as to penetrate both of the two storage recesses 24 provided vertically at a spacing on one side in the panel width direction. In addition, an example is shown in which the housing groove 25 is provided at a position shifted to one side in the panel width direction (the side of the protrusion 22 in the drawing) from the center portion in the panel width direction of the hard foamed resin base material 21A.

The depth dimension of the storage groove 25 in the panel thickness direction may be set to an appropriate dimension so that the cylindrical member 27 does not protrude from the concave bottom surface of the storage recess 24 at the location of the storage recess 24. The width of the storage groove 25 is set to a dimension corresponding to the outer diameter of the cylindrical member 27.

The storage groove 25 is provided such that the 2 nd end (lower end) in the groove longitudinal direction is positioned at a portion on the lower end side of the hard foamed resin base material 21A where the storage recess 24 is not provided.

The cylindrical member 27 is formed in a hollow cylindrical shape penetrating in the longitudinal direction. The cylindrical member 27 may be cylindrical, polygonal, or corrugated flexible pipe (bellows). The upper end of the cylindrical member 27 is positioned at the upper end of the rigid foamed resin base material 21A, and the lower end of the cylindrical member 27 is connected to the wiring box 28 housed in the box housing recess 26.

The box accommodating recess 26 is open toward one side in the panel thickness direction, which is the indoor side, at a portion of the lower end side of the rigid foamed resin base material 21A where the accommodating recess 24 is not provided. The depth dimension in the panel thickness direction, the dimension in the panel height direction, and the dimension in the panel width direction of the box accommodating recess 26 are set to appropriate dimensions so that the wiring box 28 can be accommodated therein.

The wiring box 28 has a substantially square box shape that opens toward one side in the thickness direction of the panel that is the indoor side, and a through hole that communicates with the cylindrical member 27 is provided in the upper side wall portion thereof.

The opening 31h provided in the 1 st surface material 31 of the 2 nd heat insulation wall panel 20A is provided so as to penetrate through the lower end side portion of the surface plate portion 31a of the 1 st surface material 31 so as to be positioned in accordance with the wiring box 28 when viewed in the panel thickness direction. In addition, although fig. 3(a) and 3(b) show an example in which the wiring box 28 is provided so as to be positioned at a substantially central portion in the panel width direction, the wiring box 28 may be provided at a position shifted to one side in the panel width direction.

As shown in fig. 3(a) and 3(B), two wiring boxes 28 and 28 are provided at the lower end side of the 3 rd heat-insulating wall panel 20B at a distance in the panel width direction from the center in the panel width direction. Although not shown, the box-accommodating recess 26 for accommodating the wiring boxes 28, 28 is provided in the rigid foamed resin base material 21 of the 3 rd thermal insulation wall panel 20B substantially similarly to the 2 nd thermal insulation wall panel 20A. In addition, the 3 rd heat insulation wall panel 20B has two storage grooves 25 in the rigid foamed resin base material 21, and the storage grooves 25 communicate with the box storage recess 26 and respectively store the cylindrical members 27. In the illustrated example, two wiring boxes 28, 28 are provided at substantially equal intervals in the panel width direction from the center portion in the panel width direction, but the present invention is not limited to such an embodiment.

A wiring box 28 is provided at a substantially central portion in the panel width direction of the upper end side portion of the 4 th heat-insulating wall panel 20C. Although not shown, a box storage recess 26 for storing the wiring box 28 is provided in the rigid foamed resin base material 21 of the 4 th heat-insulating wall panel 20C. In addition, a storage groove 25 is provided in the rigid foamed resin base material 21 of the 4 th heat-insulating wall panel 20C, and the storage groove 25 communicates with the box storage recess 26 and stores a cylindrical member 27. The storage groove 25 may be provided to extend in the panel height direction at a portion of the upper end side portion of the rigid foamed resin base material 21 where the storage recess 24 is not provided, and may be open at the upper end surface of the rigid foamed resin base material 21. In this case, the depth of the storage groove 25 may be set to an appropriate depth so that the cylindrical member 27 does not protrude from the surface of the rigid foamed resin base material 21 facing the indoor side.

The opening 19 of the 5 th thermal insulation wall panel 20D is provided so as to penetrate the 5 th thermal insulation wall panel 20D in the thickness direction and is provided at a position halfway in the panel height direction. In the figure, an example is shown in which the opening 19 is provided in the 5 th heat-insulating wall panel 20D so that the window member provided in the opening 19 is a waist window.

The opening 19 is provided substantially entirely in the panel width direction. That is, the 5 th heat-insulating wall panel 20D is divided into an upper end portion 20c and a lower end portion 20D by the opening 19. An appropriate window member can also be established in this opening 19.

In the illustrated example, two vacuum heat insulating materials 29 are provided in the lower end side portion 20D of the 5 th heat insulating wall panel 20D, and the vacuum heat insulating material 29 is not provided in the upper end side portion 20 c.

The panel width dimension of the 6 th thermal insulation wall panel 20E is set smaller than the panel width dimensions of the thermal insulation wall panels 20, 20A to 20D described above. In the drawings, the panel width dimensions of the respective thermal insulation wall panels 20 and 20A to 20D are set to be substantially the same as each other, and the panel width dimension of the 6 th thermal insulation wall panel 20E is set to be about 1/2 of the panel width dimensions of the thermal insulation wall panels 20 and 20A to 20D. Further, the 6 th heat-insulating wall panel 20E may also be configured to include a vacuum heat-insulating material 29.

The 7 th heat-insulating wall panel 20F is provided with a door 8 for opening and closing the entrance 9. The door body 8 may be a vertical hinged door in which the end of the door is held so as to be rotatable about an axis in the door height direction, or may be a folding door, a sliding door, or the like. The door 8 may be formed on a door frame of the 7 th heat-insulating wall panel 20F, which defines the entrance 9. The panel width dimension of the 7 th thermal insulation wall panel 20F is set to be substantially the same as the panel width dimension of each of the thermal insulation wall panels 20, 20A to 20D except for the 6 th thermal insulation wall panel 20E described above. The panel width dimensions of the respective thermal insulation wall panels 20, 20A to 20F may be substantially the same as each other, or may be different from each other, including the 6 th thermal insulation wall panel 20E. The thickness dimensions of the respective thermal insulation wall panels 20, 20A to 20F are set to be substantially the same as each other, and the panel height dimensions of the respective thermal insulation wall panels 20, 20A to 20F are set to be substantially the same as each other.

Further, the 7 th heat-insulating wall panel 20F and the door 8 may also be configured to include a vacuum heat insulator 29.

Further, a wiring box 28, a box storage recess 26 for storing the wiring box 28, a cylindrical member 27, a storage groove 25, and the like may be provided at appropriate positions of the 5 th, 6 th, and 7 th heat-insulating wall panels 20D, 20E, and 20F.

Further, a through hole to which a ventilation fan or the like is attached, a through hole through which a cable connected to the ventilation fan is inserted, or the like may be provided at an appropriate position on any one of the heat-insulating wall panels 20 and 20A to 20F. Further, a through hole or the like through which a pipe connected to an air conditioner or a water intake and drainage device is inserted may be provided at an appropriate position of any one of the heat insulating wall panels 20 and 20A to 20F. The structure of each of the heat insulating wall panels 20 and 20A to 20F is not limited to the above-described structure, and various other modifications are possible.

As shown in fig. 2, the modular house 1 is formed in a substantially rectangular shape elongated in one direction in a plan view. The modular house 1 may be configured to be provided with the heat insulating wall panels 20 and 20A to 20F such that the area occupied by the vacuum heat insulating material 29 as viewed in the panel thickness direction is 1/2 or more with respect to the total wall area obtained by summing the areas of the peripheral walls 30 and 30A to 30C as viewed in the wall thickness directions.

In the drawing, an example is shown in which a 1 st wall 30 and a 2 nd wall 30A which are arranged to face each other and form a long side are constructed by 5 heat insulating wall panels 20, 20A to 20C each of which is wrapped with a vacuum heat insulating material 29. That is, in the present embodiment, the 1 st wall 30 and the 2 nd wall 30A on the long side of the built-up house 1, which are long in one direction, are constructed by arranging the plurality of heat insulating wall panels 20, 20A to 20C enclosing the vacuum heat insulating material 29 in the panel width direction.

In addition, an example is shown in which a 3 rd wall 30B and a 4 th wall 30C which are arranged to face each other and form short sides are constructed by using 3 heat-insulating wall panels 20, 20D to 20F.

As shown in fig. 2 and 3(a), the 1 st wall 30 is constructed by using two pieces of the 1 st insulating wall panel 20, 1 piece of the 2 nd insulating wall panel 20A, 1 piece of the 3 rd insulating wall panel 20B, and 1 piece of the 4 th insulating wall panel 20C.

As shown in fig. 2 and 3(B), the 2 nd wall 30A is constructed by using 31 st insulating wall panels 20, 12 nd insulating wall panel 20A, and 13 rd insulating wall panel 20B.

As shown in fig. 2 and 3(c), the 3 rd wall 30B is constructed by 1 st insulating wall panel 20, 15 th insulating wall panel 20D, and 16 th insulating wall panel 20E.

As shown in fig. 2 and 3(D), the 4 th wall 30C is constructed by 15 th thermal insulation wall panel 20D, 16 th thermal insulation wall panel 20E, and 17 th thermal insulation wall panel 20F.

The number of heat insulation wall panels 20, 20A to 20F constituting the walls 30, 30A to 30C of the modular house 1, the arrangement positions, and the combination form are not limited to the forms shown in the drawings, and various modifications are possible.

As shown in fig. 1 and 6, the modular house 1 includes an upper frame 11 for holding upper ends of the heat insulation wall panels 20 and 20A to 20F, and a lower frame 13 for holding lower ends of the heat insulation wall panels 20 and 20A to 20F. With such a configuration, the upper and lower ends of the heat insulation wall panels 20, 20A to 20F can be held by the upper frame 11 and the lower frame 13. This can improve ease of construction as compared with a structure requiring a wall base material such as a purlin disposed in the middle.

As shown in fig. 1 and 5(c), the modular house 1 includes a vertical frame 14 provided in a range between the longitudinal ends of the upper frame 11 and the lower frame 13. The vertical frame 14 is configured to hold side end portions in the wall width direction of the heat insulation wall panels 20, 20C, 20E, and 20F disposed on the outermost sides in the wall width direction. With such a configuration, the side end portions in the wall width direction of the heat insulating wall panels 20, 20C, 20E, and 20F disposed on the outermost sides in the wall width direction can be held by the vertical frames 14. The holding form of the heat insulating wall panels 20, 20A to 20F by the upper frame 11, the lower frame 13, and the vertical frame 14 is the same, and therefore the 1 st heat insulating wall panel 20 will be described below as an example.

The modular house 1 includes an insulating ceiling panel 6 and a floor-side heat insulating material 3, the insulating ceiling panel 6 being held by an upper frame 11 disposed so as to surround the periphery thereof, and the floor-side heat insulating material 3 being held by a lower frame 13 disposed so as to surround the periphery thereof (see fig. 6). With such a structure, the heat insulation properties of the walls 30, 30A to 30C around the prefabricated house 1 can be improved, and the heat insulation properties of the ceiling side and the floor side can be improved. In addition, the heat-insulating ceiling panel 6 and the floor side heat-insulating material 3 can be held by the upper frame 11 and the lower frame 13.

The upper frame 11 is formed in an elongated shape in the wall width direction, and has a substantially same cross-sectional shape over the entire length thereof. As shown in fig. 6, the upper frame 11 includes a surface plate portion 11a, and the surface plate portion 11a is a thin plate extending in the wall width direction and is disposed so that the thickness direction thereof coincides with the wall thickness direction. The upper frame 11 includes an abutting portion 11b, and the abutting portion 11b is provided to rise upward from an end of a sheet portion extending from a lower end of the surface plate portion 11a toward the indoor side, and abuts against an upper end of the 1 st heat insulating wall panel 20. The 2 nd facing material 32 of the 1 st heat insulation wall panel 20 located on the outdoor side abuts against the abutting portion 11 b. Further, an appropriate sealing member may be interposed between the 1 st heat-insulating wall panel 20 and the contact portion 11 b.

In addition, the upper frame 11 is provided with a holding piece portion 11c for holding the cylindrical member 12 extending in the wall width direction. The holding piece portion 11c is provided to extend from the upper end portion of the contact portion 11b toward the indoor side. The upper frame 11 further includes a rising piece portion 11d, and the rising piece portion 11d is provided to rise from an indoor side end portion of the holding piece portion 11 c. A concave groove opened upward is defined by the rising piece portion 11d, the holding piece portion 11c, and the surface plate portion 11a, and the tubular member 12 is disposed in the concave groove. Various cables may be wired in the cylindrical member 12. Further, the cylindrical member 12 may not be provided, or the cylindrical member 12 may be provided integrally with the upper frame 11.

The upper frame 11 includes a panel holding piece 11e, and the panel holding piece 11e extends toward the indoor side from the upper end of the rising piece 11d and holds the heat insulating ceiling panel 6. In the illustrated example, the standing piece portion 11d and the panel holding piece portion 11e are provided separately from the holding piece portion 11c, but the above-described members may be provided integrally.

The heat-insulating ceiling panel 6 is held by the upper frame 11 so that the end portion on the outer peripheral side thereof is placed on the panel holding piece portion 11 e. The heat-insulating ceiling panel 6 may be fixed to the panel holding piece portion 11e by a fixing member such as a screw, an appropriate adhesive, an adhesive material, or the like.

The heat insulating ceiling panel 6 is made of a foamed (foamed) heat insulating material similar to the above-described rigid foamed resin base material 21. The heat insulating ceiling panel 6 may be configured not to enclose the vacuum heat insulating material 29 as described above. The heat-insulating ceiling panel 6 may be configured without the surface material including the metal plate as described above. The interior decorative layer may be provided on the lower surface of the heat-insulating ceiling panel 6 facing the indoor side by appropriate coating, adhesion of a surface decorative sheet, or the like. In the drawings, the example in which the thickness of the heat insulating ceiling panel 6 is smaller than the thickness of the 1 st heat insulating wall panel 20 is shown, but the present invention is not limited to this form.

In the present embodiment, as shown in fig. 6, a ceiling side heat insulator 7 is further provided on the upper side of the heat-insulating ceiling panel 6. With such a structure, the heat insulation of the ceiling side can be improved. The ceiling side heat insulating material 7 may be a fibrous heat insulating material containing mineral fibers such as glass wool and rock wool. In the drawings, the example in which the thickness dimension of the ceiling-side heat insulating material 7 is made larger than the thickness dimensions of the heat insulating ceiling panel 6 and the 1 st heat insulating wall panel 20 is shown, but the present invention is not limited to this form.

The ceiling-side heat insulating material 7 may be placed on and held by the heat insulating ceiling panel 6, or may be fixed and held by an appropriate fixing member or the like to the distal end portion 11f of an extension portion provided to extend from the upper end portion of the surface plate portion 11a of the upper frame 11 toward the indoor side. Further, an appropriate roofing material may be provided so as to cover the upper side of the ceiling-side heat insulating material 7. Alternatively, the roofing material may be fixed to the upper frame 11.

In the present embodiment, the edge banding 18 disposed at the inside corner portions of the 1 st heat-insulating wall panel 20 and the heat-insulating ceiling panel 6 is provided.

The edge banding 18 includes a pressing piece 18a, and the pressing piece 18a is disposed so that the thickness direction thereof coincides with the wall thickness direction and is in contact with the 1 st surface material 31 of the 1 st heat insulation wall panel 20 located on the indoor side. The edge strip 18 includes a ceiling side piece 18b, the ceiling side piece 18b is provided to extend from an upper end of the pressing piece 18a toward the indoor side, and the ceiling side piece 18b is in contact with the lower surface of the insulated ceiling panel 6. When the edge banding 18 is provided, the gap formed between the 1 st heat-insulating wall panel 20 and the inside corner of the heat-insulating ceiling panel 6 can be covered. The edge banding 18 may be secured to at least one of the insulated ceiling panel 6, the first insulated wall panel 20, and the upper frame 11 using suitable fasteners, adhesives, bonding materials, and the like. The edge strips 18 are provided along the indoor sides of the peripheral walls 30, 30A to 30C of the modular house 1. The edge strip 18 is provided so that each end in the longitudinal direction thereof does not interfere with a corner member 17 described later.

The edge banding 18 may also function as a holding portion that holds the upper end portion of the 1 st heat-insulating wall panel 20 together with the upper frame 11.

As a form of holding the upper end portion of the 1 st thermal insulation wall panel 20, a form may be adopted in which a receiving groove that opens downward is provided in the upper frame 11 to receive and hold the upper end portion of the 1 st thermal insulation wall panel 20. The upper end portion of the 1 st thermal-insulation wall panel 20 may be fixed to the upper frame 11 by a fixing member, an adhesive, a bonding material, a magnet, or the like to hold the upper end portion, and various other modifications may be made to the form of holding the upper end portion of the 1 st thermal-insulation wall panel 20.

In the present embodiment, 4 upper frames 11 are provided along the upper ends of the walls 30, 30A to 30C on the four sides of the prefabricated house 1. Further, upper end connecting members 15 are provided at four corners, and the upper end connecting members 15 connect the respective ends in the longitudinal direction of the upper frames 11, 11 arranged orthogonally to each other and adjacent to each other, to the upper end of the vertical frame 14. The respective end portions of the upper frames 11, 11 and the upper end portion of the vertical frame 14 may be fixed to the upper end connecting member 15 by appropriate fixing members. Further, when the fixing member is removed, the upper frames 11 and 11, the vertical frame 14, and the upper end connecting member 15 may be easily disassembled. In fig. 6, the upper end connecting member 15 and a lower end connecting member 16 described later are not shown. The upper frame 11, the lower frame 13, the vertical frame 14, the upper end connecting member 15, and the lower end connecting member 16 constitute a cubic frame unit 10.

The lower frame 13 is formed in an elongated shape in the wall width direction, and has a substantially same cross-sectional shape over the entire length thereof. As shown in fig. 6, the lower frame 13 includes a surface plate portion 13a, and the surface plate portion 13a is a thin plate extending in the wall width direction and is disposed so that the thickness direction thereof coincides with the wall thickness direction. In the assembled state of the modular house 1, the surface plate portion 13a is disposed at a position substantially corresponding to the surface plate portion 11a of the upper frame 11 in the wall thickness direction.

The lower frame 13 includes a base portion 13b extending from a lower end of the surface plate portion 13a toward the indoor side. The base portion 13b is brought into contact with an appropriate installation object 2 to install the modular house 1.

The lower frame 13 further includes a holding piece portion 13c extending toward the indoor side from an upper end portion of a piece portion provided upright from an indoor side end portion of the base portion 13b toward the upper side, for holding the floor side heat insulating material 3.

The floor side heat insulating material 3 is held by the lower frame 13 so that the end portion on the outer peripheral side thereof is placed on the holding piece portion 13 c. The floor side heat insulating material 3 may be fixed to the holding piece portion 13c by a fixing member such as a screw, an appropriate adhesive, an adhesive, or the like.

The floor side heat insulating material 3 is a foamed (foamed) heat insulating material similar to the above-described hard foamed resin base material 21. The floor side heat insulating material 3 may be configured not to include the vacuum heat insulating material 29 as described above. The floor side heat insulating material 3 may not have the surface material including the metal plate as described above. In the drawings, the thickness of the floor side heat insulating material 3 is set to be substantially the same as the thickness of the 1 st heat insulating wall panel 20, but the present invention is not limited to this configuration.

The lower frame 13 includes a panel holding piece 13d extending from the upper end of the surface plate 13a toward the indoor side. A projection 13e is provided at a middle portion in the wall thickness direction of the panel holding piece 13d, and the projection 13e projects upward and abuts against the lower end surface of the 1 st heat insulation wall panel 20. The projection 13e is provided to extend over the entire length of the lower frame 13. When the projection 13e is provided, rainwater and the like can be prevented from entering the indoor side. In the figure, an example is shown in which the protrusion 13e is formed in a substantially square shape having a flat upper surface when viewed in the longitudinal direction of the lower frame 13. The protrusion 13e has a protrusion dimension in the vertical direction substantially equal to the dimension of the extension piece 32h of the 1 st heat insulation wall panel 20 disposed on the outdoor side of the protrusion 13e in the vertical direction. When the extension piece portion 32h is provided, entry of rainwater and the like into the indoor side can be more effectively suppressed. Further, an appropriate sealing member may be interposed between the 1 st heat insulation wall panel 20 and the lower frame 13. The lower end portion of the 1 st heat-insulating wall panel 20 may be placed on and held by the lower frame 13, or may be fixed by a fixing member such as a screw, an appropriate adhesive, an adhesive material, or the like.

Further, a floor holding piece portion 13f is provided on the indoor side of the projection portion 13e of the panel holding piece portion 13d, and the floor holding piece portion 13f extends from a base end portion (lower end portion) of the projection portion 13e toward the indoor side and holds the floor base material 4.

The floor base material 4 is held by the lower frame 13 so that the end portion on the outer peripheral side thereof is placed on the floor holding piece portion 13 f. The floor base 4 may be fixed to the floor holding piece portion 13f by a fixing member such as a screw, an appropriate adhesive, an adhesive material, or the like.

The floor base 4 may be, for example, a floor base such as a wood laminated board such as plywood, L V L (veneer laminated board), or a wood board such as particle board, and in the illustrated example, the floor base 4 is laminated with the floor covering 5. the floor covering 5 may be a so-called wood flooring formed of a wood material and formed into a panel shape, or may be any material such as a so-called cushioned floor, floor tile, or carpet, and the floor covering 5 may be constructed at a construction site independently of the floor base 4, or may be laminated in advance on the floor base 4 and integrated.

In the figure, an example of an arrangement is shown in which the outer peripheral side end portions of the floor base material 4 and the floor covering material 5 are inserted between the floor holding piece portion 13f and the lower end surface of the 1 st heat insulating wall panel 20. The form of holding the lower end portion of the 1 st heat-insulating wall panel 20 and the outer peripheral side end portions of the floor base material 4 and the floor covering material 5 is not limited to the above form, and various other modifications are possible.

In the present embodiment, 4 lower frames 13 are provided along the lower end portions of the walls 30, 30A to 30C on the four sides of the prefabricated house 1. Further, lower end connecting members 16 are provided at four corners, and the lower end connecting members 16 connect respective ends in the longitudinal direction of the lower frames 13, 13 arranged orthogonally to each other and adjacent to each other, to the lower end of the vertical frame 14. The respective end portions of the lower frames 13, 13 and the lower end portion of the vertical frame 14 may be fixed to the lower end connecting member 16 by appropriate fasteners in the same manner as described above. Further, the lower frames 13, the vertical frame 14, and the lower end connecting member 16 may be configured to be easily disassembled when the fixing member is removed.

Further, a structure may be adopted in which appropriate reinforcing frames are provided at intervals in the longitudinal direction of the modular housing 1 on the lower side of the floor base 4, and the reinforcing frames are arranged so as to be bridged between the lower frames 13, 13 facing each other in the short-side direction of the modular housing 1. In this case, the floor side heat insulating material 3 may be provided between the reinforcing frames and the lower frames 13 facing in the longitudinal direction of the building block 1.

As shown in fig. 2, the vertical frames 14 are provided at four corners of the modular house 1.

The mullion 14 is formed in a vertically elongated shape and has a substantially uniform cross-sectional shape over the entire length thereof. As shown in fig. 5(c), the vertical frame 14 includes surface plate portions 14a, and the surface plate portions 14a, 14a are orthogonal to each other so as to form corner portions on the outer frame side of the prefabricated house 1. The surface plates 14a and 14a are thin plate-like extending in the vertical direction and extending in the longitudinal direction and the lateral direction of the modular house 1. In the assembled state of the modular house 1, the front panels 14a and 14a are arranged substantially flush with the front panels 11a and 13a of the upper frame 11 and the lower frame 13, which are arranged in parallel, respectively.

The vertical frame 14 includes abutting portions 14b, a piece portion extending from the opposite end portions of the corners of the surface panel portions 14a, 14a toward the indoor side, and the abutting portions 14b, 14b extending so as to be folded back toward the corner side from the end portions of the piece portion on the indoor side. The side end portions of the 1 st heat-insulating wall panels 20, 20 constituting the corner portions on the corner side in the panel width direction are brought into contact with the contact portions 14b, 14 b.

In the present embodiment, the corner member 17 is provided at the inside corner portion of the 1 st heat-insulating wall panel 20 and 20 constituting the corner portion, the inside corner portion being located at the inside of the house.

The corner member 17 includes pressing pieces 17a, and the pressing pieces 17a, 17a are orthogonal to each other so as to form an indoor inside corner of the built-up house 1, and abut against the 1 st surface materials 31, 31 located on the indoor side of the 1 st heat insulation wall panels 20, 20. When the corner member 17 is provided, a gap formed at a female corner portion between the 1 st heat-insulating wall panels 20 and 20 constituting the corner portion can be covered. The corner member 17 can be secured to at least one of the 1 st insulating wall panel 20 and the vertical frame 14 using suitable fasteners, adhesives, bonding materials, and the like. The corner members 17 are provided at four indoor corners of the built-up house 1.

The corner member 17 may also function as a holding portion that holds the side end portions of the 1 st insulating wall panels 20, 20 together with the vertical frame 14.

Further, as a form of holding the side end portions of the 1 st thermal insulation wall panels 20, 20 constituting the corner portions, a form may be adopted in which a receiving groove that is opened in the wall width direction for receiving and holding the side end portions of the 1 st thermal insulation wall panels 20, 20 is provided in the mullion 14. The respective side end portions of the 1 st insulating wall panels 20 and 20 may be fixed to the upright frame 14 by a fixing member, an adhesive, a bonding material, a magnet, or the like to hold the respective side end portions, and various other modifications may be made to the form of holding the respective side end portions. The edge banding 18 and the corner member 17 may be formed of an appropriate metal material or a synthetic resin material.

In addition, the frame unit 10 including the upper frame 11, the lower frame 13, the vertical frame 14, the upper end connecting member 15, and the lower end connecting member 16 described above may be formed using an appropriate metal-based material.

For example, the modular house 1 having the above-described structure can be constructed as follows.

First, the four lower frames 13 are connected by the lower end connecting members 16, and the lower end portions of the four corner stile frames 14 are connected to the lower end connecting members 16. The frame unit 10 is assembled by connecting the four upper frames 11 to upper end connecting members 15 connected to the upper end portions of the rectangular vertical frames 14. The frame unit 10 is not limited to being assembled at the installation position of the modular house 1, and may be assembled in advance at an appropriate position and carried into the installation position.

Further, the floor side heat insulating material 3, the floor base material 4, and the floor covering material 5 may be applied, the heat insulating wall panels 20 and 20A to 20F may be applied, and the heat insulating ceiling panel 6, the ceiling side heat insulating material 7, the roofing material, and the like may be applied. Further, the corner member 17, the edge strip 18, and the like may be applied. The above-described steps are merely exemplary, and various modifications can be made thereto. The modular house 1 may be configured to be disassembled (disassembled) and reassembled.

In the present embodiment, the wiring box 28 and the tubular member 27 are embedded in at least one of the plurality of heat insulation wall panels 20, 20A to 20F constituting the modular house 1, but the present invention is not limited to such an embodiment. For example, the wiring box 28 and the cylindrical member 27 may not be provided in an embedded state. In this case, the housing groove 25 of the cylindrical member 27 and the case housing recess 26 of the wiring case 28 may not be provided in the rigid foamed resin base material 21A.

In the present embodiment, the example in which the engaging protrusion 20A and the engaging recess 20b that engage with the adjacent heat-insulating wall panels 20, 20A to 20F are provided in the heat-insulating wall panels 20, 20A to 20F is shown, but the present invention is not limited to such an embodiment. For example, the side end surfaces of the respective heat insulation wall panels 20, 20A to 20F adjacent to each other in the panel width direction, which are formed in a flat surface shape, may be butted and joined to each other, or the above members may be joined by various joining members.

In the present embodiment, the heat-insulating ceiling panel 6 and the floor-side heat insulating material 3 are provided in the modular house 1, but one or both of them may not be provided.

In the present embodiment, the upper frame 11, the lower frame 13, and the vertical frame 14 are provided in the modular house 1, but at least one of them or none of them may be provided. In this case, a structure may be adopted in which an appropriate foundation material or the like for holding the respective end portions of the heat insulating wall panels 20, 20A to 20F is provided.

In the present embodiment, an example is shown in which at least one of the walls 30 and 30A to 30C around the built-up house 1 (the 1 st wall 30 and the 2 nd wall 30A in the present embodiment) is constructed using a heat insulating wall structure, but the present invention is not limited to such an embodiment. The heat insulation wall structure of the present embodiment is not limited to the modular house 1, and can be used as a wall of various buildings. The structure of each member used in the heat insulating wall structure of the present embodiment is not limited to the above-described configuration, and various other modifications are possible.

Claims (10)

1. A heat-insulating wall structure is characterized in that,

a plurality of heat-insulating wall panels containing vacuum heat-insulating materials are arranged along the width direction of the panels in such a manner that the surfaces in the thickness direction form an outer wall surface and an inner wall surface, thereby constructing a wall for dividing the interior and the exterior of a room.

2. An insulated wall construction according to claim 1,

the heat-insulating wall panel is provided with a joining protrusion protruding outward in the panel width direction and extending in the panel height direction at the 1 st end in the panel width direction, and a joining groove opening outward in the panel width direction and extending in the panel height direction and into which the joining protrusion of the adjacent heat-insulating wall panel is fitted at the 2 nd end in the panel width direction.

3. An insulated wall construction according to claim 2,

the heat-insulating wall panel comprises a rigid foamed resin base material provided with the vacuum heat-insulating material and a surface material covering the rigid foamed resin base material,

the first 1 end in the panel width direction of the hard foamed resin base material has a protrusion provided as an inner layer constituting the joining protrusion defined by the surface material, the second 2 end in the panel width direction of the hard foamed resin base material abuts against the inner side in the panel width direction of a groove bottom portion provided in the surface material so as to define a groove bottom of the joining groove.

4. An insulated wall construction according to claim 3,

the surface material includes a metal plate, and is formed by bending so as to define the engaging protrusion and the engaging groove.

5. An insulated wall construction according to claim 4,

the surface materials include a 1 st surface material on one side in the panel thickness direction and a 2 nd surface material on the other side in the panel thickness direction, which are provided at a tip of the engagement protrusion and a groove bottom of the engagement groove with a gap therebetween in the panel thickness direction.

6. An insulated wall construction according to any of claims 3-5,

the rigid foam resin base material of at least one of the plurality of heat insulation wall panels is provided with a storage recess that is open to one side in the panel thickness direction and that stores the vacuum heat insulation material, and a storage groove that is formed deeper than the storage recess and that is open at least at one side in the panel height direction, and in which a cylindrical member on which a cable is wired is stored.

7. An insulated wall construction according to claim 6,

in the hard foamed resin base material provided with the storage groove, a box storage recess in which a wiring box is stored is provided in communication with the storage groove at a position corresponding to an opening provided in the surface material.

8. A combined house is characterized in that,

use of the insulated wall structure of any of claims 1 to 7 to construct at least one of the surrounding walls.

9. The modular building of claim 8,

the modular housing includes: an upper frame holding an upper end portion of the heat insulation wall panel; a lower frame holding a lower end portion of the heat insulation wall panel; and a vertical frame that is provided in a range between the upper frame and the lower frame at the end in the longitudinal direction and that holds the end in the wall width direction of the heat insulation wall panel disposed at the outermost side in the wall width direction.

10. The modular building of claim 9,

the modular housing includes: an insulated ceiling panel held by the upper frame arranged so as to surround the periphery thereof; and a floor side heat insulating material held by the lower frame disposed so as to surround the periphery thereof.

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