JP3238213U - Wall structure of an external heat-insulated building with a four-circle plate around the inner window frame - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wall structure for preventing generation of gaps, peeling of interior materials, cracks and the like which may occur around an inner window frame of an external heat insulating building. SOLUTION: The wall structure includes a concrete outer wall 10 having a window portion, an inner window frame 32a arranged in the window portion, urethane foam 36 arranged between the concrete outer wall and the inner window frame, and urethane foam. A wooden frame 33 arranged between the inner window frame and the inner window frame is provided. On the indoor side of the concrete outer wall, a notch portion 10a is formed around the window portion. A recess is formed around the inner window frame. This recess is formed around the inner window frame by arranging the inner surface of the notch and the end surface of the wooden frame on the indoor side to be flush with each other. Plate-shaped members (four peripheral plates 61a, 61c) are attached to the recesses. [Selection diagram] Fig. 2

Description

The present invention relates to an external heat insulating building, and more specifically, to a wall structure of a reinforced concrete external heat insulating building in which a plate-shaped member (four-circumferential plate) is attached to the entire circumference of the inner window frame.

In a reinforced concrete external heat insulating building, the outside of the concrete skeleton is covered with a heat insulating layer, so cracks caused by heat stress caused by the sun's sunlight can be suppressed, and the concrete skeleton does not come into contact with air, so concrete is neutralized. It is possible to prevent the corrosion of reinforced concrete, improve the durability of the building, and maintain the temperature environment inside the building, causing dew condensation inside the building. It is evaluated as an energy-saving high-performance building because it can suppress the growth of mold and ticks and is excellent in terms of health.

Patent Document 1 discloses a wall structure including an inner window and its periphery in such an externally insulated building. FIG. 5A shows a vertical cross section of the window lower frame in the wall structure disclosed in Patent Document 1. The wall structure of Patent Document 1 is formed of an outer window frame 31a, a heat insulating composite panel 2, and a concrete outer wall 10 in order to prevent the outside temperature from being transmitted to the room through the metal outer window frame 31a. The intervals are filled with urethane foam 36. Further, in this wall structure, the mortar 35 is filled between the wooden frame 33 attached to the angle piece 31c of the outer window frame 31a and the concrete outer wall 10.

In this wall structure, the concrete outer wall 10 and the indoor surface of the mortar 35 are adjusted for non-landing with, for example, a resin mortar 62, and the interior material 63 is applied. However, gaps and peeling of the interior material 63 may occur at the joint between the wooden frame 33 and the interior material 63, and cracks may occur at the joint between the concrete outer wall 10 and the mortar 35. There is a cost issue.

As shown in FIG. 5B, the applicant of the present application fills the space formed between the outer window frame 31a and the concrete outer wall 10 with the mortar 35 for the purpose of holding the outer window frame 31a in the event of a fire. We also propose a wall structure. In this wall structure, the urethane foam 36 is filled in the space formed by the wooden frame 33 and the concrete outer wall 10, that is, the urethane foam and the mortar are arranged in the opposite direction to FIG. 5A. Such a wall structure is disclosed in Patent Document 2. The heat insulating composite panel 2 shown in FIG. 5B is provided with a plate-shaped body 52 having air holes 52b on its lower end surface. The applicant has proposed such a structure in Japanese Patent Application No. 2022-025250.

In such an arrangement, even if the mortar 35 is refilled between the concrete outer wall 10 and the wooden frame 33 (indoor side), cracks occur in the joint portion. Therefore, in order to solve this problem, crack prevention measures may be taken by arranging a frame or the like on the wooden frame 33, but in such a structure, the frame protrudes from the interior finished surface to the indoor side. There are problems such as aesthetic problems because the windows look angular and rugged, and cost issues.

Japanese Patent No. 3770494 Japanese Unexamined Patent Publication No. 2020-6633

In view of the above problems, it is an object of the present invention to provide a wall structure that prevents the generation of gaps, peeling of interior materials, cracks, etc. that may occur around the inner window frame of an externally insulated building.

The present invention provides a wall structure for an externally insulated building. The wall structure includes a concrete outer wall having a window portion, an inner window frame arranged in the window portion, urethane foam arranged between the concrete outer wall and the inner window frame, and urethane foam and the inner window frame. It has a wooden frame placed between them. On the indoor side of the concrete outer wall, a notch is formed around the window. A recess is formed around the inner window frame. This recess is formed around the inner window frame by arranging the inner surface of the notch and the end surface of the wooden frame on the indoor side to be flush with each other. A plate-shaped member (four-circumferential plate) is attached to the recess.

The indoor side surface of the concrete outer wall and the indoor side surface of the plate-shaped member are arranged on the same surface, and the wall structure further includes a base material over these surfaces and further includes an interior material on the base material.

FIG. 3 shows a view of a window portion in which a four-circumferential plate is arranged according to an embodiment of the present invention as viewed from the indoor side. It is a vertical cross-sectional view of the wall structure including the window part in which the four peripheral plates are arranged according to one Embodiment of this invention. It is a cross-sectional view of a part of the wall structure including the window part in which the four peripheral plates are arranged according to one Embodiment of this invention. It is a vertical cross-sectional view of a part of a wall structure including a window part in which a four-circle board is arranged according to one Embodiment of this invention, and shows the process at the time of constructing a four-circle board. It is a vertical sectional view which shows a part of the wall structure of the window part by the prior art.

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

FIG. 1 shows a view of the window portion 3 in which the four peripheral plates 61a, 61b and 61c are arranged according to the embodiment of the present invention as viewed from the indoor side. FIG. 2 is a vertical cross-sectional view of the wall structure G including the window portion 3 in which the four peripheral plates 61a, 61b and 61c are arranged. In FIG. 2, the upper side and the lower side of the window portion 3 are shown by omitting the intermediate portion. FIG. 3 is a cross-sectional view of a part of the wall structure G including the window portion 3 in which the four peripheral plates 61a, 61b and 61c are arranged. In the following, the left-right direction of the paper surface of FIG. 1 is referred to as a width direction, the vertical direction of the paper surface of FIG. 1 is referred to as a height direction, and the direction orthogonal to the width direction and the height direction is referred to as a thickness direction. Further, when viewed in the thickness direction of the wall structure G, the direction in which the four peripheral plates are provided is referred to as the indoor side, and the opposite direction is referred to as the outdoor side.

The structure G includes a concrete outer wall 10 and a heat insulating composite panel 2 arranged on the outdoor side of the concrete outer wall 10. The heat insulating composite panel 2 has a heat insulating layer 23, an exterior base material 21 in contact with the outdoor side of the heat insulating layer 23, and an exterior material 51 in contact with the outdoor side of the exterior base material 21. The heat insulating composite panel 2 is arranged so that the concrete outer wall 10 and the heat insulating layer 23 are in contact with each other. The heat insulating composite panel 2 (more specifically, the exterior base material 21 and the heat insulating layer 23) is attached to the concrete outer wall 10 by, for example, a fall prevention anchor (not shown).

In the wall structure G, for example, a heat insulating composite panel 2 having substantially the same structure as that disclosed in Patent Document 2 can be used. The heat insulating composite panel 2 has a structure in which the exterior base material 21 is in contact with the outdoor side of the heat insulating layer 23 and the exterior material 51 is in contact with the outdoor side of the exterior base material 21. The heat insulating layer 23 is not limited, but may be formed by, for example, arranging a required number of heat insulating materials having a thickness of 75 mm, a width of 500 mm, and a height of 2700 mm in the height direction and the width direction. can. The material of the heat insulating material is not limited, but a foamed plastic heat insulating material (JIS A9511) is typically used.

The exterior base material 21 has a plurality of grooves 22 extending in the height direction, and a thick portion (not shown) is arranged between the grooves 22 in the thickness direction of the grooves 22. A thin wall portion (not shown) is arranged adjacent to it. That is, the exterior base material 21 has a structure in which thick portions, grooves, and thin portions are alternately arranged in the width direction. The plurality of groove 22 constitutes the partition ventilation layer 7. A thick portion is in contact with the heat insulating layer 23. The exterior base material 21 has, but is not limited to, a size of, for example, 26 mm in thickness, 490 mm in width, and 2700 mm in height, for example, one extrusion having a plurality of grooves 22 having a depth of 13 mm and an opening width of 30 mm. It is formed by arranging the required number of molded cement plates in the height direction and the width direction. The exterior material 51 is not limited, but typically, exterior tiles, stone materials, paint finishes, and the like are used.

Next, the wall structure G around the window portion 3 will be described. The window portion 3 has an outer window 31 and an inner window 32. The outer window 31 is provided in the window portion 3 penetrating the concrete outer wall 10, the heat insulating layer 23, the exterior base material 21 and the exterior material 51 of the wall structure G, and the outer window frame 31a provided facing the window portion 3 is provided. Have. The inner window frame 32a is provided on the indoor side of the outer window frame 31a. A plastic face plate 32b is arranged on the concrete outer wall 10 side of the inner window frame 32a, and a wooden frame 33 is further arranged on the concrete outer wall 10 side of the face plate 32b. An angle piece 31c is attached to the indoor side of the outer window frame 31a, and the wooden frame 33 is screwed to the angle piece 31c.

The space between the outer window frame 31a and the wooden frame 33 and the concrete outer wall 10 is filled with the mortar 35 and the urethane foam 36 in this order from the outdoor side. In this structure, since the mortar 35 which is hard to burn is arranged on the outdoor side and the urethane foam 36 which is easy to burn is arranged on the indoor side, the possibility that the fire spreads to the heat insulating layer 23 in the event of a fire outdoors or indoors is reduced. be able to. The outer window frame 31a is connected to the concrete outer wall 10 via the support bar steel 34, but since the support bar steel 34 is embedded in the mortar 35, corrosion of the support bar steel 34 is prevented and the durability of the window is improved. Can be made to.

On the upper side of the window portion 3 (that is, the portion on the lower end side of the wall structure G facing the window portion 3), the heat insulating composite panel 2 is arranged on the outdoor side of the concrete outer wall 10 and the mortar 35 (FIG. 2). .. Further, also on the side portion side of the window portion 3, the heat insulating composite panel 2 is similarly arranged on the outdoor side of the concrete outer wall 10 and the mortar 35 (FIG. 3). Plate-shaped hugging materials 52 and 52a are arranged on the end faces of the exterior base material 21 of the heat insulating composite panel 2 and the heat insulating layer 23 on the window portion 3 side without contacting the outer window frame 31a.

The holding material 52 arranged on the end surface of the lower end of the heat insulating composite panel 2 has a size corresponding to the width of the window portion 3 and the thickness of the exterior base material 21 and the heat insulating layer 23, and has a groove 22 of the exterior base material 21. A plurality of air holes 52b communicating with the air holes 52b are provided. The external air enters the plurality of grooves 22 through the plurality of air holes 52b and rises as an air flow 70. The shape of the air holes 52b is not limited, but is preferably rectangular or elliptical rather than circular, which may be closed by the viscosity of air. As the holding material 52, the same material as the exterior material 51, for example, a normal siding plate, a cement molded plate, a tile, a metal plate, or the like can be used as needed. The hugging material 52 can be bonded to, for example, the end faces of the lower ends of the heat insulating layer 23 and the exterior base material 21 with an adhesive.

In FIG. 2, the hugging material 52 corresponds to the thickness of the exterior base material 21 and the heat insulating layer 23, but the lower end surface of the exterior material 51 and the lower end surface of the heat insulating layer 23 and the exterior base material 21 are flush with each other. The hugging material 52 may also cover the lower end surface of the exterior material 51.

A sealing material 41a is arranged between the outer window frame 31a and the holding material 52, and a backer 41b is arranged between the sealing material 41a and the mortar 35. As described above, in the wall structure G, the holding member 52 having the plurality of air holes 52b and the outer window frame 31a are arranged apart from each other with the sealing material 41a and the backer 41b interposed therebetween. Rainwater that has entered the groove 22) and descends inside the groove 22 is unlikely to be drawn into the room from the window frame even if the sealing material 41a has a problem. Further, in the wall structure G, unlike the structure shown in FIG. 6 of Patent Document 2, since there is no parting frame at the lower end of the heat insulating composite panel 2, there is no difference between the lower end of the compartment ventilation layer 7 and the outdoor air pressure. Therefore, the phenomenon that rainwater invades from the outer window frame 31a together with the air flow does not occur.

A drainage frame 31b is provided at the upper end of the heat insulating composite panel 2 on the lower side of the window portion 3. The drainage frame 31b has a plurality of air holes 311a communicating with the outside and a plurality of air holes 311b communicating with the plurality of grooves 22 on the lower surface thereof. The air flow 70 that has risen inside the plurality of grooves 22 is discharged to the outside through the plurality of air holes 311b and the plurality of air holes 311a. A sealing material 41a and a backer 41b are also arranged between the drainage frame 31b and the outer window frame 31a.

As shown in FIG. 3, the hugging material 52a is also arranged on the end surface of the side end of the heat insulating composite panel 2. The hugging material 52a has a size corresponding to the height of the window portion 3 and the thickness of the exterior base material 21 and the heat insulating layer 23. As the holding material 52a, the same material as the exterior material 51, for example, a normal siding plate, a cement molded plate, a tile, a metal plate, or the like can be used as needed. The hugging material 52a can be bonded to, for example, the end faces of the heat insulating layer 23 and the exterior base material 21 with an adhesive.

In FIG. 3, the hugging material 52a corresponds to the thickness of the exterior base material 21 and the heat insulating layer 23, but faces the end surface of the side end of the exterior material 51 and the end surface of the heat insulating layer 23 and the exterior base material 21. At the same time, the hugging material 52 may also cover the side end surface of the exterior material 51. A sealing material 41a and a backer 41b are arranged between the outer window frame 31a, the holding material 52a, and the exterior material 511s.

The inner window 32 has an inner window frame 32a provided on the indoor side of the outer window frame 31a. A plastic face plate 32b, a wooden frame 33, and a urethane foam 36 are arranged in this order between the inner window frame 32a and the concrete outer wall 10. The face plate 32b, the wooden frame 33, and the urethane foam 36 are arranged in a state where the end faces on the indoor side thereof form the same surface. These end faces are arranged at positions deeper on the outdoor side than the indoor side surface of the inner window frame 32a.

On the indoor side of the concrete outer wall 10, a notch portion 10a is formed around the window portion 3. The notch portion 10a is formed at the time of skeleton formation as described later. The inner surface of the notch portion 10a is also located on the same surface as the end surface of the face plate 32b, the wooden frame 33, and the urethane foam 36 on the indoor side. That is, a recess 10a formed in the concrete outer wall 10 and a recess formed by the face plate 32b, the wooden frame 33, and the end faces of the urethane foam 36 are formed around the inner window frame 32a.

Plate-shaped members 61a, 61b and 61c are arranged in the recess formed in this way, and these plate-shaped members are referred to as a four-circle plate. Structural plywood is used as the four peripheral plates 61a, 61b and 61c. As the structural plywood, for example, a cement-based molded plate, a volcanic vitreous multi-layer plate, a plastic plate, or the like can be appropriately used depending on the purpose. The four peripheral plates 1a, 61b and 61c are fixed to the notched portion 10a of the concrete outer wall 10 and the end face of the wooden frame 33 by a fixing tool 61d such as a nail and an adhesive.

The widths of the four peripheral plates (upper plate) 61a arranged on the upper side of the window portion 3 and the four peripheral plates (side plates) 61b arranged on both sides of the window portion 3 are not limited, but may be 100 mm, for example. The width of the four-circumferential plate (lower plate) 61c arranged on the lower side of the window portion 3 is not limited, but can be, for example, 160 mm. The widths of the four peripheral plates 61a, 61b and 61c are such that the four peripheral plates 61a, 61b and 61c are attached to the concrete outer wall with the four peripheral plates attached over the concrete outer wall 10 and the wooden frame 33 arranged with the urethane foam 36 in between. It may be wide enough to be securely fixed to the 10 and the wooden frame 33, and preferably the widths of the four peripheral plates 61a, 61b and 61c are the four peripheral plates 61a, 61b and 61c and the concrete outer wall 10 and the wooden frame 33. The size of the contact portion is set to be 50% or more of the width of the four peripheral plates 61a, 61b and 61c. For example, in the case of the four-round plate 61c as an example, since the thickness of the wooden frame 33 is typically 25 mm and the thickness of the non-fixed urethane foam 36 is typically 75 mm, the four-round plate 61c and the concrete outer wall are described. The height of the notch 10a is 60 mm and the four-circle plate 61c so that the dimension of the contact portion between the 10 and the wooden frame 33 (that is, the total length in the height direction) is 50% or more of the width of the four-circumference plate 61c. The width of is set to 160 mm. The thicknesses of the four peripheral plates 61a, 61b, and 61c are not limited, but can be, for example, 12 mm. The thicknesses of the four peripheral plates 61a, 61b and 61c may be sufficient to exhibit the connection rigidity between the concrete outer wall 10 and the wooden frame 33. The lengths of the four peripheral plates 61a, 61b, and 61c are appropriately set according to the size of the window portion 3.

The indoor surface of the concrete outer wall 10 (excluding the notch 10a) and the indoor surface of the four peripheral plates 61a, 61b and 61c are located on the same surface. A resin mortar 62 having an indoor surface of the concrete outer wall 10 preferably subjected to non-landing adjustment, easily following drying, shrinkage and cracking over the surfaces of the four peripheral plates 61a, 61b and 61c, and having excellent adhesive strength and bending strength. , Is applied thinly as a base material. On the resin mortar 62, an interior material 63 such as cloth pasting, plaster wall, painting, etc. is further applied.

By arranging the four peripheral plates 61a, 61b and 61c of the plate-like body around the inner window frame 32a of the window portion 3 in this way, gaps are generated, the interior material is peeled off, and cracks are generated around the window portion 3. There is no problem such as. This is because the vibrations of the four peripheral plates 61a, 61b and 61c firmly attached to the concrete outer wall 10 and the wooden frame 33 are small, and the contact surface between the concrete outer wall 10 and the four peripheral plates 61a, 61b and 61c having a relatively high moisture content. In the first place, since the four peripheral plates 61a, 61b and 61c are adopted for the external heat insulating building, there is no dew condensation on the concrete outer wall 10, the four peripheral plates 61a, 61b and 61c do not absorb moisture, and the hygroscopicity is high. Factors such as the urethane foam 36 absorbing the moisture of the four peripheral plates 61a, 61b and 61c are achieved by having a combined effect.

Further, the four peripheral plates 61a, 61b and 61c also function as a blindfold material for the urethane foam 36 filled between the wooden frame 33 and the concrete outer wall 10. Further, the four peripheral plates 61a arranged on the upper side of the window portion 3 serve as a mounting base for the curtain rod, and the four peripheral plates 61b arranged on both sides of the window portion 3 serve as a mounting base for the tuft of the curtain. Further, when the four-circumferential plate 61c is arranged under the sliding window for the balcony, it also functions as a baseboard for mounting the skirting board and a collision cushioning material for the vacuum cleaner.

Next, in the wall structure G in which the four peripheral plates 61a, 61b and 61c are arranged, the construction process around the window portion 3 including the four peripheral plates 61a, 61b and 61c will be described with reference to FIG. Although only the upper side of the window portion 3 is shown in FIG. 4, the lower side and the side portion side are also constructed in substantially the same process.

FIG. 4A is an example of the formation of the concrete outer wall 10. First, a formwork 11 formed by a weir plate 11a, a crosspiece 11b, and a support 11c is installed, and a heat insulating composite panel 2 that also serves as a formwork is erected on the outside of the formwork 11. On the indoor side of the formwork 11, the notch plate 12 is arranged at a position corresponding to the notch portion 10a. Reinforcing bars are arranged inside the formwork 11 and concrete is placed.

FIG. 4B shows a state in which the formwork 11 is removed from the mold. The concrete outer wall 10 has a notch portion 10a formed at an end portion desired from the window portion 3 on the indoor side. Further, a step is formed between the lower end surface desired for the window portion 3 of the concrete outer wall 10 and the lower end surface desired for the window portion 3 of the heat insulating composite panel 2.

Next, as shown in FIG. 4C, the outer window frame 31a is attached via the support steel bar 34 attached to the concrete outer wall 10. An angle piece 31c is attached to the indoor side of the outer window frame 31a, and the wooden frame 33 is screwed to the angle piece 31c. By filling the mortar 35 between the concrete outer wall 10 and the outer window frame 31a and the wooden frame 33, the outer window frame 31a and the wooden frame 33 are fixed. Further, urethane foam 36 is filled between the concrete outer wall 10 and the wooden frame 33.

The inner surface of the notch 10a of the concrete outer wall 10 and the indoor end surface of the wooden frame 33 are located on the same surface, and this surface forms a recess with respect to the indoor surface of the concrete outer wall 10. ing. The four peripheral plate 61a is attached to this recess. The four peripheral plate 61a is fixed to the inner surface of the notch portion 10a and the end surface of the wooden frame 33 by a fixing tool 61d such as a nail and an adhesive. As a result, the indoor end surface of the urethane foam 36 is located on the same surface as the inner surface of the notch portion 10a and the indoor end surface of the wooden frame 33.

Next, as shown in FIG. 4D, a plastic face plate 32b is arranged on the lower surface of the wooden frame 33. Further, a plastic inner window frame 32a is arranged under the face plate 32b. The inner window frame 32a is preferably arranged so as to slightly project from the end surface of the wooden frame 33 on the indoor side to the indoor side, and the protrusion amount is more preferably 6 mm.

If necessary, after adjusting the unevenness of the indoor surface of the concrete outer wall 10, a thin resin mortar 62 is applied to the concrete outer wall 10 and the four peripheral plates 61a as an interior base to smooth the concrete outer wall 10. Finally, as shown in FIG. 4 (E), the interior material 63 such as cloth pasting, plaster wall, painting, etc. is arranged on the resin mortar 62 to finish the interior interior 6 of the room.

1 External heat insulating building 10 Concrete outer wall 10a Notch 11 Formwork 11a Dam board 11b Lumber 11c Supporting work 11d Notch 12 Notch 12 Notch board 2 Insulation composite panel 21 Exterior base material 22 Groove 23 Insulation layer 3 Window 31 Outer window 31a Outer window frame 31b Drain plate 311a 311b Air hole 31c Angle piece 32 Inner window 32a Inner window frame 32b Face plate 33 Wooden frame 34 Support bar Steel 35 Mortal 36 Foam urethane 4 Waterproof 41a Sealing material 41b Backer 5 Exterior 51 Exterior material 52, 52a Hugging material 52b Air hole 6 Interior 61a, 61b, 61c Quadruple plate 62 Resin mortar 63 Interior material 7 compartment Ventilation tank 70 Air flow

Claims (2)

The wall structure of an externally insulated building
A concrete outer wall with windows and
The inner window frame arranged in the window portion and
Urethane foam arranged between the concrete outer wall and the inner window frame,
A wooden frame arranged between the urethane foam and the inner window frame,
Equipped with
On the indoor side of the concrete outer wall, a notch is formed around the window portion.
A plate-shaped member was attached to a recess formed around the inner window frame so that the inner surface of the notch and the end surface of the wooden frame on the indoor side were flush with each other.
Wall structure. A claim that the indoor side surface of the concrete outer wall and the indoor side surface of the plate-shaped member are arranged on the same surface, a base material is further provided over these surfaces, and an interior material is further provided on the base material. The wall structure according to 1.

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