JP7168464B2 - building foundation structure - Google Patents

Description

TECHNICAL FIELD The present invention relates to a foundation structure of a building constructed with cast-in-place concrete such as a slab foundation.

Patent Literatures 1 and 2 disclose a building foundation structure formed by arranging precast concrete blocks at intervals around the periphery of a foundation slab constructed of reinforced concrete in the form of a slab. In this foundation structure, thermal insulation is placed between blocks located around the perimeter of the foundation slab.

On the other hand, Patent Literature 3 discloses a heat-insulating foundation structure for a building in which the outer side of a heat insulating material attached to the side of a continuous foundation is covered with an anti-termite sheet.

JP 2018-35530 A JP 2018-35531 A JP-A-11-350502

However, it is desirable to cover the heat insulating material with a protective layer such as concrete in order to improve the fire resistance, termite resistance, durability, etc. of the foundation and to create a sense of robustness. However, when the protective layer is formed of cast-in-place concrete and the bundles are connected, the protective layer may crack because it cannot follow the deformation of the bundles.
SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a foundation structure for a building that can improve fire resistance and durability by covering with a heat insulating material and that can suppress the occurrence of cracks.

To achieve the above object, the building foundation structure of the present invention is a building foundation structure constructed of cast-in-place concrete, comprising a bottom plate portion formed in a slab shape, and a peripheral edge of the top surface of the bottom plate portion. a plurality of bundles arranged at intervals along the same, a plate-shaped heat insulating material arranged between the bundles, a protective concrete portion formed of cast-in-place concrete on the outer surface side of the heat insulating material; A joint plate interposed between the protective concrete portion and the bundle portion has a higher deformation followability than the protective concrete portion.

Here, the bundle portion has a widened portion wider than the outer side on the inner side, and the insulating material is arranged so as to fill the opening between the widened portions, and the protective concrete portion is provided. The joint plate may be interposed between the inner surface side of and the outer surface side of the widened portion and the heat insulating material.

Further, the joint plate and the widened portion of the bundle portion and the protective concrete portion opposed thereto may be joined by a fitting structure.

Further, the heat insulating material may be arranged so as to fill the opening between the bundle portions, and the joint plate may be arranged so as to cover the end surface of the bundle portion on the opening side. Here, it is preferable that anchor portions are provided that are extended from the joint plate to the interiors of the bundle portion and the protective concrete portion, respectively.

Further, the heat insulating material may have a projecting portion projecting toward the protective concrete portion at its lower portion. Further, a coating layer may be provided so as to be flush with the side surface of the bottom plate portion and the outer side surfaces of the bundle portion and the protective concrete portion. A basic heat insulating material may be arranged inside the bundle portion and the heat insulating material.

In the foundation structure of the building of the present invention configured as described above, plate-shaped heat insulating materials are provided between a plurality of bundle portions arranged at intervals along the peripheral edge of the upper surface of the bottom plate portion formed in a slab shape. placed. Between the protective concrete portion formed of cast-in-place concrete on the outer surface side of the heat insulating material and the bundle portion, a joint plate having higher deformation followability than the protective concrete portion is interposed.

By covering the outer side of the heat insulating material with a noncombustible material such as cast-in-place concrete in this way, fire resistance and durability can be improved. Furthermore, the occurrence of cracks can be suppressed by interposing a joint plate with high deformation followability between the protective concrete portion and the bundle portion.

In addition, if a widened part is provided on the inner side of the bundle part and a joint plate is interposed between the inner side of the protective concrete part and the outer side of the widened part and the heat insulating material, It is possible to suppress the occurrence of a seam continuously crossing to the side surface side.

Furthermore, if the joint plate, the widened portion of the bundle portion facing it, and the protective concrete portion are joined by a fitting structure, it is possible to prevent them from separating even if a horizontal force acts due to shaking of an earthquake or the like.

In addition, when the heat insulating material is arranged so as to fill the opening between the bundles, if the joint plate is arranged so as to cover the end face of the bundle on the opening side, the bundle, the protective concrete part, and the heat insulating material It can be easily configured by simply arranging a joint plate like a partition between them. In such a case, by providing an anchor portion that extends from the joint plate to the inside of the bundle portion and the protective concrete portion, it is possible to make it difficult for the anchor portions to separate even if a horizontal force is applied due to shaking of an earthquake or the like.

Furthermore, if a protruding portion protruding toward the protective concrete portion is provided at the lower portion of the heat insulating material, the integrity between the heat insulating material and the protective concrete portion can be enhanced. Further, if a continuous coating layer is provided on the side surface of the bottom plate portion and the outer surface of the bundle portion and the protective concrete portion, it is possible to easily create an exterior design with continuity and a sense of unity. By arranging the basic heat insulating material inside the bundle portion and the heat insulating material, a basic structure with higher heat insulating performance can be obtained.

FIG. 2 is an enlarged perspective view illustrating the configuration of the foundation structure of the building according to the present embodiment; It is a perspective view explaining the whole foundation structure composition of a building. FIG. 2 is a plan view seen in the direction of arrows AA in FIG. 1; FIG. 2 is a cross-sectional view seen in the BB arrow direction of FIG. 1; 2 is an enlarged perspective view illustrating the configuration of the foundation structure of the building of Example 1. FIG. FIG. 6 is a plan view seen in the CC arrow direction of FIG. 5;

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is an enlarged perspective view illustrating the configuration of a building foundation structure 10 according to the present embodiment, and FIG. 2 shows the overall configuration of the foundation structure 10. As shown in FIG.

The foundation structure 10 of the present embodiment is a slab foundation of a building constructed of cast-in-place concrete. That is, as shown in FIG. 2 , the foundation structure 10 includes a foundation slab 1 as a bottom plate portion constructed in a slab shape of reinforced concrete in, for example, a rectangular area in plan view, which is a building foundation construction area, and a peripheral edge of the foundation slab 1 . A plurality of bundles (2A, 2B, 2C) arranged at intervals, a plate-shaped heat insulating material 3 arranged between the bundles, and a protective concrete arranged on the outer surface 3a side of the heat insulating material 3 It is mainly composed of a portion 5 and a joint plate 7 interposed between the protective concrete portion 5 and the bundle portions (2A, 2B, 2C).

Although illustration is omitted, the foundation slab 1 is mainly composed of a bar arrangement portion composed of a plurality of reinforcing bars arranged in a grid pattern in the horizontal direction, and concrete placed on site (cast in place concrete). configured to

Below the foundation slab 1, as shown in FIG. 1, a riprap layer 13 is formed of cobblestone, rip-off concrete, or the like. In addition, the lower part of the plate-like foundation slab 1 is backfilled under the ground G in a post-process (see FIG. 4), and the upper part protrudes from the ground G. As shown in FIG. That is, the upper portion of the side surface 12 and the upper surface 11 of the base slab 1 are protruded from the ground G and exposed.

Then, as shown in FIG. 2, along the periphery of the base slab 1, a plurality of bundles (2A-2C) are arranged at intervals. Here, the bundled portion arranged at the corner of the base slab 1 is called the corner bundled portion 2A, and the bundled portion arranged between the corner bundled portions 2A, 2A is called the intermediate bundled portion 2B or the T-shaped bundled portion 2C.

The bundles (2A-2C) are constructed of reinforced concrete so as to be integral with the foundation slab 1. The foundation slab 1 and bundles (2A-2C) can be constructed by pouring concrete once, or separately by pouring concrete twice. Here, the corner bundle portion 2A is formed in a substantially L shape in plan view, the intermediate bundle portion 2B is formed in a substantially rectangular shape in plan view, and the T-shaped bundle portion 2C is formed in a substantially T shape in plan view.

Further, inside the foundation slab 1, an I-shaped bundle portion 24 and a central bundle portion 25 are provided by reinforced concrete as needed. At the intersection of the opposing T-shaped bundle portions 2C, 2C, a central bundle portion 25 having a substantially rectangular shape in plan view is arranged, and between the intermediate bundle portion 2B and the central bundle portion 25, a substantially I-shaped I shape in plan view is provided. A mold stack 24 is placed.

Here, referring to FIGS. 1 and 2, the configuration of the bundle portion will be further described by taking the corner bundle portion 2A as an example. The bundled corner portion 2A is formed with an outer surface 21a that rises from the upper surface 11 of the base slab 1 like a wall. This outer surface 21 a forms a vertical surface that is substantially continuous with the side surface 12 of the base slab 1 .

Further, as shown in FIG. 3, the bundle portion (2A-2C) is formed with a widened portion 26 on the inner surface 21b side, which is wider than the outer surface 21a side. That is, the bundle portions (2A-2C) have both side edge portions protruding toward the opening side, and the intermediate bundle portion 2B, for example, is formed in a substantially convex shape in plan view.

A reinforcing plate 22 for connecting the building body U (see FIG. 4) via anchor bolts 23 is arranged on the upper surface of the corner bundling portion 2A. A plate-shaped heat insulating material 3 is arranged so as to fill the opening between the bundles. That is, a rectangular plate-shaped heat insulating material is formed so as to cover the rectangular openings between the corner bundle portion 2A and the intermediate bundle portion 2B, between the intermediate bundle portions 2B and 2B, and between the intermediate bundle portion 2B and the T-shaped bundle portion 2C. 3 is placed.

Such a heat insulating material 3 can be formed by one heat insulating plate, but can also be formed by stacking a plurality of heat insulating plates. A foamed plastic-based heat insulating material such as extruded polystyrene foam can be used for the heat insulating plate.

In the building foundation structure 10 of the present embodiment, as shown in FIGS. 3 and 4, two heat insulating plates, which are the projecting portion 31 and the inner portion 32, are stacked to form the heat insulating material 3. As shown in FIGS. The projecting portion 31 is arranged on the side of the outer surface 21a of the bundles (2A-2C), and the inner portion 32 is arranged on the inner side of the base slab 1. As shown in FIG. As shown in FIG. 3 , the width of the protruding portion 31 in the interbundle direction is shorter than that of the inner portion 32 , and when both are aligned at the center, both sides of the protruding portion 31 are positioned on both sides of the inner portion 32 . It becomes a shape in which the edge protrudes.

Further, as shown in FIG. 4 , the height of the upper surface of the protrusion 31 is lower than the height of the upper surface of the inner portion 32 , and the upper surface of the protrusion 31 is covered with the protective concrete portion 5 . Also, the protruding portion 31 is formed to have a thickness about half the thickness of the inner portion 32 . For example, in order to provide the heat insulating material 3 with a thickness of about 100 mm, a heat insulating plate having a thickness of about 60 mm to 70 mm as the inner portion 32 and a heat insulating plate having a thickness of about 30 mm to 40 mm as the projecting portion 31 are combined.

The protective concrete portion 5 provided on the side of the outer surface 3a of the heat insulating material 3 is made of cast-in-place concrete. That is, the inner surface 5b of the protective concrete portion 5 is formed using the projecting portion 31 and the outer surface 3a of the inner portion 32 as a formwork. For this reason, a concave portion 51 matching the shape of the projecting portion 31 is formed in the lower portion of the protective concrete portion 5 on the side of the inner surface 5b.

On the other hand, as shown in FIG. 3, a gap to be a joint 70 is provided between the side edge portions on both sides of the protective concrete portion 5 and the bundle portion (2B). In short, in the extending direction of the peripheral edge of the foundation slab 1, the protective concrete portion 5 and the bundle portions (2A-2C) are separated and not continuous.

Further, joint plates 7 are interposed between the inner surface 5b of the protective concrete portion 5, the outer surface 3a of the heat insulating material 3 (inner portion 32), and the widened portion 26 around the side edge portions on both sides of the protective concrete portion 5. be done.

The joint plate 7 is formed in a substantially rectangular strip shape in a side view so that it can be arranged from the upper edge to the lower edge of the protective concrete portion 5 . In short, the integral joint plate 7 is arranged across the widened portion 26 of the bundle (2A-2C) and the side edge portion of the inner portion 32 of the heat insulating material 3. As shown in FIG.

The joint plate 7 is made of a material with high deformation followability. For example, foamed plastic insulation such as extruded polystyrene foam can be used. For example, by foaming a polycarbonate resin at a high magnification, it can be made hard and can be made into a material with enhanced anti-termite performance. Polycarbonate resin materials have higher heat resistance and toughness than polystyrene foams, and have high adhesive performance with cement-based materials. Then, by forming the joint plate 7 from a material such as plastic foam insulation that has higher deformation followability than concrete, the deformation of the bundles (2A-2C) is directly transmitted to the protective concrete portion 5. can prevent

The joint plate 7 is joined to the widened portion 26 of the bundle portion (2A-2C) facing it and the protective concrete portion 5 by a fitting structure. This fitting structure is formed by a groove portion 71 having a substantially V-shaped cross section provided in the joint plate 7, and convex portions 27 and 52 having a substantially V-shaped cross section provided on the side of the widening portion 26 and the protective concrete portion 5. . That is, by fitting with the projections 27 and 52 fitted in the grooves 71 of the joint plate 7, the force of the joint plate 7 in the width direction (horizontal direction substantially parallel to the plate surface) can be counteracted.

The shape of the V-shaped concave-convex fitting by the joint plate 7 is not limited to this. For example, the groove may have any shape as long as it can be easily processed with a trimmer such as a substantially trapezoidal dovetail groove, a substantially U-shaped cross-sectional groove, or a substantially rectangular cross-sectional groove.

In selecting the shape of the concave-convex fitting groove provided on the plate surface of the joint plate 7, it is due to the provision of defects such as 1) adhesion strength, 2) junker ratio when placing concrete, 3) workability, and 4) grooves. reduction in strength, etc. are taken into consideration.

Therefore, 1) when examining the adhesion strength, the order of strength is: dovetail groove>rectangular groove>U-shaped groove>V-shaped groove. On the other hand, 2) the smaller the junker ratio, the better, and the order of favorable is V-shaped groove<U-shaped groove<rectangular groove=dovetail groove. 3) In terms of workability, V-shaped groove>U-shaped groove>rectangular groove=dovetail groove in descending order of working efficiency. Furthermore, 4) regarding strength reduction due to chipping, the smaller the strength reduction, the better.

Here, the reduction in strength due to chipping in 4) can be avoided by designing the thickness of the joint plate 7 to be greater than the adhesive force, so it is not an important selection point. Considering the adhesion strength per processing cost and the junker rate due to poor construction, the V-shaped groove portion 71 is most preferable, so the V-shaped groove will be described below as an example.

In the present embodiment, V-shaped grooves 71, 71 are formed at a position facing the widened portion 26 and a position facing the inner portion 32 of the heat insulating material 3 on the outer side surface 7a side of the joint plate 7, respectively. be. A V-shaped groove portion 71 is formed at a position facing the widened portion 26 on the inner side surface 7b side of the joint plate 7 .

On the other hand, the outer surface 5 a side of the protective concrete portion 5 is covered with the coating layer 6 . The covering layer 6 is substantially flush with the outer surface of the outer wall U1 of the building body U. In addition, the upper edge of the protective concrete portion 5 is covered with a draining material U2 projecting from the lower edge of the building body U.

1 and 4, the basic heat insulating material 4 is arranged along the inner surface 21b side of the bundle portions (2A-2C) and the side surface of the inner portion 32 of the heat insulating material 3. FIG. For the basic heat insulating material 4, for example, a foamed plastic heat insulating material (thickness of about 100 mm) having a fine cellular structure can be used.

Further, as shown in FIG. 1, a continuous coating layer 6 can be provided as an exterior on the outer surface of the base structure 10 formed flush. For example, the coating layer 6 can be formed by applying a coating as a finishing layer to the surface of a base layer coated with a highly elastic resin mortar or the like.

Next, a construction method of the building foundation structure 10 according to the present embodiment will be described.
First, the ground G to be the foundation construction area is excavated, cobblestone (crushed stone) is spread evenly, and then the riprap layer 13 is provided by placing dump concrete. Then, reinforcing bars for the foundation slab 1 are arranged on the rubble layer 13 .

On top of the reinforcing bars for the foundation slab 1, the bundles (2A-2C), the I-shaped bundles 24 and the central bundles 25 are also arranged. Furthermore, the inner portion 32 of the heat insulating material 3 is formed to match the shape of the opening between the widened portions 26, 26 of the bundle (2A-2C), and the outer surface 3a side of the inner portion 32 is provided with it. A protruding portion 31 having a width narrower than that is arranged.

Also, joint plates 7 are arranged along both side edge portions of the inner portion 32 of the heat insulating material 3 . Furthermore, a void material that can be easily removed after the concrete hardens or that can be regarded as equivalent to a gap is placed at a location where a joint 70 that will be a gap substantially perpendicular to the side edge of the joint plate 7 is formed.

Formwork is then assembled at a position covering the outer surface 5a of the protective concrete portion 5 and at a position that will be the outer surface 21a of the bundle (2A-2C), and cast-in-place concrete is placed. Here, the concrete can be cast at one time, but it is also possible to cast the concrete in two steps, one for the foundation slab 1 and the other.

When concrete is poured into the foundation slab 1 and bundles (2A-2C), the concrete that has flowed into the grooves 71 of the joint plate 7 hardens to form the projections 27 and 52. As shown in FIG. Also, a portion where the protruding portion 31 is arranged and not filled with concrete becomes a recessed portion 51 of the protective concrete portion 5 .

After curing the concrete, the formwork is removed, and dirt and foreign matter such as concrete slag adhering to the surfaces of the bundles (2A-2C) and the foundation slab 1 are removed.
Then, on the inner side surface 21b of the bundle (2A-2C) and the side surface of the inner portion 32 of the heat insulating material 3, the basic heat insulating material 4 coated with an adhesive is attached. Furthermore, the top surfaces of the heat insulating material 3, the protective concrete portion 5 and the bundle portions (2A-2C) can be covered with a waterproof sheet if necessary.

Then, as shown in FIG. 1, the outer surface 21a of the bundle (2A-2C), the side surface 12 of the base slab 1, and the outer surface 5a of the protective concrete portion 5 are continuously coated with highly elastic resin mortar. A base layer is provided, and a finish layer is applied thereon to complete the coating layer 6.例文帳に追加In addition, the coating layer 6 can also be completed by coating once.

Next, the operation of the building foundation structure 10 of the present embodiment will be described.
The building foundation structure 10 of the present embodiment configured in this manner includes a plurality of bundle portions (2A-2C ), a plate-like heat insulating material 3 is arranged so as to fill the opening.

Between the protective concrete portion 5 formed of cast-in-place concrete on the outer surface 3a side of the heat insulating material 3 and the widened portion 26 of the bundle portion (2A-2C), there is a deformation-following property higher than that of the protective concrete portion 5. A high joint plate 7 is interposed.

Thus, by covering the outer surface 3a side of the heat insulating material 3 with the protective concrete portion 5 made of a noncombustible material such as cast-in-place concrete, fire resistance can be improved. In addition, high adhesion can be ensured due to the adhesive strength of cast-in-place concrete. In addition, since cast-in-place concrete is a cheap and easily available material, it is excellent in workability.

Furthermore, by interposing the joint plate 7 with high deformation followability between the protective concrete portion 5 and the bundle portions (2A-2C), the occurrence of cracks can be suppressed. In short, by applying a force due to the deformation of the bundle (2A-2C) through the joint plate 7 to the protective concrete portion 5 made of cast-in-place concrete having a relatively small tensile force, stress that causes cracks is generated. can be suppressed.

Then, widened portions 26, 26 are provided on the inner side surface 21b side of the bundle portion (2A-2C), and between the inner side surface 5b side of the protective concrete portion 5 and the widened portion 26 and the outer side surfaces 21a, 3a side of the heat insulating material 3 By adopting a configuration in which the joint plate 7 is interposed between the joint plates 7, it is possible to suppress the occurrence of a seam continuously crossing from the outer surface side to the inner surface side.

Furthermore, if the joint plate 7 and the widened portion 26 of the bundle portion (2A-2C) facing it and the protective concrete portion 5 are joined by a fitting structure, even if a horizontal force acts due to shaking of an earthquake, etc. You can make it difficult to leave. Further, even if a large horizontal force acts due to shaking of a large earthquake or an external impact, the joint plate 7 can follow the deformation, so that the adhesion performance such as waterproofness and termite resistance is maintained.

In addition, if the projecting portion 31 projecting toward the protective concrete portion 5 is provided at the lower portion of the outer surface 3a side of the heat insulating material 3, the projecting portion 31 is fitted into the recessed portion 51 of the protective concrete portion 5 to provide heat insulation. The integrity between the material 3 and the protective concrete portion 5 can be enhanced.

Furthermore, if the outer surface 21a of the bundle portion (2A-2C) and the outer surface 5a of the protective concrete portion 5 are formed flush with each other, it becomes easier to provide an exterior material or the like straddling them, so that the design of the exterior can be improved. You are free to raise it.

In addition, since there is no projecting portion on the side surface 12 side of the base slab 1, there is no need to use an exterior panel or the like, and it is possible to freely reduce costs while maintaining a high degree of design, with few restrictions. can.

If the coating layer 6 is provided continuously on the side surface 12 of the base slab 1, the outer surface 21a of the bundle (2A-2C), and the outer surface 5a of the protective concrete portion 5, the exterior has continuity and a sense of unity. design can be easily created. Further, by arranging the basic heat insulating material 4 inside the bundle portions (2A-2C) and the heat insulating material 3, a basic structure with higher heat insulating performance can be obtained.

Example 1, which is different from the above embodiment, will be described below with reference to FIGS. 5 and 6. FIG. It should be noted that the same terminology or the same reference numerals will be used to describe the same or equivalent portions as those described in the above embodiment.

In the building foundation structure 10A of Example 1, the configuration of the joint 80 is different from the configuration of the joint 70 described in the above embodiment. That is, as shown in FIG. 5, the base structure 10A includes a base slab 1 as a bottom plate, a plurality of bundles (2D, 2E) arranged at intervals around the periphery of the base slab 1, and a bundle between the bundles. A plate-shaped heat insulating material 3A arranged in the heat insulating material 3A, a protective concrete portion 5A arranged on the outer surface 3a side of the heat insulating material 3A, and an eye interposed between the protective concrete portion 5A and the bundle portion (2D, 2E) It is mainly configured by the main plate 8 .

In the first embodiment, only the corner bundle portion 2D, which is the bundle portion arranged at the corner of the base slab 1, and the intermediate bundle portion 2E arranged between the corner bundle portions 2D, 2D are shown as bundle portions. As will be explained, bundles such as T-shaped bundles are also provided as in the previous embodiment.

The bundles (2D, 2E) are constructed of reinforced concrete so as to be integrated with the foundation slab 1. Here, the corner bundle portion 2D is formed in a substantially L shape in plan view, and the intermediate bundle portion 2E is formed in a substantially rectangular shape in plan view.

In addition, in the bundle portions (2D, 2E) of Example 1, the end face on the side of the opening where the heat insulating material 3A is arranged is formed into a substantially rectangular plane when viewed from the front. That is, the bundle portions (2D, 2E) are formed with an end face substantially orthogonal to the outer side surface 21a and the inner side surface 21b on the opening side.

A plate-shaped heat insulating material 3A is arranged so as to fill the opening between the bundles. That is, the rectangular plate-shaped heat insulating material 3A is arranged so as to close the rectangular opening between the corner bundle portion 2D and the intermediate bundle portion 2E and between the intermediate bundle portions 2E, 2E.

Such a heat insulating material 3A can be formed by a heat insulating board such as foamed plastic heat insulating material such as extruded polystyrene foam. In the building foundation structure 10A of the first embodiment, as shown in FIGS. 5 and 6, two insulating plates, which are the projecting portion 31A and the inner portion 32, are stacked to form the insulating material 3A. The projecting portion 31A is arranged on the outer side surface 21a side of the bundle portions (2D, 2E), and the inner portion 32 is arranged on the inner side of the base slab 1. As shown in FIG.

As shown in FIG. 6, the protruding portion 31A and the inner portion 32 are formed to have the same width, which is the length in the interbundle direction. Further, the height of the upper surface of the projecting portion 31A is lower than the height of the upper surface of the inner portion 32, and the upper portion of the projecting portion 31A is covered with the protective concrete portion 5A (see FIG. 4 of the above embodiment). Moreover, the protruding portion 31A is formed to have a thickness approximately half the thickness of the inner portion 32 .

The protective concrete portion 5A provided on the side of the outer surface 3a of the heat insulating material 3A is formed of cast-in-place concrete using the upper outer surface 3a of the projecting portion 31A and the inner portion 32 as a formwork.

Joints 80 are provided between the side edge portions on both sides of the protective concrete portion 5A and the heat insulating material 3A and the bundle portion (2E). This joint 80 is provided so as to be substantially orthogonal to the outer side surface 21a and the inner side surface 21b of the bundle (2E).

A joint plate 8 is arranged at the joint 80 so as to cover the end face of the bundle portion (2E) on the opening side. That is, the joint plate 8 is interposed between the side edge portions on both sides of the protective concrete portion 5A and the heat insulating material 3A and the bundle portion (2E).

The joint plate 8 is formed in a substantially rectangular band plate shape when viewed from the front so that it can be arranged from the upper edge to the lower edge of the end face of the bundle (2E). In short, the integrated joint plate 8 extends from the outer surface 21a side to the inner surface 21b side of the bundle (2E), and is arranged so as to straddle the protective concrete portion 5A and the heat insulating material 3A.

The joint plate 8 is made of the same material as the joint plate 7 described in the above embodiment. That is, it is molded from a foamed plastic heat insulating material such as a polycarbonate resin material or an extruded polystyrene foam, which is highly deformable.

The joint plate 8 is joined to the bundle portion (2E) facing it and the protective concrete portion 5A by a fitting structure. This fitting structure includes a groove portion 81 which is a dovetail groove having a substantially trapezoidal cross section provided in the joint plate 8, and convex portions 27A and 52A having a substantially trapezoidal cross section provided on the side of the bundle portion (2E) and the protective concrete portion 5A. formed by That is, by fitting the protrusions 27A and 52A fitted into the grooves 81 of the joint plate 8, the force in the width direction (horizontal direction substantially parallel to the plate surface) of the joint plate 8 can be resisted. In addition, although the case where the groove part 81 is provided in three places of the joint board 8 of 1 sheet was demonstrated in FIG. 6, it is not limited to this. As shown in the figure, grooves 81 are provided at three locations to increase adhesion to both the bundle portion (2E) side and the protective concrete portion 5A side. can be followed. On the other hand, even when the two grooves 81 are provided on the outer surface side and the inner surface side, if the joint plate 8 remains so as to bridge the joint 80 obliquely, the gap can be continuously closed by following the deformation due to expansion and contraction. can.

Furthermore, a screw anchor 82 as an anchor portion is attached to the joint plate 8 in a direction substantially orthogonal to the plate surface. The screw anchor 82 is inserted perpendicularly to the plate surface of the joint plate 8 so that the head thereof is hooked on the plate surface.

The screw anchors 82 are attached so as to extend from the heat insulating material 3A side into the bundle (2E), and those attached so as to extend from the bundle (2E) side into the protective concrete portion 5A. There is. That is, the screw anchor 82 is provided to fix the joint plate 8 to the bundle portion (2E) and the protective concrete portion 5A.

A plurality of screw anchors 82 are attached at intervals in the vertical direction. For example, a plurality of screw anchors 82, .

In the building foundation structure 10A of the first embodiment configured as described above, the heat insulating material 3A is arranged so as to fill the openings between the bundles, and the openings of the bundles (2D, 2E) are covered so as to cover the end faces on the opening side. A ground plate 8 is arranged.

With such an arrangement of the joint plate 8, it is only necessary to arrange it like a partition between the bundle portions (2D, 2E), the protective concrete portion 5A, and the heat insulating material 3A, so that the structure can be easily constructed. Even in the case of such arrangement of the joint plate 8, by providing the screw anchors 82 extending from the joint plate 8 to the inside of the bundle portions (2D, 2E) and the protective concrete portion 5A, respectively, the earthquake can be prevented. It is possible to make it difficult to separate even if a horizontal force acts due to shaking or the like.
Other configurations and effects are substantially the same as those of the above-described embodiment, so description thereof will be omitted.

As described above, the embodiments and examples of the present invention have been described in detail with reference to the drawings. is included in the present invention.

For example, in the above-described embodiment and Example 1, the case where the adhesion of the joint plates 7 and 8 is increased by V-shaped or trapezoidal concave-convex fitting has been described, but the present invention is not limited to this. For example, by drilling a hole in the joint plate and filling the hole with concrete, a concave-convex fit can be formed.

10, 10A: Building foundation structure 1: Foundation slab (bottom plate)
11: Upper surface 12: Side surfaces 2A, 2D: Corner bundle (bundle)
2B, 2E: Intermediate bundle (bundle)
2C: T-shaped bundle (bundle)
21a: Outer surface 21b: Inner surface 26: Widened parts 27, 27A: Protruding parts 3, 3A: Heat insulating material 3a: Outer surfaces 31, 31A: Projecting part 4: Basic heat insulating material 5, 5A: Protective concrete part 5a: Outer surface 5b: inner side surfaces 52, 52A: convex portion 6: coating layer 7: joint plate 71: groove portion 8: joint plate 81: groove portion 82: screw anchor (anchor portion)
U: Building body (building)

Claims (7)

A foundation structure of a building constructed of cast-in-place concrete,
a slab-shaped bottom plate;
a plurality of bundles arranged at intervals along the periphery of the upper surface of the bottom plate;
a plate-shaped heat insulating material arranged between the bundles;
a protective concrete portion formed of cast-in-place concrete on the outer surface side of the heat insulating material;
a joint plate interposed between the protective concrete portion and the bundle portion having higher deformation followability than the protective concrete portion ;
The bundle portion has a widened portion on the inner side surface side, the widened portion being wider than the outer side surface side, and the heat insulating material is arranged so as to fill the opening between the widened portions,
The foundation structure of a building , wherein the joint plate is interposed between the inner surface side of the protective concrete portion and the outer surface side of the widened portion and the heat insulating material . 2. The foundation structure of a building according to claim 1 , wherein the joint plate and the widened portion of the bundle portion and the protective concrete portion opposed thereto are joined by a fitting structure. A foundation structure of a building constructed of cast-in-place concrete,
a slab-shaped bottom plate;
a plurality of bundles arranged at intervals along the periphery of the upper surface of the bottom plate;
a plate-shaped heat insulating material arranged between the bundles;
a protective concrete portion formed of cast-in-place concrete on the outer surface side of the heat insulating material;
a joint plate interposed between the protective concrete portion and the bundle portion having higher deformation followability than the protective concrete portion;
The basic structure of a building , wherein the heat insulating material has a projecting portion projecting toward the protective concrete portion at a lower portion thereof. A foundation structure of a building constructed of cast-in-place concrete,
a slab-shaped bottom plate;
a plurality of bundles arranged at intervals along the periphery of the upper surface of the bottom plate;
a plate-shaped heat insulating material arranged between the bundles;
a protective concrete portion formed of cast-in-place concrete on the outer surface side of the heat insulating material;
a joint plate interposed between the protective concrete portion and the bundle portion having higher deformation followability than the protective concrete portion;
The foundation structure of a building , wherein a covering layer is provided so as to be flush with the side surface of the bottom plate portion and the outer side surfaces of the bundle portion and the protective concrete portion. A foundation structure of a building constructed of cast-in-place concrete,
a slab-shaped bottom plate;
a plurality of bundles arranged at intervals along the periphery of the upper surface of the bottom plate;
a plate-shaped heat insulating material arranged between the bundles;
a protective concrete portion formed of cast-in-place concrete on the outer surface side of the heat insulating material;
a joint plate interposed between the protective concrete portion and the bundle portion having higher deformation followability than the protective concrete portion;
A basic structure of a building , wherein a basic heat insulating material is arranged inside the bundle portion and the heat insulating material. The heat insulating material is arranged so as to fill the opening between the bundles,
The foundation structure of the building according to any one of claims 3 to 5 , wherein the joint plate is arranged so as to cover the end surface of the bundle portion on the opening side. 7. The foundation structure of a building according to claim 6 , further comprising anchor portions extending from said joint plate to insides of said bundle portion and said protective concrete portion, respectively.

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