JP2021042604A - Connecting metal fitting - Google Patents

Abstract

To provide a connecting metal fitting which connects a structural wall with a structure comprising durability even to stress other than that in a shearing direction in a wooden building structure.SOLUTION: A connecting metal fitting 10' connecting a vertically standing flat plate-like wooden structural wall 2' with a structure 4 disposed perpendicularly to the structural wall 2'. The connecting metal fitting 10' comprises: a foundation portion 10b' disposed at an opening side of a recessed portion 2b' formed in the structural wall 2' and fixed to the structure 4; and a plate-like insertion plate portion 10c' extended from the foundation portion 10b' toward an inside of the recessed portion 2b'. In the insertion plate portion 10c', there are provided a plurality of slits 10d, 10e, 10f ... where a trunk of a drift pin 21 penetrating the structural wall 2' in front/back direction is respectively disposed, in a left and right direction. The slits 10d, 10e, 10f ... are formed so that an end edge at an opposite side to the foundation portion 10b' in a vertical direction of the insertion plate portion 10c' is open.SELECTED DRAWING: Figure 4

Description

The present invention relates to a connecting metal fitting that connects a structural wall and a structure in a wooden building structure such as a house, a store, or a warehouse.

Construction methods used for wooden buildings include frame construction methods, frame wall construction methods, rigid frame construction methods, etc., all of which are columns and structural walls that make up the walls, and beams and slabs that make up the floor and ceiling surfaces. It is designed to be connected to the structure.

For example, in the building structure shown in Patent Document 1, a wooden pillar to which a wall is fixed and a wooden beam are connected by using a connecting metal fitting. Specifically, the connection fitting comprises a foundation that is screwed to a wooden beam and a plate-shaped insertion plate that extends from the foundation toward the inside of a recess formed at the top or bottom of the column. , The insertion plate portion is formed with a through hole penetrating in the front-rear direction, and the body portion of the drift pin pierced through the pillar in the front-rear direction is inserted into the through hole.

In the connection fitting as in Patent Document 1, a plurality of through holes are formed in the left-right direction of the insertion plate portion, and the shear direction that occurs when the column and the beam move in the horizontal direction or the column is deformed in the left-right direction. The stress can be distributed to the body of a plurality of drift pins, and the structural strength at the connecting portion between these columns and beams can be increased. In recent years, such connection fittings have also been used for connecting structural walls to structures in the frame wall construction method.

Japanese Unexamined Patent Publication No. 2006-104730 (Page 4, Fig. 2)

External force such as an earthquake acts on the building, and due to the movement and deformation of the columns, not only the stress in the shear direction but also the force that causes the columns and beams to tilt in the vertical direction or separate from each other in the vertical direction at the connection part. May work. In the case of a connection fitting as in Patent Document 1 against such a force, the through hole and the drift pin of the metal insertion plate portion having high structural strength have high durability, so that the hole portion of the wooden pillar is used. Stress is concentrated between the drift pin and the hole, and there is a risk of damage such as cracking around the hole through which the drift pin is pierced.

The present invention has been made by paying attention to such a problem, and in a wooden building structure, a connecting metal fitting for connecting a structural wall and a structure having durability against stresses other than in the shear direction is provided. The purpose is to provide.

In order to solve the above problems, the connection fitting of the present invention is used.
It is a connecting metal fitting that connects a flat wooden structural wall that stands up in the vertical direction and a structure that is arranged orthogonally to the structural wall.
The connection fittings are a base portion arranged on the opening side of a recess formed in the structural wall and fixed to the structure, and a plate-shaped insertion plate portion extending from the foundation portion toward the inside of the recess. And with
The insertion plate portion is provided with a plurality of slits in the left-right direction in which the body portions of the drift pins pierced in the front-rear direction are arranged in the structural wall.
The slit is characterized in that the end edge on the opposite side of the foundation portion in the vertical direction of the insertion plate portion is open.
According to this feature, the body of the drift pin that is inserted into the hole that penetrates the structural wall back and forth is arranged in the slit formed in the insertion plate of the connection fitting, so that the structural wall and the structure Relative movement in the horizontal direction can be regulated. In addition, the slit is open to the edge of the insertion plate on the opposite side of the foundation in the vertical direction, and the drift pin is allowed to move in the vertical direction in the slit, so that external forces such as earthquakes can be applied. Drift even when the structural wall and the structure are tilted in the vertical direction or separated from each other in the vertical direction due to the movement or deformation of the structural wall acting on the building. Stress is not concentrated between the pin and the hole through which the drift pin is pierced, and damage to the wooden structural wall can be effectively prevented.

Each of the slits is characterized in that it extends in the vertical direction.
According to this feature, each drift pin evenly contacts each slit when the structural wall and the structure move relative to each other in the horizontal direction.

The starting ends of the slits located at the left and right ends of the insertion plate portion are located on the base portion side as compared with the starting ends of the slits located on the center side of the insertion plate portion, and the drift pin is located on the slit. It is characterized by being separated from the starting end side.
According to this feature, when the structural wall and the structure are tilted in the vertical direction, it is possible to secure a large movement allowance for the drift pins at both the left and right ends having a large movement width.

The plurality of slits are characterized in that the starting ends are formed so as to be separated from the foundation portion as the insertion plate portion approaches the center side from the left and right ends.
According to this feature, the drift pins can be formed in a dispersed manner in the vertical direction, so that the strength of the structural wall can be ensured.

The end edge of the insertion plate portion on the opposite side of the foundation portion is characterized in that it is formed in an arc shape.
According to this feature, even if the drift pin comes out of the slit due to the relative movement between the structural wall and the structure, the drift pin interferes with the edge of the insertion plate when the relative movement between the structural wall and the structure converges. It is easy to return to the slit without doing it.

It is a perspective view which shows the building structure in the Example of this invention. It is an exploded perspective view which shows the building structure. It is an exploded perspective view which shows the state of connecting a structural wall and a 1st beam structure. It is a front sectional view which shows the building structure. FIG. 4 is a cross-sectional view taken along the line AA of FIG. It is a front view which shows the structure of a shear metal. (A) is an explanatory view showing a normal state of the first beam structure and the second beam structure, and (b) shows a state in which the second beam structure is horizontally moved to the right side with respect to the first beam structure. Explanatory drawing, (c) is explanatory drawing which shows the state which the 2nd beam structure moved horizontally to the right side from the state of (b). (A) is an explanatory diagram showing a normal state of the shear hardware and the drift pin, (b) is an explanatory diagram showing a state in which the drift pin is moved up and down with respect to the shear hardware, and (c) is further from the state of (b). It is explanatory drawing which shows the state which the drift pin moved up and down.

A mode for carrying out the connection fitting according to the present invention will be described below based on examples.

The building structure according to the embodiment will be described with reference to FIGS. 1 to 8. Hereinafter, the front right side of the paper in FIG. 1 will be referred to as the front side (front side) of the building structure, and the left and right sides of the building structure as viewed from the front will be described as the left and right sides of the building structure.

As shown in FIG. 1, the building structure 1 is, for example, a building structure such as a detached house or an apartment, and is applied to a two-story building in this embodiment. Although the building structure 1 of this embodiment exemplifies a two-story building, it can also be applied to a one-story building or a three-story or more building.

As shown in FIGS. 1 and 2, the building structure 1 includes a foundation F, a plurality of structural walls 2, 2', ..., A first slab 3 (structural slab plate), and a first beam structure 4 ( (Structure), a second slab 5 (structural slab plate), a second beam structure 6 (structure), and a roofing material 7. Specifically, a plurality of structural walls 2 forming a side wall (outer wall) of the first floor portion are erected and arranged above the foundation F. The first slab 3 is fixed above the structural wall 2 on the first floor, and the first beam structure 4 is fixed above the first slab 3. Further, above the first beam structure 4, a plurality of structural walls 2'constituting the side walls of the second floor portion are erected and arranged. A second slab 5 is fixed above the structural wall 2'on the second floor, a second beam structure 6 is fixed above the second slab 5, and a roofing material is fixed above the second beam structure 6. 7 is fixed. That is, the structural walls 2 and 2'support the first slab 3 and the second slab 5, and columns other than the structural walls 2 and 2'can be omitted. In this embodiment, the embodiment in which the structural walls 2 and 2'contain the side wall is illustrated, but the side wall may be separately provided on the outside of the structural walls 2 and 2'.

The structural walls 2 and 2'are composed of, for example, laminated wood plank panels having a thickness of 150 mm, and are arranged side by side in the left-right direction or the front-rear direction (the width direction of the structural wall 2) to form the building structure 1. It constitutes the side wall. Further, a window frame 16 is installed at a portion where the structural walls 2 and the structural walls 2'are separated from each other (only FIG. 1 is shown). The window frame 16 may not be provided at the portion where the structural walls 2 and 2'are separated from each other and may be used as an opening, or another structural member may be arranged in place of the window frame 16.

Further, a floor plate (floor finishing material) (not shown) is supported above the foundation F and the first beam structure 4. Further, a partition (not shown) different from the structural walls 2 and 2'that divide the space is provided on the first floor portion or the second floor portion of the building structure 1. The partition of the first floor portion is fixed between the first slab 3 and the floor board in a state of being suspended from the first slab 3. That is, since the partition is supported by the first slab 3 having a structural strength higher than that of the floor plate, the partition can be stably installed. Since the partition on the second floor has the same configuration as the partition on the first floor, the description thereof will be omitted. Further, the partition may be installed independently above the floor board, and in this case, the partition may be a partition having a height that does not reach the first slab 3 or the second slab 5.

The first slab 3 is integrally formed by arranging and fixing a plurality of thick laminated wood sheets 31, 31'with a thickness of 150 to 210 mm in the left-right direction (width direction of the first slab 3). It functions as a structural slab board that constitutes the ceiling of the first floor. The thick plate laminated wood 31 is formed shorter in the front-rear direction than the thick plate laminated wood 31', and the first slab 3 has a substantially L shape when viewed from above.

Further, the second slab 5 is integrally formed by arranging and fixing a plurality of thick plate laminated wood 51 having a thickness of 150 to 210 mm in the left-right direction (width direction of the second slab 5). It functions as a structural slab board that constitutes the ceiling on the second floor. The plank laminated wood 51 extends in the front-rear direction to the same length, and the second slab 5 forms a rectangle when viewed from above.

As shown in FIGS. 2 and 3, the first beam structure 4 is formed in a frame body in which a plurality of H-shaped steels 41 to 48 (metal beams) are integrally connected. Specifically, the H-shaped steels 41 and 42 extending in the left-right direction are arranged in parallel with each other separated from each other in the front-rear direction, and the H-shaped steels 43 and 44 extending in the front-rear direction so as to connect the H-shaped steels 41 and 42. 45 and 46 are arranged so as to be separated from each other on the left and right. The H-shaped steels 41 and 42 are separated by substantially the same length as the length of the thick plate laminated wood 31 in the front-rear direction, and extend in a direction orthogonal to the extending direction (front-back direction) of the thick plate laminated wood 31. ..

Further, the H-shaped steel 43 arranged on the rightmost side of the H-shaped steels 43 to 46 and the H-shaped steel 44 adjacent to the left side thereof are connected by an H-shaped steel 47 extending in the left-right direction. The H-shaped steel 44 and the H-shaped steel 45 adjacent to the left side thereof are connected by an H-shaped steel 48 extending in the left-right direction. Further, the H-shaped steel 43 connects the right end portions of the H-shaped steels 41 and 42, and the H-shaped steel 46 arranged on the leftmost side of the H-shaped steels 43 to 46 is the H-shaped steel 41 and 42. It is connected at the position on the right side of the left end. Since the second beam structure 6 has the same configuration as the first beam structure 4, the description of the second beam structure 6 will be omitted.

Next, a detailed connection mode of the structural walls 2, 2', the first slab 3, and the first beam structure 4 will be described with reference to FIGS. 3 to 5. Since the connection mode of the structural wall 2', the second slab 5, and the second beam structure 6 is the same as the connection mode of the structural wall 2, the first slab 3, and the first beam structure 4, the description thereof will be described. Omit. Furthermore, here, a mode in which the structural walls 2, 2'and the first slab 3 are connected to the H-shaped steel 41 of the first beam structure 4 will be illustrated.

As shown in FIGS. 3 to 5, joining bolts 8 extending in the vertical direction are embedded and installed on both the left and right sides of the upper end portion of the structural wall 2. The upper end of the joint bolt 8 protrudes above the upper end surface 2a of the structural wall 2, and is fixed to the connection fitting 12 by screwing the nut 24 after inserting the joint bolt 8 into the lower plate portion 12B of the connection fitting 12. ing. At this time, since the lower plate portion 12B of the connecting metal fitting 12 comes into contact with the upper end surface 2a of the structural wall 2, the connecting metal fitting 12 does not easily move in the horizontal direction or tilt in the vertical direction, and the joining bolt It is possible to suppress the concentration of stress on the 8 and prevent the joint bolt 8 from being deformed. As will be described in detail later, the joining bolt 8 has a telescopic structure in which the rod-shaped body 26 is inserted into the tubular body 25 and is connected so as to be relatively movable within a predetermined stroke in the separating direction (see FIG. 7). ..

The connection fitting 12 has a structure arranged in the notch portion 15 of the first slab 3, and the upper plate portion 12A thereof is fixed to the bottom plate of the H-shaped steel 41 by bolts, nuts 17 and the like. Specifically, the bolts and nuts 17 are fixed on both sides of the upright portion 41b of the H-shaped steel 41. The notch portion 15 has a size that allows the connection fitting 12 to be loosely fitted, and the connecting fitting 12 is provided with the covering wood 18 in the gap between the connection fitting 12 and the notch portion 15. Rattling is regulated.

Further, an insertion plate portion 10c of the shear metal fitting 10 (connecting metal fitting) is embedded and installed in the central portion of the upper end portion of the structural wall 2. The shear metal 10 extends from the foundation portion 10b toward the recess 2b and the foundation portion 10b fixed to the peripheral edge of the opening of the recess 2b (see FIG. 5) formed in the central portion of the upper end portion of the structural wall 2. A plate-shaped insertion plate portion 10c to be provided is provided, and a bolt 10a extending upward is provided on the base portion 10b.

The shear metal fitting 10 is fixed to the box metal fitting 11 by the bolt 10a and the nut 20, and the box metal fitting 11 is fixed to the bottom plate of the H-shaped steel 41 by the bolt and the nut 19 or the like via the notch portion 15'. There is.

Further, the connection fitting 12 and the box fitting 11 have a thickness similar to the thickness of the first slab 3, and have a structure arranged in the cutouts 15, 15'of the first slab 3, and have a first beam structure. By connecting the body 4 and the structural walls 2 and 2'on the upper and lower floors via the connecting metal fittings 12 and the box metal fittings 11, it is easy to assemble while ensuring their fixing strength.

Further, joining bolts 8'extending in the vertical direction and metal fittings 22 connected to the lower ends of the joining bolts 8'are embedded and installed on both left and right sides of the lower end portion of the structural wall 2'. The metal fitting 22 has a rectangular shape in a plan view, and is fixed to the upper plate of the H-shaped steel 41 with bolts, nuts 23, and the like.

In this embodiment, the connection fitting 12 has a height similar to the thickness of the first slab 3, and the connection fitting 12 supports the first beam structure 4, but the present invention is not limited to this. For example, the connecting metal fitting 12 may be formed at a height lower than the thickness of the first slab 3, and the connecting metal fitting 12 may be connected at a position slightly downwardly separated from the first beam structure 4.

Further, a recess 2b'(see FIG. 5) is formed in the central portion of the lower end portion of the structural wall 2', and the insertion plate portion 10c'of the shear metal fitting 10'(connecting metal fitting) is embedded in the recess 2b'. It is installed. Further, the bolt 10a'extending downward from the foundation portion 10b'of the shear metal fitting 10'is inserted from above into the through hole 41a formed in the H-shaped steel 41 of the first beam structure 4 and fastened by the nut 9. ..

Further, the H-shaped steel 41 of the first beam structure 4 is fixed to the first slab 3 by using a screw 14 and a screw hole 3a of the first slab 3. That is, the first slab 3 and the first beam structure 4 are integrated, and the first slab 3 is supported while its structural strength is reinforced by the first beam structure 4.

Further, as described above, since the first slab 3 has a substantially L-shape when viewed from above, the front portion of the thick plate laminated wood 31'is stretched to the front side of the first beam structure 4. It is supposed to be put out. That is, the front portion of the thick plate laminated wood 31'has a cantilever structure, and since there are no structural walls 2 or pillars below, the space on the first floor can be produced openly.

The structural wall 2 is arranged at positions vertically above and vertically below the H-shaped steel 41 of the first beam structure 4. The structural wall 2 forming the side wall of the first floor portion is fixed to the foundation F via anchor bolts, metal fittings, etc. (not shown).

Next, the structure of the shear hardware 10, 10'will be described with reference to FIG. Since the structures of the shear metal fittings 10 and 10'are almost the same, the structure of the upper shear metal fitting 10'in FIG. 6 will be described here, and the description of the lower shear metal fitting 10 will be omitted.

As shown in FIG. 6, the insertion plate portion 10c'of the shear metal fitting 10'is substantially such that the vertical width of the central portion of the upper end edge (the end edge on the opposite side of the foundation portion 10b') is high. It is formed in an arc shape, and a plurality of slits 10d, 10e, 10f, ... That open upward are provided in the left-right direction, and a guide slit 10 g that also opens upward is provided at the center portion of the insertion plate portion 10c'in the left-right direction. It is provided in.

One slit 10d, 10e, and 10f are formed on each of the left and right sides of the guide slit 10g, and each is formed so as to extend in the vertical direction (vertical direction). Further, the slits 10d, 10e, 10f, ... Have substantially the same vertical dimension L1. As described above, since the insertion plate portion 10c'is formed in a substantially arc shape so that the vertical width of the central portion is high, the start ends of the slits 10d arranged at the left and right ends of the insertion plate portion 10c'. 10j (the end on the base portion 10b'side) is arranged at the position P1 closest to the base portion 10b', and the starting end 10k of the slit 10e adjacent to the center side of the insertion plate portion 10c'of the slit 10d is the position P1. The starting end 10m of the slit 10f, which is arranged at a position P2 farther from the base portion 10b'and is adjacent to the center side of the insertion plate portion 10c' of the slit 10e, is a position P3 farther from the base portion 10b' than the position P2. Is located in.

Further, the guide slit 10g has a vertical dimension L2 longer than the dimension L1 (L1 <L2). Further, the starting end 10n (the end on the base portion 10b'side) of the guide slit 10g is arranged at the position P2.

The body of the drift pin 21 pierced in the front-rear direction of the structural wall 2'is arranged in each of the slits 10d, 10e, 10f, ... And the guide slit 10g (particularly, FIGS. 5 and 7 (a)). reference). A hole 2c'extending a predetermined length from the front surface side to the rear surface side is formed in the structural wall 2', and the drift pin 21 is inserted through the hole 2c'(see FIG. 5). The structural wall 2 is formed with a hole 2c extending from the rear surface side to the front surface side by a predetermined length, and the drift pin 21 is inserted through the hole 2c.

Next, a case where the first beam structure 4 and the second beam structure 6 move relatively horizontally will be described with reference to FIGS. 7 and 8. Here, the shear stress applied to the joint portion between the structural wall 2'and the first beam structure 4 will be described, and the shear stress applied to the joint portion between the structural wall 2'and the second beam structure 6 will be described. Omit.

As shown in FIG. 7A, normally, the structural wall 2'and the first beam structure 4 and the second beam structure 6 are connected so as to be orthogonal to each other. Further, a tubular body 25 is embedded and fixed in the structural wall 2', and the upper end portion of the rod-shaped body 26 is loosely inserted into the tubular body 25 to form a joining bolt 8'. The body 25 and the rod 26 are connected so as to be relatively movable within a predetermined stroke in a direction away from each other.

Further, as shown in FIG. 8A, normally, the body portion of each drift pin 21 is arranged at the slits 10d, 10e, 10f, ... Of the shear metal fitting 10'and the guide slit 10g substantially at the center in the vertical direction. ing. The body of the drift pin 21 has a diameter slightly smaller than the left-right width of the slits 10d, 10e, 10f, ... And the guide slit 10g, and movement in the left-right direction is restricted.

As shown in FIG. 7B, distortion occurs between the structural wall 2'and the first beam structure 4 and between the structural wall 2'and the second beam structure 6 due to ground changes, aging, and the like. May occur. Specifically, for example, when the second beam structure 6 moves horizontally to the right with respect to the first beam structure 4, the structure wall 2'is deformed so as to have a substantially parallelogram in front view, and the structure wall 2'is deformed into a substantially parallelogram. Along with this, the tubular body 25 moves in a direction away from the rod-shaped body 26. In this way, the tubular body 25 is separated from the rod-shaped body 26 and the joint bolt 8'extends, so that the connection portion between the joint bolt 8'and the structural wall 2'is not damaged, and the structural wall 2 'Can be transformed.

At this time, as shown in FIG. 8B, with the deformation of the structural wall 2', a force for moving the drift pins 21 in the shear metal fitting 10'to the right also acts, and each drift pin 21 is slit. 10d, 10e, 10f, ... And the right wall portion constituting the guide slit 10g are pressed against each other, and the drift pins 21 of the slits 10d, 10e, 10f, ... Are moved up and down with the drift pin 21 of the guide slit 10g as a rotation fulcrum. A force that moves in the direction acts. Specifically, the drift pin 21 arranged on the right side of the guide slit 10g moves downward along the slits 10d, 10e, 10f, and the drift pin 21 arranged on the left side of the guide slit 10g is the slit 10d, It moves upward along 10e and 10f.

As described above, since the body portion of the drift pin 21 is arranged in the slits 10d, 10e, 10f, ... Formed in the insertion plate portion 10c'of the shear metal fitting 10'and the guide slit 10g, the structural wall 2'and It is possible to regulate the relative movement in the horizontal direction with the first beam structure 4.

Further, as shown in FIG. 7 (c), when the second beam structure 6 moves horizontally to the right with respect to the first beam structure 4 from the state of FIG. 7 (b), the tubular body 25 Further moves in the direction away from the rod-shaped body 26, and the left bottom surface of the structural wall 2'is tilted so as to be separated from the upper surface of the first beam structure 4.

At this time, as shown in FIG. 8C, the drift pins 21 of the slits 10d, 10e, 10f, ... A force that moves it in the vertical direction acts. Specifically, the drift pins 21 arranged in the slits 10d, 10e, 10f arranged on the left side of the guide slit 10g can escape upward from the opening above the slits 10d, 10e, 10f. Further, the drift pin 21 arranged in the slit 10d arranged on the rightmost side comes into contact with the start end 10j of the slit 10d, and the movement of each drift pin 21 is restricted.

In this embodiment, a mode in which the drift pins 21 of the slits 10d, 10e, 10f, ... Move in the vertical direction with the drift pin 21 of the guide slit 10g as a rotation fulcrum is illustrated, but the structural wall 2'and the first The drift pin 21 of the guide slit 10g may move in the vertical direction depending on the state of relative movement with the beam structure 4 or the deformation state of the structural wall 2'. Even in this case, since the vertical dimension L2 of the guide slit 10g is longer than the vertical dimension L1 of the slits 10d, 10e, 10f, ..., It is difficult for the drift pin 21 to come out of the guide slit 10g. ..

As described above, the shear metal fittings 10'are arranged on the opening side of the recess 2b'formed in the structural wall 2'and fixed to the first beam structure 4 with the foundation portion 10b'and the foundation portion 10b'. A plate-shaped insertion plate portion 10c'extended from the recess 2b'toward the inside is provided, and the insertion plate portion 10c'has a body of a drift pin 21 pierced in the structural wall 2'in the front-rear direction. A plurality of slits 10d, 10e, 10f, ... In which the portions are arranged are provided in the left-right direction, and the slits 10d, 10e, 10f, ... Are the opposite ends of the base portion 10b'in the vertical direction of the insertion plate portion 10c'. The edges are open and formed. According to this, since the drift pins 21 are arranged in the slits 10d, 10e, 10f, ..., It is possible to regulate the relative movement of the structural wall 2'and the first beam structure 4 in the horizontal direction. .. In addition, the slits 10d, 10e, 10f, ... Are open to the opposite edge of the base portion 10b'in the vertical direction of the insertion plate portion 10c', and the drift pin can move in the vertical direction in the slit. Since it is allowed, it is open to the opposite edge of the base portion 10b', and the drift pin 21 is allowed to move in the vertical direction in the slits 10d, 10e, 10f, ... Therefore, it drifts. The stress generated between the pin 21 and the hole 2c'of the structural wall 2'through which the drift pin 21 is pierced can be suppressed, and the wooden structural wall 2'can be effectively prevented from being damaged.

Specifically, since the building structure 1 is configured by connecting the wooden structural wall 2'and the first metal beam structure 4, the structural wall 2'and the first structural wall 2'due to changes in the ground and aging. 1 When a distortion occurs between the beam structure 4 and the wooden structure wall 2', the building structure 1 can be prevented from being damaged due to a large deformation.

Further, the structural wall 2'is connected to the first beam structure 4 by a stretchable joint bolt 8', and when the structural wall 2'is deformed, the joint bolt 8'extends in accordance with the deformation. The deformation allowance of the structural wall 2'can be increased, and damage to the building structure 1 can be effectively prevented.

Further, when the structural wall 2'is significantly deformed, it is inserted into the slits 10d, 10e, 10f, ... Of the insertion plate portion 10c'of the shear metal fitting 10', through the hole 2c'that penetrates the structural wall 2'front and back. Since the body of the drift pin 21 is arranged, the structural wall 2'and the first beam structure are caused by the shear stress acting between the structural wall 2'and the first beam structure 4 when the structural wall 2'is deformed. It is possible to restrict the relative movement of 4 and 4 in the horizontal direction. Here, since the slits 10d, 10e, 10f, ... Are open upward, when the structural wall 2'is greatly deformed, the drift pin 21 moves upward and the slits 10d, 10e, 10f, ... Since it can be pulled out from the upper opening, the stress generated between the drift pin 21 and the hole 2c'of the structural wall 2'through which the drift pin 21 is pierced can be suppressed, and the wooden structural wall 2'is effectively damaged. Can be prevented.

That is, by significantly deforming the structural wall 2'with respect to the first beam structure 4, damage to the building structure 1 is prevented, and damage to the connection portion between the structural wall 2'and the first beam structure 4 is prevented. Therefore, the durability of the building structure 1 can be substantially improved.

Depending on the state of relative movement between the structural wall 2'and the first beam structure 4 and the deformation state of the structural wall 2', the slits 10d, 10e, 10f, ... It may rise or fall, but even in this case, since each drift pin 21 is allowed to move in the vertical direction, stress is applied between the drift pin 21 and the hole 2c'of the structural wall 2'. Can be prevented from occurring.

Further, since the slits 10d, 10e, 10f, ... Are formed so as to extend in the vertical direction, the relative movement of the structural wall 2'and the first beam structure 4 in the horizontal direction can be reliably regulated. At the same time, when the structural wall 2'and the first beam structure 4 move relative to each other, the drift pins 21 come into contact with the slits 10d, 10e, 10f, ... Evenly. In other words, since stress is not concentrated on one drift pin 21, damage to the drift pin 21 and the wooden structural wall 2'can be prevented.

Further, the start ends 10j of the slits 10d located at the left and right ends of the insertion plate portion 10c'are located closer to the base portion 10b' than the start ends 10k and 10m of the slits 10e and 10f located on the center side of the insertion plate portion 10c'. The drift pin 21 is separated from the starting end 10j side of the slit 10d. Specifically, each drift pin 21 is arranged at a substantially central portion in the vertical direction of each slit 10d, 10e, 10f, ... In a normal state. According to this, when the structural wall 2'and the first beam structure 4 move relative to each other, a large movement allowance of the drift pins 21 arranged in the slits 10d at both left and right ends having a large vertical movement width is secured. be able to.

Further, the plurality of slits 10d, 10e, 10f, ... Are formed so that the starting ends 10j, 10k, 10m are separated from the base portion 10b'as the insertion plate portions 10c'approaching from the left and right ends toward the center side. Specifically, the start end 10j of the slit 10d is arranged at the position P1 closest to the base portion 10b', and the start end 10k of the slit 10e is arranged at the position P2 farther from the base portion 10b' than the position P1. The starting end 10m of 10f is arranged at a position P3 farther from the base portion 10b'from the position P2, and each drift pin 21 is located at a substantially central portion in the vertical direction of each slit 10d, 10e, 10f, ... In a normal state. Have been placed. According to this, since each drift pin 21 can be distributed and arranged in the vertical direction, it is not necessary to form the hole 2c'for installing each drift pin 21 in the horizontal direction of the structural wall 2', and the structure is not required. The strength of the wall 2'can be secured. Further, since the slits 10d, 10e, 10f, ... Can be configured with the minimum size according to the vertical movement width of each drift pin 21 when the structural wall 2'and the first beam structure 4 move relative to each other. , The strength of the insertion plate portion 10c'can be ensured.

Further, the edge of the insertion plate portion 10c'on the opposite side of the foundation portion 10b'is formed in an arc shape, and the drift pin 21 is formed in each slit 10d due to the relative movement between the structural wall 2'and the first beam structure 4. , 10e, 10f, ..., The drift pin 21 is unlikely to interfere with the edge of the insertion plate portion 10c'when the relative movement between the structural wall 2'and the first beam structure 4 converges. In addition, since the edges (corners) on the opening side of the slits 10d, 10e, 10f, ... Are formed in a curved surface, it is easy to smoothly return to the slits 10d, 10e, 10f, ....

Although examples of the present invention have been described above with reference to the drawings, the specific configuration is not limited to these examples, and any changes or additions within the scope of the gist of the present invention are included in the present invention. Is done.

For example, in the above embodiment, the slits 10d, 10e, 10f, ... Are formed by extending in the vertical direction. For example, each slit is inclined or arcuate toward the central portion in the left-right direction of the insertion plate portion. May extend to.

Further, in the above embodiment, three slits 10d, 10e, 10f, ... Are formed on each of the left and right sides of the guide slit 10g, but the number of slits can be freely changed. Further, when a plurality of slits are provided, the configuration of the guide slits may be omitted.

Further, in the above embodiment, the form in which the structural wall 2 is fixed to the first beam structure 4 via the first slab 3 is illustrated, but the present invention is not limited to this, and for example, the structural wall 2 is the first in the top view. It may be fixed to the first slab 3 at a position deviated from the beam structure 4 in the front-rear direction or the left-right direction.

Further, in the above embodiment, the first beam structure 4 is mainly exemplified as the structure to which the shear hardware 10, 10'is fixed, but the structure is the first slab 3, the second slab 5, or the like. It may be a beam used for a frame construction method, a ramen construction method, or the like. That is, the structure may be any structure to which the structural walls are connected.

Further, in the above embodiment, the first beam structure 4 is a frame body in which a plurality of H-shaped steels 41 to 48 are integrally connected, but the H-shaped steels 41 to 48 have the first slab 3. The H-shaped steels 41 to 48 may not be directly connected to each other as long as they are integrally connected to each other. The H-shaped steels 41 to 48 may be individually fixed to the first slab 3, or after the H-shaped steels 41 to 48 are integrated to form the first beam structure 4, the first slab 3 is formed. The first beam structure 4 may be fixed to the.

Further, in the above-described embodiment, the structural walls 2 and 2'are composed of a thick plate laminated lumber having a thickness of 150 mm, but the present invention is not limited to this, and for example, a plurality of plates are laminated so that the fiber directions are orthogonal to each other. It may be composed of glued laminated lumber (so-called Cross Laminated Timber (CLT)). According to this, since the structural walls 2 and 2'are composed of CLT having high strength while allowing deformation such as bending, the structural wall 2'is damaged even if the structural wall 2'is greatly deformed. Can be prevented.

Further, in the above embodiment, the embodiment in which the first slab 3 and the second slab 5 and the like are supported only by the structural wall 2 is illustrated, but columns and the like may be arranged as an auxiliary.

Further, in the above embodiment, the first slab 3 and the second slab 5 are composed of a plurality of thick plate laminated materials 31, 31', but the structural slab plate may be composed of one plate material.

Further, in the above embodiment, the metal beam has been described as an H-shaped steel, but the present invention is not limited to this, and for example, an L-shaped steel or a channel steel may be used, and a hollow or solid prismatic beam material may be used. And so on.

1 Building structure 2, 2'Structural wall 3 1st slab 4 1st beam structure (structure)
5 2nd slab 6 2nd beam structure (structure)
10,10'Shear hardware (connecting metal fittings)
10b, 10b'Foundation part 10c, 10c' Insertion plate part 10d-10f Slit 10g Guide slit 10j-10n Start end 21 Drift pin 41-48 H-section steel

Claims (5)

It is a connecting metal fitting that connects a flat wooden structural wall that stands up in the vertical direction and a structure that is arranged orthogonally to the structural wall.
The connection fittings are a base portion arranged on the opening side of a recess formed in the structural wall and fixed to the structure, and a plate-shaped insertion plate portion extending from the foundation portion toward the inside of the recess. And with
The insertion plate portion is provided with a plurality of slits in the left-right direction in which the body portions of the drift pins pierced in the front-rear direction are arranged in the structural wall.
The slit is a building structure characterized in that the edge on the opposite side of the foundation portion in the vertical direction of the insertion plate portion is open. The building structure according to claim 1, wherein each of the slits is formed so as to extend in the vertical direction. The starting ends of the slits located at the left and right ends of the insertion plate portion are located on the base portion side as compared with the starting ends of the slits located on the center side of the insertion plate portion, and the drift pin is located on the slit. The building structure according to claim 1 or 2, wherein the building structure is separated from the starting end side. The building structure according to claim 3, wherein the plurality of slits are formed so that their starting ends are separated from the foundation portion as they approach the center side from the left and right ends of the insertion plate portion. The building structure according to any one of claims 1 to 4, wherein the edge of the insertion plate portion on the opposite side of the foundation portion is formed in an arc shape.

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