JP6180985B2 - Bearing wall structure - Google Patents

Description

  The present invention relates to a load-bearing wall structure of a building.

In a conventional roof structure of a wooden building, a ridge beam is provided at the highest position of the roof structure, and a girder beam is provided in parallel with the ridge beam. A plurality of purlins are provided in parallel with these ridge beams and girder beams with a predetermined interval (for example, Patent Document 1).
In buildings, bearing walls with the ability to resist horizontal loads (side forces) such as earthquakes and winds are attached to the frame with braces, or nail surface boards (boards) such as structural plywood. It is made by hitting with etc. In the bearing wall on the wife side of a building, regardless of whether the bracing or the face material is used, the bracing or the lower end of the face material is usually fixed to the base or floor beam, and the upper end is fixed to the shed beam or the like.

JP-A-5-148935

Bearing walls that support the force (horizontal force) from the side of a building, such as rolling during an earthquake or strong wind from a typhoon, have become increasingly important to improve earthquake resistance. It is necessary to secure what you have. However, if the bearing wall is made strong, there is a problem that it is difficult to secure an opening space such as a window and the comfort of the building may be impaired.
In particular, in recent years, in order to improve the indoor landscape, there is a desire to omit the ceiling surface and shed beam surface on the top floor and to widen the space above the room on the top floor. In such a case, the strength and rigidity of the member constituting the roof are not sufficient even if trying to extend and fix the braces and face materials for providing the bearing wall without providing the shed beam to the member constituting the roof, There is a problem that sufficient rigidity as a bearing wall cannot be obtained.

The invention described in claim 1 has been made in view of the above-described problems of the prior art, and the object is to reinforce the rafters and secure a sufficiently rigid roof construction surface, An object of the present invention is to provide a load-bearing wall structure that can improve the earthquake resistance by increasing the rigidity of the load-bearing wall, is economical, can secure a large indoor space, and has improved building comfort.
The invention according to claim 2 is a load-bearing wall that can function as a load-bearing wall by providing a brace in addition to the object of the invention according to claim 1 and further constitute a stronger load-bearing wall. The purpose is to provide a structure.

In addition to the object of the invention described in claim 2, the invention described in claim 3 provides a bearing wall structure that can make the bracing member common and can be made more economical. The purpose is to provide.
In addition to the object of the invention described in claim 2, the invention described in claim 4 can use a bracing member in common and can be made more economical. The purpose is to provide.
In addition to the object of the invention described in claim 1, the invention described in claim 5 is capable of suppressing the concentration of load and capable of providing a load-bearing wall having excellent earthquake resistance. The purpose is to provide.

(Claim 1)
The invention according to claim 1 is a load bearing wall structure provided in parallel with the rafter 70 spanned between the master beam 30, the purlin 50 and the girder beam 40, and is formed on the lower surface of at least a part of the rafter 70. A reinforcing member 60 along the rafter 70 is fixed, a plurality of columns 120 reaching the reinforcing member 60 are provided, and a load bearing material 200 reaching the reinforcing member 60 is provided between the adjacent columns 120. It is characterized by that.
The load bearing material 200 includes both the bracing 220 and the face material (wall surface material 240).

In the present invention, the reinforcing member 60 is fixed to the lower surface of at least a part of the rafter 70 along the rafter 70, so that the rafter 70 and the reinforcing member 60 are constrained (reinforced), and both are integrated. By doing so, the rigidity of the rafter 70 and the reinforcing member 60 is increased, and deformation and movement of the rafter 70 and the reinforcing member 60 are suppressed.
The roof construction surface can be constituted by the master beam 30, the main building 50 and the girder beam 40, the rafter 70 spanned between them, and the reinforcing member 60 on the lower surface thereof. Since the rafter 70 is fixed by the reinforcing member 60, the rafter 70 and the reinforcing member 60 can be integrated into a highly rigid roof construction surface, and the earthquake resistance can be improved.

Of the plurality of pillars 120 reaching the reinforcing member 60, the load-bearing material 200 reaching the reinforcing member 60 is provided between the adjacent pillars 120, so that the space between the adjacent pillars 120 can be used as a bearing wall. Since the rafter 70 and the reinforcing member 60 are fixed and integrated with each other, the rigidity of the load bearing material 200 reaching the reinforcing member 60 can be increased.
Further, in the present invention, the rafter 70 and the reinforcing member 60 are fixed to increase the rigidity of the roof construction surface, thereby ensuring a sufficiently high horizontal construction surface. Then, the load-bearing wall is provided by allowing the load-bearing material 200 to reach the reinforcing member 60 of the roof construction surface with increased rigidity. This makes it possible to reduce or omit other structures for increasing the rigidity of the horizontal surface (for example, a fire beam, a hut beam, etc.). It is not necessary to fix the load-bearing material 200 to another structure provided at a position lower than the reinforcing member 60 on the roof construction surface, which is economical and makes it possible to make the indoor space clean and large.

(Claim 2)
The invention described in claim 2 is characterized in that, in addition to the feature of the invention described in claim 1, the load bearing member 200 is a brace 220.
In the present invention, the load-bearing material 200 between the adjacent columns 120 is a brace 220, so that a triangulation structure is formed inside the adjacent columns 120 to suppress deformation when subjected to a horizontal force such as an earthquake. Thus, the space between adjacent pillars 120 can function as a load bearing wall. Further, the brace 220 reaches the reinforcing member 60 fixed to the lower surface of the rafter 70. Since the rafter 70 and the reinforcing member 60 are integrated to enhance rigidity, a stronger bearing wall can be configured.

Here, the bracing 220 includes a member in which two members are provided in a cross shape (shaking) between adjacent columns 120, but only one member is provided diagonally between adjacent columns 120. Included.
(Claim 3)
The invention described in claim 3 is characterized by the following points. That is, a bearing wall structure provided in parallel with the rafter 70 spanned between the master beam 30, the purlin 50 and the girder 40, and along the rafter 70 on the lower surface of at least a part of the rafter 70 A reinforcing member 60 is fixed, and a plurality of pillars 120 reaching the reinforcing member 60 are provided. A spacer member 260 having a horizontal side 270 is fixed to the lower surface of the reinforcing member 60, and between the adjacent pillars 120. A brace 220 is provided as the load-bearing material 200, and the upper end of the brace 220 is fixed to the horizontal side 270.

In the present invention, when the brace 220 is provided with two members in a cross-like shape between the adjacent columns 120, the upper end of the brace 220 is fixed to the horizontal side 270 of the spacer member 260. The thing of the same length can be used.
In addition, when only one brace 220 is provided obliquely, it is possible to cope with a member having the same length even in a case where the diagonal direction is changed depending on the strength design.
As a result, the members of the brace 220 can be made common and more economical.

(Claim 4)
The invention described in claim 4 has the following features in addition to the features of the invention described in claim 2 described above. That is, the reinforcing member 60 has a horizontal side 270, and the upper end of the brace 220 is fixed to the horizontal side 270.
In the present invention, in the case where two braces 220 are provided in a cross shape (shaking shape) between adjacent columns 120, the upper end of the brace 220 is fixed to the horizontal side 270 of the reinforcing member 60, so that the same length is obtained. Can be used.

In addition, when only one brace 220 is provided obliquely, it is possible to cope with a member having the same length even in a case where the diagonal direction is changed depending on the strength design.
This makes it possible to share the members of the brace 220, and it is not necessary to prepare and manage the brace 220 members having different lengths, and it is necessary to prepare and fix a special separate member (for example, the spacer member 260). Therefore, construction on site can be simplified and made more economical.
(Claim 5)
The invention described in claim 5 has the following characteristics in addition to the characteristics of the invention described in claim 1 described above. That is, the load-bearing material 200 is a face material (specifically, a wall surface material 240).

  In the present invention, by using the load bearing material 200 as a face material (wall surface material 240), the force applied to the load bearing material 200 due to an earthquake or the like can be dispersed on the sides of the face material (wall surface material 240). As a result, it is possible to suppress the concentration of the load as compared with the bracing 220, and it is possible to provide a load-bearing wall having excellent earthquake resistance.

Since this invention is comprised as mentioned above, there exists an effect as described below.
According to the first aspect of the present invention, a portion of the rafter is reinforced by the reinforcing member to secure a sufficiently rigid roof construction surface, and the bearing wall is provided to the reinforcing member, thereby increasing the rigidity of the bearing wall. Thus, it is possible to provide a load-bearing wall structure that can improve earthquake resistance, is economical, can secure a large indoor space, and can improve the comfort of the building.
According to the invention described in claim 2, in addition to the effect of the invention described in claim 1, the bracing is provided as the load-bearing material, so that deformation when subjected to horizontal force can be suppressed and adjacent. The space between the columns functions as a load-bearing wall, and this bracing can form a stronger load-bearing wall because the rafter and the reinforcing member are integrated into the reinforcing member with increased rigidity. It is possible to provide a simple bearing wall structure.

According to the third aspect of the present invention, in addition to the effect of the second aspect of the present invention, the bracing member can be used in common and can be made more economical. Can be provided.
According to the invention described in claim 4, in addition to the effect of the invention described in claim 2, the bracing member can be used in common and can be made more economical. Structure can be provided.
According to the invention described in claim 5, in addition to the effect of the invention described in claim 1, the load bearing wall that can suppress the concentration of load and can provide a bearing wall excellent in earthquake resistance. Structure can be provided.

It is a 1st embodiment of the present invention, and is a schematic perspective view of a building which has a load-bearing wall structure. It is a 1st embodiment of the present invention, and is a top view of a roof structure which has a frame and a reinforcing face material. FIG. 3 is a cross-sectional view of the first embodiment of the present invention taken along line AA in FIGS. 1 and 2. FIG. 3 is a BB cross-sectional view of the first embodiment of the present invention shown in FIGS. 1 and 2. It is the 1st Embodiment of this invention, Comprising: It is a right view of the building which has a load-bearing wall structure using a brace. It is the 2nd Embodiment of this invention, Comprising: It is a right view of the building which has a load-bearing wall structure using a spacer member and a brace. It is the 3rd Embodiment of this invention, Comprising: It is a right view of the building which has a load bearing wall structure using the reinforcement member with a horizontal side. It is the 4th Embodiment of this invention, Comprising: It is a right view of the building which has a load-bearing wall structure using a face material (wall surface material). It is the 5th Embodiment of this invention, Comprising: It is a right view of the building which has a load-bearing wall structure using a spacer member and a brace. It is the 5th Embodiment of this invention, Comprising: It is a left view of the building which has a load-bearing wall structure using a spacer member and a brace.

(First embodiment)
The bearing wall structure in the present embodiment can be applied to the bearing wall in the wooden building 10.
As shown in FIG. 1, in the present embodiment, the roof is a so-called single-flow roof that is inclined so that the height gradually increases from one end to the other end. The horizontal member 20 as a horizontal member provided at the lowest position in the roof structure is a girder 40, and the horizontal member 20 as a horizontal member provided at the highest position in the roof structure is provided. , Master Building 30. In the present embodiment, the slope of the roof is “0.5 / 10”.

For convenience, the wall surface of the building 10 with the master beam 30 is the front surface of the building 10, the wall surface of the beam beam 40 is the rear surface, and the right side wall surface when viewed from the front of the building 10 is the right side surface (Fig. 1), the left side wall as viewed from the front of the building 10 is the left side (right side in FIG. 1).
In the present embodiment, the building 10 includes a foundation (not shown) placed on the ground and a base 15 placed on the foundation and fixed to the foundation with anchor bolts. The base 15 is provided along the outer wall line of the building 10, and a plurality of pillars 120 are erected on the base 15.

A plurality of pillars 120 are arranged on the outer wall line of the building 10, and a girder beam 40 as a horizontal member 20 is bridged horizontally along the outer wall line on the back side (front side) on these pillars 120. Yes. Further, a master beam 30 as a horizontal member 20 is bridged horizontally along the outer wall line on the front side (back side).
In addition, a purlin 50 is provided between the beam 40 and the ridge beam 30 in parallel with these, that is, horizontally. The number of purlins 50 is not limited to this, and two or more purlins may be provided.
A rafter 70 is bridged between the plurality of horizontal members 20 so as to be orthogonal to the horizontal members 20 (the master beam 30, the main building 50 and the girder beam 40) along the slope of the roof.

Climbing beams 61 as a plurality of reinforcing members 60 along the rafters 70 are fixed to some lower surfaces of the plurality of rafters 70.
Specifically, climbing beams 61 are provided as reinforcing members 60 that are obliquely passed from the master beam 30 toward the purlin 50 and the beam 40. The climbing beam 61 is provided along the slope of the roof described above. Specifically, three climbing beams 61 are provided from the master beam 30 to the girder beam 40, and one climbing beam 61 is provided from the master beam 30 to the purlin 50. These climbing beams 61 are orthogonal to the horizontal member 20 (the master beam 30, the main building 50, and the girder beam 40).

At the place where the climbing beam 61 as the reinforcing member 60 is provided, the lower surface of the rafter 70 is fixed to the upper surface of the climbing beam 61 with nails. The other rafters 70 are arranged so as to be placed on the master beam 30, the main building 50 and the girder beam 40, and are fixed to the horizontal members 20 with nails at positions intersecting with the horizontal members 20, respectively. Yes.
On the rafter 70, a field board 130 is provided as a face material (see FIGS. 3 and 4). The base plate 130 is arranged so as to straddle a plurality of rafters 70 and is fixed to the rafters 70. Although not particularly illustrated, a waterproof sheet and a roof surface material are provided on the base plate 130.

A frame 80 is formed in the four sides of a space surrounded by the plurality of horizontal members 20 and the plurality of reinforcing members 60 on a part of the roof near the left side surface and the front corner of the building 10. The frame 80 is formed in a frame shape on one side of the wife in the four sides of a space surrounded by the master beam 30 and the main building 50 as the horizontal members 20 and the two climbing beams 61 (reinforcing members 60). When viewed from above, it is formed in a square shape. The frame body 80 is fixed to the master beam 30, the purlin 50, and the two climbing beams 61 by nails. Further, three reinforcement receiving members 110 parallel to the master beam 30 and the main building 50 are passed into the frame body 80.
Reinforcing surface members 90 (shaded portions in FIG. 1) are fixed to the lower surfaces of the frame body 80 and the reinforcing receiving member 110 with nails. Specifically, two rectangular reinforcing face members 90 are arranged side by side and fixed so as to block the square opening portion of the frame body 80 as a whole (see FIG. 2). The reinforcing face member 90 is fixed to the horizontal member 20 (the building beam 30 and the main building 50) and the climbing beam 61 (the reinforcing member 60) via the frame body 80.

As shown in FIG. 2, the frame body 80 is a fastening member on the inner side surface surrounded by the two horizontal members 20 (the building beam 30 and the main building 50) and the two reinforcing members 60 (the climbing beam 61). It is fixed with nail as 280. The two reinforcing surface members 90 are fixed to the lower surface side of the frame body 80 with nails as fastening members 280.
The reinforcing face material 90 is fixed so as to close the lower surface side of the square-shaped frame body 80 using two rectangular pieces, but the shape of the reinforcing face material 90 is particularly limited to this. It is not a thing. One square face material that matches the square opening on the lower surface side of the frame 80 may be used, and three or more rectangular face materials may be arranged side by side and fixed. is there.

Further, the fixing means (fastening member 280) to the horizontal member 20 (the building beam 30 and the main building 50) and the reinforcing member 60 (the climbing beam 61) of the frame body 80 is not limited to the nail but may be a screw. In addition, a mounting bracket that can fix both of them may be used.
Further, the fixing means (fastening member 280) of the reinforcing face member 90 to the frame body 80 is not limited to a nail, and may be a screw, or a mounting bracket that can fix both of them may be used. It ’s good.
As shown in FIG. 3, a frame body 80 is fixed to the side surface of the purlin 50 by a nail as a fastening member 280, and a reinforcing surface member 90 is fixed to a lower surface of the frame body 80 by a nail as a fastening member 280.

A rafter 70 is fixed to the upper surface of the main building 50 in a direction orthogonal to the main building 50. Further, on the upper surface of the purlin 50, a restraining member 100 that is provided between the rafters 70 to prevent movement and deformation of the rafters 70 is fixed by a nail as a fastening member 280. A ceiling edge 150 is fixed to the lower side surface of the main building 50, and a ceiling material 140 is fixed to the upper surface of the ceiling edge 150.
As shown in FIG. 4, a rafter 70 is fixed to the upper surface of the climbing beam 61 by a nail (fastening member 280). A frame body 80 is fixed to the side surface of the climbing beam 61 as the reinforcing member 60 by a nail (fastening member 280), and a reinforcing surface member 90 is fixed to the lower surface of the frame body 80 by a nail (fastening member 280). Between the rafters 70, a restraining member 100 as a so-called anti-rolling is fixed.

As shown in FIG. 5, in the right side view of the building 10 in FIG. 1 (viewed from the direction of arrow C in FIG. 1), the column 120 on the front side (building 30 side) of the building 10 and the center adjacent thereto A brace 220 as a load bearing material 200 that extends from the base 15 to the reinforcing member 60 (the climbing beam 61) is provided between the column 120 on the side (the main building 50 side).
This brace 220 (two members) is cross-shaped (chapter-shaped) on a trapezoidal diagonal line composed of two adjacent columns 120, a base 15, and a reinforcing member 60 (climbing beam 61). Is provided. Each member of the brace 220 is fixed to the base 15 and the pillar 120 by metal fittings (not shown) at the corners of the corners formed by the base 15 and the pillar 120 at the lower end. Further, each member of the brace 220 has a reinforcing member 60 (climbing beam) by a metal fitting (not shown) at a corner portion of a corner formed by the reinforcing member 60 (climbing beam 61) and the column 120 at the upper end. 61) and the column 120.

Note that the lengths of the two members of the brace 220 are different because the reinforcing member 60 (the climbing beam 61) is inclined.
The right side of the building 10 is formed with a wall, but the wall in the area where the bracing 220 is provided (the left half of FIG. 5) is a load-bearing wall, and the area where the bracing 220 is not provided (see figure). The wall on the right half of 5) is a non-bearing wall.
Further, the reinforcing member 60 is fixed to the lower surface of the rafter 70 on the right side of the building 10 with nails (fastening members 280).

The fixing of the upper end and the lower end of the braces is not limited to using the metal fitting (not shown), and may be fixed with nails, screws, or the like.
(Function and effect)
In the present embodiment, the reinforcing member 60 is fixed to the lower surface of a part of the rafter 70 along the rafter 70, so that the rafter 70 is restrained (reinforced) and the rigidity is increased, and the rafter 70 is not deformed or moved. It can be suppressed.
The roof is composed of a plurality of horizontal members 20 (building beam 30, purlin 50 and girder beam 40), a plurality of rafters 70 spanned between the plurality of horizontal members 20, and reinforcing members 60 (climbing beams 61) on the lower surface thereof. Part of the construction can be constructed. Since the rafter 70 is fixed by the reinforcing member 60, the rafter 70 and the reinforcing member 60 can be integrated into a highly rigid roof construction surface, and the earthquake resistance can be improved.

  The frame body 80 is formed in the four sides of a space surrounded by the plurality of horizontal members 20 (the building beams 30 and the main building 50) and the plurality of reinforcing members 60 (the climbing beams 61). By fixing the surface of the reinforcing surface member 90 to the end surface on the lower surface side of the frame body 80 and fixing it with a nail, both can be easily fixed. Further, a reinforcing surface member 90 is brought into contact with and fixed to the lower surface of the frame body 80 by using the frame body 80. For this reason, in the assembling work, even when the error in the dimensional accuracy of the mounting position of the horizontal member 20 and the reinforcing member 60 is large, when attaching the frame body 80, the reinforcing surface material 90 to the lower surface By adjusting the attachment position, it becomes possible to adjust the error, and the attachment of the reinforcing face material 90 can be facilitated.

Further, since the reinforcing surface member 90 is fixed to the lower surface of the frame body 80, the frame body 80 is restrained and deformation of the frame body 80 is suppressed. Accordingly, the plurality of horizontal members 20 and the plurality of reinforcing members 60 to which the frame body 80 is fixed are also restrained and deformation is suppressed, and as a result, the roof structure constituted by the horizontal members 20 and the reinforcing members 60 is configured. The rigidity of the surface can be further increased.
Further, a reinforcement receiving member 110 for receiving the reinforcing surface member 90 is passed inside the frame body 80. The reinforcement receiving member 110 can firmly fix the reinforcing surface member 90 and the frame body 80, and the frame body 80, the horizontal member 20 to which the frame body 80 is fixed, and the reinforcing member 60 (the climbing beam). The rigidity of 61) can be further increased.

  In the present embodiment, since the reinforcing member 60 (the climbing beam 61) is fixed to the lower surface of some of the rafters 70, the rigidity of the rafters 70 is increased, and deformation and movement of the rafters 70 are suppressed. As a result, it is possible to make the restraint member 100 as a so-called stopper for preventing deformation and movement of the rafter 70 lower than usual. Specifically, as shown in FIG. 3, sufficient restraint of the rafter 70 is ensured even when the restraining member 100 (anti-rolling) having a rectangular cross section is tilted sideways. As a result, the height from the lower end to the upper end of the cross-sectional shape of the restraining member 100 (anti-rolling) can be lowered, and the space between the restraining member 100 (anti-rolling) and the base plate 130 can be made larger than usual. As a result, the movement of the air behind the ceiling (black arrow in FIG. 3) can be improved, and the ventilation performance of the ceiling can be improved. Thereby, it is not necessary to provide a passage communicating for ventilation of the back of the ceiling, and the ceiling surface can be provided at a high position near the roof along the roof gradient. As a result, the indoor space can be increased by further increasing the ceiling height.

  Here, in the normal building 10, the horizontal construction surface is basically composed of both (1) the roof surface and (2) the ceiling surface or the roof beam surface. On the other hand, in the present embodiment, the horizontal construction surface having sufficiently high rigidity can be secured by the roof construction surface by the roof structure having high rigidity of (1), and the ceiling surface and the roof beam surface of (2) can be secured. A structure for securing a horizontal surface can be eliminated. Thereby, what protrudes to the indoor side, such as a fire beam, can be omitted, and the indoor space can be made a clean and large space without a protruding object such as a fire beam or a shed beam surface.

Furthermore, it demonstrates concretely. As shown in FIG. 5, in the present embodiment, among the plurality of columns 120 reaching the reinforcing member 60, the bracing 220 as the load bearing material 200 reaching the reinforcing member 60 is provided between the adjacent columns 120. The space between the adjacent columns 120 can be a bearing wall. Since the rafter 70 and the reinforcing member 60 are fixed and integrated with each other, the rigidity of the load bearing material 200 reaching the reinforcing member 60 can be increased.
In the present embodiment, the load bearing material 200 between the adjacent columns 120 is the brace 220, so that the rectangular structure configured by the adjacent columns 120, the reinforcing member 60 (the climbing beam 61), and the base 15 is provided. The structure of a trigonometer can be made in the interior of the chamber to prevent deformation when subjected to a horizontal force such as an earthquake, and the space between adjacent columns 120 can function as a bearing wall. Further, the brace 220 reaches the reinforcing member 60 fixed to the lower surface of the rafter 70. Since the rafter 70 and the reinforcing member 60 are integrated to enhance rigidity, a stronger bearing wall can be configured.

  In the present embodiment, the rafter 70 and the reinforcing member 60 are fixed to increase the rigidity of the roof construction surface, thereby ensuring a sufficiently high horizontal construction surface. Then, the bearing wall is provided by causing the bracing 220 as the load bearing material 200 to reach the reinforcing member 60 (climbing beam 61) of the roof construction surface with increased rigidity. Thereby, in order to make the rigidity of a horizontal construction surface high, the other structures (for example, a fire beam, a hut beam, etc.) provided in a position lower than a roof construction surface can be omitted. There is no need to fix the brace 220 as the load-bearing material 200 to another structure such as a roof beam provided at a position lower than the reinforcing member 60 of the roof construction surface, and it is economical and the indoor space is a clean and large space It becomes possible to do.

Here, the brace 220 is provided with two members in a cross shape (shaking) between the adjacent pillars 120, but is not necessarily limited to this. Only one member may be provided obliquely.
In the above-described embodiment, only three of the plurality of rafters 70 are provided with the reinforcing member 60 (the climbing beam 61) and the rafter 70 and the reinforcing member 60 are fixed. However, the present invention is not particularly limited thereto. . One, two, or four or more reinforcing members 60 may be provided. The reinforcing members 60 may be provided every two rafters 70, every other rafter 70, or on every rafter 70. It may be.

Further, the climbing beam 61 is used as the reinforcing member 60. However, the reinforcing member 60 is not limited to the climbing beam 61, as long as it can fix the rafter 70 and increase the rigidity of the rafter 70. Other members having other shapes than the climbing beam 61 may be used.
The reinforcing member 60 is not limited to wood as long as the reinforcing member 60 is fixed to the rafter 70 and can increase the rigidity of the rafter 70, and is a metal fitting that can be fixed along the rafter 70. Also good.
In the embodiment described above, only one frame body 80 is provided in a very small area of about one-sixth of the entire roof structure, and the reinforcing surface member 90 is provided on the lower surface of the frame body 80. However, the present invention is not limited to this, and a total of two pieces may be formed one at a corner on the diagonal line of the roof structure. Further, a total of four pieces may be formed at the four corners of the roof structure. In addition, the roof structure is divided into a plurality of grid-like regions, and the reinforcing face materials 90 are alternately arranged in a checkered pattern so that the reinforcing face materials 90 are not provided at positions adjacent to each side of the reinforcing face material 90. It may be. Further, the frame body 80 and the reinforcing face material 90 may be provided in all parts of the roof structure.

(Second Embodiment)
In the present embodiment, FIG. 6 is used instead of FIG. 5 of the first embodiment.
In the first embodiment, as shown in FIG. 5, the brace 220 as the load-bearing material 200 is directly fixed to the lower portion of the reinforcing member 60 disposed obliquely along the rafter 70.
In the present embodiment, as shown in FIG. 6, a trapezoidal spacer member 260 having a horizontal side 270 is fixed to the lower surface of the reinforcing member 60, and the upper end of the brace 220 as the load-bearing material 200 is attached to the spacer member 260. It is fixed to the horizontal side 270.

In other words, the upper end of the brace 220 is fixed to the corner portion of the corner formed by the column 120 and the horizontal side 270 of the spacer member 260. The brace 220 is provided on a rectangular diagonal line constituted by two adjacent columns 120, the base 15, and the horizontal side 270 of the spacer member 260. The brace 220 is provided by two members in a cross shape (slapping shape), but since the lengths of the diagonal lines of the rectangle are the same, the lengths of the two members are also the same.
In the present embodiment, the upper ends of the two members of the brace 220 are fixed to the horizontal side 270 of the spacer member 260, so that the same length can be used. In addition, when only one brace 220 is provided obliquely, it is possible to cope with a member having the same length even in a case where the diagonal direction is changed depending on the strength design. Accordingly, the members of the brace 220 can be shared, and it is not necessary to prepare and manage the members of the brace 220 having different lengths.

The configuration, operation, and effects other than the use of the spacer member 260 described above are the same as those in the first embodiment, and a description thereof is omitted.
(Third embodiment)
In this embodiment, FIG. 7 is used instead of FIG. 5 of the first embodiment.
In the first embodiment, as shown in FIG. 5, the brace 220 is fixed to the lower end surface of the reinforcing member 60 disposed obliquely along the rafter 70, and the lower end surface of the reinforcing member 60 is also the rafter. It was tilted as well as 70 tilt.

In the present embodiment, as shown in FIG. 7, the reinforcing member 60 has a trapezoidal shape and has a horizontal side 270 on the lower end surface. The upper end of the brace 220 is fixed to the horizontal side 270 of the lower end surface of the reinforcing member 60.
That is, the upper end of the brace 220 is fixed to a corner portion having a corner shape constituted by the column 120 and the horizontal side 270 of the trapezoidal reinforcing member 60. The brace 220 is provided on a rectangular diagonal line formed by two adjacent columns 120, the base 15, and the horizontal side 270 of the trapezoidal reinforcing member 60. This brace 220 is provided by two members in a cross shape (slapping shape), but since the lengths of the diagonal lines of the rectangle are the same, the lengths of the two members are also the same. .

In the present embodiment, two members of the brace 220 having the same length can be used by fixing the upper ends of the two members to the horizontal side 270 of the reinforcing member 60. This makes it possible to share the members of the brace 220, and it is not necessary to prepare and manage the brace 220 members having different lengths, and it is necessary to prepare and fix a special separate member (for example, the spacer member 260). Therefore, construction on site can be simplified and made more economical.
Note that the configuration, operation, and effects other than the use of the trapezoidal reinforcing member 60 having the horizontal side 270 described above are the same as those in the first embodiment, and a description thereof will be omitted.

(Fourth embodiment)
In the present embodiment, FIG. 8 is used instead of FIG. 5 of the first embodiment.
In the first embodiment, as shown in FIG. 5, a load bearing wall is configured by using a brace 220 as the load bearing material 200.
In the present embodiment, as shown in FIG. 8, the load-bearing material 200 is configured with a load-bearing wall by using a face material (specifically, a wall surface material 240).
In the present embodiment, a wall surface material 240 that fills a trapezoidal space region composed of two adjacent pillars 120, a base 15, and a reinforcing member 60 that is obliquely fixed to the lower surface of the rafter 70 is fixed. It is what has been. That is, the lower side of the wall material 240 is fixed to the base 15, one side of the wall material 240 is fixed to the left column 120, the other side of the wall material 240 is fixed to the right column 120, The upper side of the material 240 is fixed to the lower end of the reinforcing member 60. Although not particularly shown, each side is fixed by a nail. Of course, the fixing means is not limited to the nail, and may be another fastening member 280 such as a screw, or may be fixed by a metal fitting or the like.

In the present embodiment, since the load bearing material 200 is a face material (wall surface material 240), the force applied to the load bearing material 200 due to an earthquake or the like can be distributed over the entire length of each side of the wall surface material 240. The load concentration can be suppressed as compared with the case where the bracing 220 is used as 200, and a bearing wall excellent in earthquake resistance can be provided.
The configuration, operation, and effects other than using the face material described above as the load-bearing material 200 instead of the brace 220 are the same as those in the first embodiment, and a description thereof is omitted.
(Fifth embodiment)
In the first to fourth embodiments described above, it is applied to a one-story building 10, but in this embodiment, a two-story building is used as shown in FIGS. 9 and 10. It is applied to building 10.

In the present embodiment, the climbing beam 61 as the reinforcing member 60 is fixed to the lower surface of the rafter 70 of the inclined roof on the second floor. A plurality of columns 120 reaching the reinforcing member 60 is provided, and a brace 220 as a load bearing material 200 reaching the reinforcing member 60 is provided in a part between the adjacent columns 120.
In the first to fourth embodiments described above, the lower end of the load-bearing material 200 is fixed to the base 15, but in this embodiment, the load-bearing material 200 provided on the second floor wall is replaced with the base 15. It is fixed to the trunk difference 300 between the first floor and the second floor.

In the present embodiment, a spacer member 260 having a horizontal side 270 is fixed to the lower end of the reinforcing member 60 on the second-floor wall as in the second embodiment. A brace 220 as the load-bearing material 200 is fixed to a corner portion between the two.
In the second floor wall, the upper end of the load-bearing material 200 may be fixed to the lower end of the reinforcing member 60 that is inclined similarly to the first embodiment without providing the spacer member 260. Similarly to the embodiment, the reinforcing member 60 having the horizontal side 270 may be fixed to the lower end. Further, as in the fourth embodiment, the load bearing wall 200 may be composed of a face material (wall surface material 240) instead of the brace 220 as the load bearing material 200. Since their configurations, functions, and effects are the same as those described in each embodiment, their descriptions are omitted.

10 Building 15 Base
20 Horizontal member 30 Master beam
40 Girder 50 Purlin
60 Reinforcement member 61 Climbing beam
70 Rafter 80 Frame
90 Reinforcement face material 100 Restraint member
110 Reinforced material 120 Column
130 Base plate 140 Ceiling material
150 Ceiling edge 200 Bearing material
220 Bracing 240 Wall material
260 Spacer member 270 Horizontal side
280 Fastening member 300

Claims (5)

It is a load-bearing wall structure provided in parallel with the rafters spanned between the master beam, purlin and girder beam,
A reinforcing member along the rafter is fixed to the lower surface of at least a part of the rafter,
A plurality of pillars reaching the reinforcing member are provided,
A load-bearing wall structure characterized in that a load-bearing material that reaches the reinforcing member is provided between the adjacent columns.   The load-bearing wall structure according to claim 1, wherein the load-bearing material is a brace. It is a load-bearing wall structure provided in parallel with the rafters spanned between the master beam, purlin and girder beam,
A reinforcing member along the rafter is fixed to the lower surface of at least a part of the rafter,
A plurality of pillars reaching the reinforcing member are provided,
A spacer member having a horizontal side is fixed to the lower surface of the reinforcing member,
A brace as a load bearing material is provided between the adjacent columns,
Resistant force wall structure you wherein the upper end of the brace is secured to said horizontal leg. The reinforcing member has a horizontal side,
The bearing wall structure according to claim 2, wherein an upper end of the bracing is fixed to the horizontal side.   The load-bearing wall structure according to claim 1, wherein the load-bearing material is a face material.