JP6860354B2 - Building structure - Google Patents

Description

The present invention relates to a building structure.

Conventionally, a technique for constructing a building having a skeleton formed of square tubular columns and beams is known (see, for example, Patent Document 1).
In this technique, columns and beams are joined by joint members such as rectangular column-beam joint metal fittings, column joint metal fittings, and beam joint metal fittings. In addition, the square tubular pillars and beams are arranged between the wooden squares arranged at the four corners of the pillars and beams and the adjacent squares, and four sets of wooden squares are stacked to connect the squares. It is configured with a building panel. Then, a relatively large-scale wooden building can be constructed by adopting such square tubular columns and beams and each metal joint.

Japanese Unexamined Patent Publication No. 2015-21287

In the technique described in Patent Document 1, on the side surface of a column-beam joint metal fitting arranged at an intersection on an extension line of a column and a beam, a column-beam joint metal fitting joined to the upper and lower end surfaces of the column-beam joint metal fitting, and a column-beam joint metal fitting. The beam joining hardware to be joined is a heavy one that is preferably used when constructing a large-scale building. Therefore, when constructing a small building such as a detached house or the upper floor part of a middle-high-rise building, the load applied to the building frame and the construction cost increase, and the structural strength is also over-engineered. It may become.

The present invention has been made in view of the above circumstances, and can reliably join columns and horizontal structures such as beams without using heavy metal joints as in the past, like a detached house. The purpose is to provide the optimum building structure for constructing the upper floors of small-scale buildings and middle- and high-rise buildings.

The invention according to claim 1 is formed by, for example, as shown in FIGS. 1 to 14, a pillar 3 and a horizontal structure (beam 8, floor slab 30, beam 80) attached to the pillar 3. In the building structure including the building frame 1
The pillars 3 (3A, 3B, 3C) are mainly composed of a shaft member 4 provided between the upper and lower floors and a plurality of hollow building panels 5 fixed along the shaft member 4. It is composed and
The plurality of building panels 5 are vertically stacked along the length direction of the shaft member 4, and the lower end surface of the building panel 5 above is in contact with the upper end surface of the building panel 5 below. It is in a state and
The shaft member 4 is a square lumber having a core that is not hollow, and support hardware 11 and 21 for supporting the horizontal structure are fixed to the shaft member 4.
The support hardware 11 and 21 have a plate-shaped fixing portion 12 fixed to the shaft member 4, a mounting portion 13 on which the horizontal structure is mounted, and the horizontal structure on the mounting portion 13. and the engaged portion 14 of the body engagement portion provided on the horizontal structure in mounted state is engaged, wherein the fixing unit 12, the side surface of the shaft member 4 of the pillar 3 It is bolted to any height position in
The horizontal structure is attached to the shaft member 4 of the pillars 3 via the support hardware 11 .
The engaged portion 14 is a plate-shaped portion provided from the fixed portion 12 to the mounted portion 13 and connecting the fixed portion 12 and the mounted portion 13.
The engaging portion includes a slit 9a provided at the lengthwise side end of the horizontal structure into which the engaged portion 14 is inserted, and the lengthwise side end of the horizontal structure and the slit 9a. It has a drift pin 16 that penetrates the engaged portion 14 inserted into the.
The support metal fitting 11 further includes a plate-shaped set metal fitting 15 provided while ensuring a gap for inserting the engaged portion 14 into the slit 9a.
The set hardware 15 is joined and fixed to the engaged portion 14 with bolts and nuts.
The drift pin 16 is characterized in that the set hardware 15 penetrates together with the lengthwise side end portion of the horizontal structure and the engaged portion 14.

According to the invention of claim 1, the pillar 3 is mainly composed of a shaft member 4 provided between the upper and lower floors and a building panel 5 fixed along the shaft member 4. Since the horizontal structure is attached to the shaft member 4 of the pillars 3, the horizontal structure can be attached to any position along the length direction of the shaft member 4. .. That is, since the horizontal structure is attached to the shaft member 4 instead of the hollow building panel 5, the mounting state is stable and strong, and the mounting location is the shaft member 4. It can be set arbitrarily along the length direction. Further, by providing the hollow building panel 5, the weight of the pillar 3 itself can be reduced. Further, since the horizontal structure is attached to the shaft member in this way, it is not necessary to use each heavy joint metal fitting as in the conventional case, and the load applied to the building frame 1 is not used because each joint metal fitting is not used. And costs can be reduced. Moreover, the structural strength of the building frame 1 does not become over-engineered, and it is most suitable for constructing a small-scale building such as a detached house or an upper floor portion of a middle-high-rise building.
Further, a support metal fitting 11 for supporting the horizontal structure is fixed to the shaft member 4, and since the horizontal structure is attached to the shaft member 4 via the support metal fitting 11, the shaft member 4 is attached. The horizontal structure can be attached to the shaft member 4 without interruption between the upper and lower floors. Therefore, the upper and lower floors of the building skeleton 1 can be structurally integrated by the shaft member 4 provided between the upper and lower floors, so that the proof stress of the building skeleton 1 can be improved.

Further , in a state where the support hardware 11 is fixed to the shaft member 4, the horizontal structure is mounted on the fixed portion 12, the mounted portion 13 on which the horizontal structure is mounted, and the horizontal structure is mounted on the mounted portion 13. Since the engaging portion 14 with which the engaging portion provided on the horizontal structure is engaged is provided, the horizontal structure is mounted on the mounting portion 13 and the engaging portion is engaged with the engaged portion 14. By combining them, the horizontal structure mounted on the mounting portion 13 can be easily and stably supported by the supporting hardware 11.

Further , by using the set metal fitting 15, not only the horizontal structure (shaft member 9) and the engaged portion 14 are joined to each other, but also the set metal fitting 15 and the horizontal structure are joined to each other, and the set metal fitting 15 and the engaged portion 14 are engaged with each other. Since the portions 14 can also be joined to each other, the joining strength between the horizontal structure and the supporting hardware 11 can be improved.

According to a second aspect of the invention, for example 6, 8, 11 to 14, in the building structure according to claim 1,
A recess (recess 9b, recess 82) with which the mounting portion 13 matches is formed on the lower surface of the horizontal structure.
The lower surface of the horizontal structure and the lower surface of the mounting portion 13 are flush with each other in a state where the mounting portion 13 is aligned with the recess.

According to the second aspect of the present invention, the lower surface of the horizontal structure and the lower surface of the mounting portion 13 are flush with each other in a state where the mounting portion 13 is aligned with the recess formed on the lower surface of the horizontal structure. Therefore, when the horizontal structure is supported by the support hardware 11, the lower surface of the horizontal structure does not protrude due to the mounting portion 13. Therefore, when a member such as a ceiling material is attached to the lower surface of the horizontal structure, it is not necessary to consider the protrusion, and the workability can be improved.

The invention according to claim 3 is, for example, as shown in FIGS. 1, 6, and 13, a column 3 and a horizontal structure attached to the column 3 (beam 8, floor slab 30, beam 80). In the building structure including the building frame 1 formed by
The pillars 3 (3A, 3B, 3C) are mainly composed of a shaft member 4 provided between the upper and lower floors and a plurality of hollow building panels 5 fixed along the shaft member 4. It is composed and
The plurality of building panels 5 are vertically stacked along the length direction of the shaft member 4, and the lower end surface of the building panel 5 above is in contact with the upper end surface of the building panel 5 below. It is in a state and
The shaft member 4 is a square lumber having a core that is not hollow, and support hardware 11 and 21 for supporting the horizontal structure are fixed to the shaft member 4.
The support hardware 11 and 21 are provided with a fixing portion 12 fixed to the shaft member 4, and the fixing portion 12 is said to have an arbitrary height position on the side surface of the shaft member 4 in the pillar 3. It is bolted in a state of protruding sideways from the side surface of the shaft member 4.
The horizontal structure is attached to the shaft member 4 of the pillars 3 via the support hardware 11.
On the side surface of the shaft member 4 of the horizontal structure (beam 80), the support metal fitting 21 is positioned above the support metal fitting 21 and protrudes toward the shaft member 4 side, and the horizontal structure is provided with the support metal fitting 21. It is characterized in that a protruding portion 83 that comes into contact with the shaft member 4 is provided in a state of being attached to the shaft member 4 via the shaft member 4.

According to the invention of claim 3 , the pillar 3 is mainly composed of a shaft member 4 provided between the upper and lower floors and a building panel 5 fixed along the shaft member 4. Since the horizontal structure is attached to the shaft member 4 of the pillars 3, the horizontal structure can be attached to any position along the length direction of the shaft member 4. .. That is, since the horizontal structure is attached to the shaft member 4 instead of the hollow building panel 5, the mounting state is stable and strong, and the mounting location is the shaft member 4. It can be set arbitrarily along the length direction. Further, by providing the hollow building panel 5, the weight of the pillar 3 itself can be reduced. Further, since the horizontal structure is attached to the shaft member in this way, it is not necessary to use each heavy joint metal fitting as in the conventional case, and the load applied to the building frame 1 is not used because each joint metal fitting is not used. And costs can be reduced. Moreover, the structural strength of the building frame 1 does not become over-engineered, and it is most suitable for constructing a small-scale building such as a detached house or an upper floor portion of a middle-high-rise building.
Further, a support metal fitting 11 for supporting the horizontal structure is fixed to the shaft member 4, and since the horizontal structure is attached to the shaft member 4 via the support metal fitting 11, the shaft member 4 is attached. The horizontal structure can be attached to the shaft member 4 without interruption between the upper and lower floors. Therefore, the upper and lower floors of the building skeleton 1 can be structurally integrated by the shaft member 4 provided between the upper and lower floors, so that the proof stress of the building skeleton 1 can be improved.
Further, since the column 3 and the horizontal structure (beam 80) are directly connected by the projecting portion 83, the force applied to the joint portion between the column 3 and the horizontal structure can be effectively dispersed. it can.

According to the present invention, columns and horizontal structures such as beams can be reliably joined without using heavy metal joints as in the past, and small-scale buildings such as detached houses and middle- and high-rise buildings can be joined. It is possible to provide an optimum building structure for constructing an upper floor part of an object.

It is a perspective view which shows the building frame. It is a perspective view which shows a pillar. It is sectional drawing which shows the pillar. It is a perspective view which shows the column base hardware. It is sectional drawing which shows the joint part of a column and a foundation. It is a perspective view which shows the joint part of a column and a beam. It is sectional drawing which shows the beam. It is an enlarged perspective view which shows the support hardware. It is a perspective view which shows the deformation example of a column. It is a perspective view which shows the deformation example of the joint part of a column and a beam. It is a perspective view which shows the support metal fitting in FIG. It is a perspective view which shows the support state of the beam by the support metal fitting in FIG. It is a perspective view which shows the joint state of a beam and a floor panel. It is a perspective view which shows the structure of the upper floor part in a middle-high-rise building.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, although the embodiments described below are provided with various technically preferable limitations for carrying out the present invention, the technical scope of the present invention is not limited to the following embodiments and illustrated examples. Absent.

In FIG. 1, reference numeral 1 indicates a building skeleton. The building skeleton 1 is constructed on the foundation 2, and is formed by a pillar 3 which is a vertical structure and a beam 8 which is a horizontal structure attached to the pillar 3.
The pillar 3 is erected on the upper surface of the foundation 2 so as to be located between the four corners of the building skeleton 1 and the pillars 3 and 3 at these four corners, and the beam 8 is constructed on the second floor of the building skeleton 1. It is provided so as to be bridged between the adjacent pillars 3 and 3 at the height position and the height position where the roof is constructed. As a result, the building frame 1 is in a state of being composed of a gate-shaped frame composed of columns 3 and beams 8. As shown in FIG. 1, the building frame 1 has a long span of the gate-shaped frame along the X direction and a short span of the gate-shaped frame along the Y direction.

The pillar 3 is mainly composed of a plurality of shaft members 4 and a plurality of building panels 5, and also includes a pillar base metal fitting 6 and a stigma metal fitting 7, and FIGS. Etc., it is formed in a square cylinder shape. Further, the pillar 3 is provided between the upper and lower floors, and functions as a through pillar having a large cross section and few defects.

The shaft member 4 is a long wooden material (so-called square timber) provided between the upper and lower floors, and is arranged at the four corners of the pillar 3. That is, the shaft member 4 also functions as a through pillar provided between the upper and lower floors. In other words, the pillar 3 functions as a through pillar by providing such a shaft member 4.
Further, the shaft member 4 has a connecting bolt 4a that protrudes from the lower end surface and is used for connecting to the column base metal fitting 6, and a metal reinforcing cap 4b provided on the lower end surface to reinforce the lower end surface. ..

The building panel 5 is a so-called wooden adhesive panel used for building a building such as a house. In the building panel 5, vertical and horizontal frame members are assembled in a rectangular shape, and auxiliary crosspieces are appropriately assembled inside the rectangular frame formed in this way to form a frame body 5a. The face material 5b is attached to both sides, and the structure is hollow inside. A heat insulating material such as glass wool or rock wool is loaded in the hollow portion inside. By using the hollow building panel 5 in this way, the weight of the pillar 3 can be reduced.
Further, in forming the pillar 3, a plurality of the building panels 5 are used, and the plurality of building panels 5 are vertically stacked along the length direction of the shaft member 4. It is fixed at 4.
Then, in the present embodiment, two upper and lower building panels 5 are provided so as to be stacked between the adjacent shaft members 4 and 4, and these adjacent shaft members 4 and 4 are connected to each other. .. That is, the main body portion (main portion as a pillar) of the pillar 3 in the present embodiment is formed by the shaft members 4 at the four corners and the upper and lower two building panels 5 provided on the four side surfaces of the pillar 3. It is in a state of being.

As shown in FIGS. 1 and 2, the column base metal fitting 6 is attached to the leg portion (lower end surface) of the column 3, and in the present embodiment, since the column 3 is joined to the foundation 2, the column 3 is integrated. It is used to enhance the sex.
As shown in FIG. 4, the column base metal fitting 6 includes four box-shaped metal fittings 6a arranged apart from each other in the front-rear and left-right directions, and four connecting members 6b for connecting the box-shaped metal fittings 6a to each other. It is formed in a shape.

The box-shaped metal fitting 6a is a rectangular plate member 60 formed in a square tubular shape and fixed to the upper and lower ends of the tubular member 60 by welding or the like so as to close the upper and lower end surfaces of the tubular member 60. It is composed of 61 and 61.
A rectangular opening 62 is formed on one side surface of the tubular member 60. Further, one through hole 63 is formed in the substantially central portion of the upper plate member 61, and a through hole 64 is also formed in the substantially central portion of the lower plate member 61.

The connecting member 6b is a channel steel having a web 65, an upper flange 66, and a lower flange 67, and connects the four box-shaped metal fittings 6a provided at the four corners of the column base metal fitting 6.
The upper surface of the upper flange 66 and the upper surface of the upper plate member 61 of the box-shaped metal fitting 6a are flush with each other, and the lower surface of the lower flange 67 and the lower surface of the lower plate member 61 of the box-shaped metal fitting 6a are flush with each other. It has become.
A plurality of screw holes are formed in the upper flange 66 at intervals in the length direction thereof, and screws can be driven into and fixed to the lower end surface of the building panel 5 in the pillar 3 in contact with the upper flange 66. It has become. Therefore, the lower flange 67 has a protrusion dimension from the web 65 set to be shorter than that of the upper flange 66, making it easier to drive screws.

In such a column base metal fitting 6, as shown in FIG. 5, four connecting bolts 4a protruding from the lower end surfaces of the four shaft members 4 in the column 3 are attached to the upper plate member 61 in each tubular member 60. The reinforcing cap 4b is brought into contact with the upper surface of the box-shaped metal fitting 6a, and then the nut is screwed into the connecting bolt 4a and tightened.
Further, the lower end surface of the building panel 5 of the pillar 3 is brought into contact with the upper surface of the upper flange 66 of the connecting member 6b via an adhesive, and then screws are constructed from a large number of holes formed in the upper flange 66. It is screwed into the lower end surface of the panel 5.
In this way, the lower end surface of the shaft member 4 and the lower end surface of the building panel 5 are joined to the upper surface of the box-shaped metal fitting 6a and the upper surface (joint surface) of the upper flange 66, respectively, whereby the lower end surface of the pillar 3 is joined. Is joined to the upper surface of the column base hardware 6.

Further, the column base hardware 6 is installed on the upper surface of the foundation 2. The foundation 2 is made of reinforced concrete, and an anchor bolt 2a projecting from the foundation 2 is inserted into a through hole 64 of a lower plate member 61 in the box-shaped metal fitting 6a, and a nut is inserted into the inserted anchor bolt 2a. Is screwed and tightened.
In this way, the lower end surface of the column 3 is joined to the upper surface of the foundation 2 via the column base metal fitting 6. In other words, the pillar 3 can be erected on the foundation 2 in this way.
When the pillar 3 is erected on the foundation 2, the work of screwing the nut into the connecting bolt 4a and the work of screwing the nut into the anchor bolt 2a are performed by opening 62 formed in the box-shaped metal fitting 6a. It is done using.

As shown in FIGS. 1 and 2, the stigma hardware 7 is attached to the stigma (upper end surface) of the pillar 3, and is used to protect the stigma of the pillar 3 and to enhance the integrity of the pillar 3. ing.
The stigma metal 7 is a metal plate formed in a square frame shape, the four corners of which correspond to the shaft members 4 at the four corners of the pillar 3, and the sides between the four corners are the building panels of the pillar 3. It corresponds to 5. A plurality of screw holes are formed in the stigma metal fitting 7, and the screws are screwed into the shaft member 4 and the building panel 5 after being brought into contact with the upper end surface of the pillar 3 via an adhesive.

As shown in FIGS. 6 and 7, the beam 8 attached to the pillar 3 as described above is formed in a square tubular shape like the pillar 3, and the shaft members 9 (also referred to as chord members) at the four corners. And a building panel 10 for connecting the shaft members 9 at the four corners. As shown in FIG. 7, the beam 8 has a cross section formed in a rectangular frame shape in which the left and right dimensions are longer than the vertical dimensions.
The shaft member 9 is a long wooden material (so-called square timber) bridged between adjacent columns 3 and 3, and is a portion directly supported by a support metal fitting 11 described later.
The building panel 10 is configured in the same manner as the building panel 5 in the pillar 3, and has a frame body 10a and a face material 10b. Further, the building panels 10 are used so as to be continuous as much as necessary according to the distance between the adjacent pillars 3 and 3.

Further, the width dimension from one side surface to the other side surface of the beam 8 (that is, the dimension in the direction orthogonal to the length direction) is the width dimension from one side surface of the column 3 to the other side surface in the opposite direction. It is set to be approximately equal or slightly shorter. As a result, the beam 8 can be attached to the pillar 3 so that the position of the shaft member 4 on the pillar 3 and the position of the shaft member 9 on the beam 8 are aligned. That is, it is possible to join the shaft member 4 and the shaft member 9 to each other. Further, the beam 8 is attached so as to straddle the plurality of adjacent shaft members 4 and 4.

Further, at least one side end portion of the shaft member 9 on both side ends in the length direction of the beam 8 is provided along the height direction of the shaft member 9 (beam formation direction) and from the upper end surface of the shaft member 9. There is a slit 9a formed over the lower end surface.
The slit 9a is a portion into which the engaged portion 14 of the support hardware 11 described later is inserted. Further, at least one side end portion of both side end portions in the length direction of the shaft member 9 is joined by the drift pin 16 after the engaged portion 14 is inserted into the slit 9a. That is, at least one side end portion (both side end portions in the present embodiment) of both side end portions in the length direction of the shaft member 9 functions as an engaging portion that engages with the engaged portion 14 of the support hardware 11. To do. More specifically, at least one side end portion of both side end portions in the length direction of the shaft member 9 is provided with an engaging portion that engages with the engaged portion 14 of the support hardware 11. The joint portion has a slit 9a formed in the shaft member 9 and a plurality of drift pins 16 for joining the shaft member 9 and the engaged portion 14. Further, it is assumed that the shaft member 9 is formed with a plurality of through holes for inserting the plurality of drift pins 16.
Further, the set metal fitting 15 in the support metal fitting 11 described later is attached to the slit 9a while ensuring a gap for inserting the engaged portion 14.

As shown in FIGS. 6 and 8, the support metal fitting 11 is for supporting the beam 8, and includes a fixing portion 12, a mounting portion 13, an engaged portion 14, a set metal fitting 15, and the like. To be equipped.
The support hardware 11 is fixed to the shaft member 4 of the pillar 3. Unlike the building panel 5, the shaft member 4 is a square lumber (solid wood, laminated lumber, laminated lumber) having a core that is not hollow, so that the support hardware 11 follows the length direction of the shaft member 4. It can be installed in any position. In other words, the beam 8 is attached to the shaft member 4 via the support hardware 11.

The fixing portion 12 is a plate-shaped portion in contact with a predetermined height position (position corresponding to the position of the second floor and the roof described above) on the side surface of the shaft member 4, and is a lug screw bolt or a lug screw bolt or the like with respect to the shaft member 4. It is fixed by a fixture such as a coach screw bolt.

The mounting portion 13 is a plate-shaped portion that projects vertically from the lower end portion of the fixing portion 12 toward the side, and the end portion of the shaft member 9 of the beam 8 in the length direction is mounted.
Further, a recess 9b is formed on the lower surface of the end portion on the length side of the shaft member 9 in which the mounting portion 13 matches. Then, in a state where the mounting portion 13 is aligned with the recess 9b, the lower surface of the shaft member 9 in the beam 8 and the lower surface of the mounting portion 13 are flush with each other.

The engaged portion 14 is an engaging portion (end in the length direction of the shaft member 9 including the slit 9a) provided on the shaft member 9 in a state where the shaft member 9 of the beam 8 is mounted on the mounted portion 13. Part) is a plate-shaped part with which it engages. The engaged portion 14 is provided so as to connect the fixed portion 12 and the mounted portion 13 from the central portion of the fixed portion 12 to the central portion of the mounted portion 13.
In other words, the engaged portion 14 functions as a reinforcing rib that connects the fixing portion 12 and the mounted portion 13 to increase the rigidity of the support hardware 11 itself.
Further, the engaged portion 14 has a hook portion 14a for hooking the drift pin 16 provided at the highest position among the plurality of drift pins 16 and a through hole 14b for inserting the other drift pins 16. , Are formed.
The hook portion 14a is formed with a notch at the upper end portion of the engaged portion 14, so that the drift pin 16 inserted in advance in the through hole of the shaft member 9 can be hooked. By forming such a hooking portion 14a, when the beam 8 is mounted on the mounting portion 13 of the supporting hardware 11, the drift pin 16 can be hooked on the hooking portion 14a, so that it is stable. In this state, the drift pin 16 can be inserted through the other through hole 14b.

The set metal fitting 15 is a plate-shaped metal fitting that is inserted into and fixed to the slit 9a formed in the shaft member 9 of the beam 8, and is joined and fixed to the engaged portion 14 by a fixing tool such as a bolt or a nut. Will be done.
That is, this plate-shaped set metal fitting 15 is used as a set with the engaged portion 14, one side is fixed to the beam 8 (shaft member 9), and the other side is the supporting metal fitting 11 (engaged portion). It is fixed to 14). By using such a set hardware 15, not only the shaft member 9 and the engaged portion 14 are joined to each other, but also the set hardware 15 and the shaft member 9 and the set hardware 15 and the engaged portion 14 are joined to each other. Since it can be joined, it is preferable because the joining strength between the beam 8 and the supporting hardware 11 can be improved.

A form in which the engaging portion (slit 9a, drift pin 16) provided at the end portion on the length side of the shaft member 9 in the length direction is engaged with the engaged portion 14 will be described in more detail.
The drift pin 16 is inserted into the hole formed at the highest position among the plurality of holes in the shaft member 9 of the beam 8. Further, the set hardware 15 is also inserted into the slit 9a and fixed by the same drift pin 16.
With the set hardware 15 and the drift pin 16 attached, the shaft member 9 is placed on the mounting portion 13. At this time, the shaft member 9 is placed so that the slit 9a of the shaft member 9 is aligned with the engaged portion 14 of the support hardware 11. Further, the drift pin 16 is placed so as to be hooked on the hooking portion 14a. The shaft member 9 can be positioned by mounting the shaft member 9 on the mounting portion 13 so as to hook the drift pin 16 on the hooking portion 14a.
In the state where the positioning is performed in this way, the position of the through hole formed in the shaft member 9 and the position of the through hole 14b formed in the engaged portion 14 are in a state of facing each other, and the other drift pins 16 Can be inserted.
Then, the shaft member 9, the engaged portion 14, and the set metal fitting 15 are joined by the other drift pins 16 other than the drift pins 16 provided at the highest position. Further, the engaged portion 14 and the set hardware 15 are joined and fixed by a fixing tool such as a bolt or a nut.
In this way, the engaging portion provided at the end portion on the length side of the shaft member 9 in the length direction can be engaged with the engaged portion 14. Further, in the same manner, the building skeleton 1 can be constructed by joining the plurality of columns 3 and the plurality of beams 8.

As shown in FIG. 1, a floor slab 17 is provided on the building skeleton 1 constructed as described above to form the floor of the building. Although the floor slab 17 is provided only on the second floor in FIG. 1, it is assumed that the floor slab 17 is also provided on the first floor.
The floor slab 17 is a floor panel for construction, in which vertical and horizontal frame members are assembled in a rectangular shape, and auxiliary crosspieces are appropriately assembled inside the rectangular frame thus formed to form a frame body. A face material is attached to the upper surface of the frame, and the structure is hollow inside. A heat insulating material such as glass wool or rock wool is loaded in the hollow portion inside.
Further, at a position along the outer peripheral edge of the building frame 1, a body difference 17a joined to the outer end surface of the floor slab 17 is provided.
The floor slab 17 and the body difference 17a are placed and fixed on the upper surface of the beam 8 in the case of the second floor, and are placed and fixed on the upper surface of the foundation 2 in the case of the first floor. It is assumed that the foundation 2 is provided with not only the anchor bolts 2a for the pillar 3 but also the anchor bolts for the floor slab 17.
Further, although not shown, the roof slab is placed and fixed on the upper surface of the beam 8 provided at the height position where the roof is constructed. The roof in this embodiment is a flat roof, and a parapet is provided at a position along the outer peripheral edge of the roof slab. When the roof is a sloping roof, a hut is formed on the upper surface of the beam 8 provided at the height position where the roof is constructed, and a field board or roof finishing material (roofing such as roof tiles and slate) is formed on the upper surface. A roof is formed by appropriately providing a material).
Further, in addition, an outer wall finishing material, a window, a door, etc. are attached to the building frame 1 to form an outer shell of the building. In addition, overhanging parts such as eaves and balconies will be provided as needed.

It is preferable that the columns 3 and beams 8 constituting the building frame 1 are assembled in advance at the factory as much as possible, and the columns 3 and beams 8 in the present embodiment also include the column base metal fittings 6 and the capital head metal fittings 7 in advance. It is assumed that it is in the mounted state. The support hardware 11 may also be attached to the pillar 3 in advance as long as it does not interfere with transportation.

According to the present embodiment, the pillar 3 is mainly composed of a shaft member 4 provided between the upper and lower floors and a building panel 5 fixed along the shaft member 4. Since the beam 8 is attached to the shaft member 4 of the pillars 3, the beam 8 can be attached to any position along the length direction of the shaft member 4. That is, since the beam 8 is attached to the shaft member 4 instead of the hollow building panel 5, the mounting state is stable and strong, and the mounting location is the length of the shaft member 4. It can be set arbitrarily along the vertical direction. Further, by providing the hollow building panel 5, the weight of the pillar 3 itself can be reduced. Further, since the beam 8 is attached to the shaft member 4 in this way, it is not necessary to use each heavy joint metal fitting as in the conventional case, and the load applied to the building frame 1 is not used because each joint metal fitting is not used. And costs can be reduced. Moreover, the structural strength of the building frame 1 does not become over-engineered, and it is most suitable for constructing a small-scale building such as a detached house or an upper floor portion of a middle-high-rise building.

Further, a support metal fitting 11 for supporting the beam 8 is fixed to the shaft member 4, and the beam 8 is attached to the shaft member 4 via the support metal fitting 11, so that the shaft member 4 is on the upper and lower floors. The beam 8 can be attached to the shaft member 4 in a state where the beam 8 is not interrupted. Therefore, the upper and lower floors of the building skeleton 1 can be structurally integrated by the shaft member 4 provided between the upper and lower floors, so that the proof stress of the building skeleton 1 can be improved.

Further, the support hardware 11 has a fixing portion 12 fixed to the shaft member 4, a mounting portion 13 on which the beam 8 is mounted, and a beam 8 in a state where the beam 8 is mounted on the mounting portion 13. Since the engaged portion 14 with which the engaging portion provided in the above is engaged is provided, the beam 8 is placed on the mounted portion 13 and the engaged portion is engaged with the engaged portion 14. The supporting metal fitting 11 can easily and stably support the beam 8 mounted on the mounting portion 13.

Further, in a state where the mounted portion 13 matches the recess formed on the lower surface of the beam 8, the lower surface of the beam 8 and the lower surface of the mounted portion 13 are flush with each other. When the 8 is supported, the lower surface of the beam 8 does not have a protrusion due to the mounting portion 13. Therefore, when a member such as a ceiling material is attached to the lower surface of the beam 8, it is not necessary to consider the protrusion, and the workability can be improved.

Further, the pillar 3 is formed by a plurality of shaft members 4, 4 and a building panel 5 connecting the plurality of shaft members 4, 4 to each other, and the beam 8 straddles the plurality of shaft members 4, 4. Therefore, the mounting state of the beam 8 can be made more stable as compared with the case where the beam 8 is mounted only on one shaft member 4, for example.

[Modification example]
The embodiment to which the present invention can be applied is not limited to the above-described embodiment, and can be appropriately changed without departing from the spirit of the present invention. Hereinafter, a modified example will be described. The following modifications may be combined as much as possible.

[Modification 1]
In the above-described embodiment, in the pillar 3, shaft members 4 having a length extending between the upper and lower floors are arranged at the four corners, and building panels 5 are provided between the shaft members 4 and 4 adjacent to the shaft members 4 at the four corners. Moreover, the building panels 5 are formed so as to be stacked one above the other.
On the other hand, the columns 3A and 3B in this modification have fewer components (shaft material 4, building panel 5) than the columns 3 in the above-described embodiment.
The pillar 3A shown in FIG. 9A is mainly composed of a single shaft member 4 provided between the upper and lower floors and upper and lower building panels 5 fixed along the shaft member 4. Has been done.
Further, the pillar 3B shown in FIG. 9B has two shaft members 4 and 4 provided between the upper and lower floors and upper and lower building panels 5 fixed along the shaft members 4 and 4. And, it is mainly composed.
For example, a horizontal structure such as a beam is attached to the shaft member 4 of the columns 3A and 3B as described above. In this case, the horizontal structure may be attached directly to the shaft member 4 or may be attached via the support metal fitting 11.
When the columns 3A and 3B are configured as shown in FIGS. 9A and 9B, the specifications of the column base hardware and the stigma hardware are also changed according to the columns 3A and 3B.

According to this modification, columns 3A and 3B can be reliably joined to horizontal structures such as beams without using heavy metal fittings as in the past, and a small building such as a detached house can be joined. In addition, it is possible to provide an optimum building structure for constructing an upper floor portion in a middle-high-rise building. Moreover, when the building frame 1 is constructed using the columns 3A and 3B as described above, the number of elements (shaft members 4 and building panels 5) constituting the columns 3A and 3B is small, so that the cost can be further reduced. It is possible to reduce the burden on the building by reducing the weight.

The configuration of the pillar 3A in the modified example shown in FIG. 9A is the minimum configuration for realizing the present invention. Compared to the example of the pillar 3A shown in FIG. 9 (a), the number of building panels 5 used is also increased by increasing the number of shaft members 4 used, and the pillar 3B shown in FIG. 9 (b) and the pillar 3B are used. The pillar 3 in the above-described embodiment can be formed. That is, in the present invention, the number of shaft members constituting the pillar may be one or more.

[Modification 2]
There are a plurality of beams 80 in this modified example, and as shown in FIG. 10, they are attached to the shaft members 4 and 4 adjacent to each other on one side surface of the pillar 3. In other words, the beam 80 in this modification does not straddle the adjacent shaft members 4 and 4 on one side surface of the column 3, but constructs the building frame 1 in a form of being attached to each of the adjacent shaft members 4 and 4. doing. Therefore, the plurality of beams 80 are adjacent to each other with a gap from each other and are arranged in parallel. The floor slab constituting the floor is provided so as to straddle the plurality of beams 80, 80.

The beam 80 is a square lumber (solid wood, laminated lumber, laminated lumber) having a core that is not hollow, and as shown in FIGS. 10 to 12, a support metal fitting 21 fixed to a shaft member 4 of the pillar 3 is used. It is attached to the shaft member 4.
The support hardware 21 is the same as the support hardware 11 in the above-described embodiment, in which the fixing portion 22 fixed to the shaft member 4 of the pillar 3, the mounting portion 23 on which the beam 80 is mounted, and the beam 80 are engaged. An engaged portion 24 with which the joint portion engages is provided.

Slits 81 formed at at least one side end of both side ends of the beam 80 in the length direction along the height direction of the beam 80 (beam formation direction) and from the upper end surface to the lower end surface of the beam 80. The engaged portion 24 of the support hardware 21 is inserted.
Further, at least one side end of the beam 80 on both sides in the length direction is joined by the drift pin 26 after the engaged portion 24 is inserted into the slit 81. More specifically, at least one side end of the beam 80 on both sides in the length direction is provided with an engaging portion that engages with the engaged portion 24 of the support hardware 21. The portion has a slit 81 formed in the beam 80 and a plurality of drift pins 26 for joining the beam 80 and the engaged portion 24. Further, the beam 80 is formed with a plurality of through holes for inserting the plurality of drift pins 26.
On the other hand, the engaged portion 24 of the support hardware 21 is provided on the shaft member 9 in a state where the beam 80 is mounted on the mounted portion 23 (the length direction side of the beam 80 including the slit 81). It is a plate-shaped portion formed in a substantially J-shape with which the end portion) is engaged, and is provided so as to connect the fixing portion 22 and the mounting portion 23. In other words, the engaged portion 24 functions as a reinforcing rib that connects the fixed portion 22 and the mounted portion 23 to increase the rigidity of the supporting metal fitting 21 itself.
Further, the engaged portion 24 includes a hook portion 24a for hooking the drift pin 26 provided at the highest position among the plurality of drift pins 26, and a through hole 24b for inserting the other drift pins 26. , Are formed.
The hooking portion 24a can hook the drift pin 26 at the highest position previously inserted into the through hole of the beam 80. By forming such a hooking portion 24a, when the beam 80 is mounted on the mounting portion 23 of the supporting hardware 21, the drift pin 26 can be hooked on the hooking portion 24a, so that it is stable. In this state, the drift pin 26 can be inserted through the other through hole 24b.

A recess 82 with which the mounting portion 23 matches is formed on the lower surface of the end portion on the length side of the beam 80. Then, in a state where the mounting portion 23 is aligned with the recess 82, the lower surface of the beam 80 and the lower surface of the mounting portion 23 are flush with each other.

A protrusion 83 is provided at the upper end of the end face of the beam 80 in the length direction. The protruding portion 83 is located above the supporting metal fitting 21, and is in contact with the shaft member 4 in a state where the beam 80 is mounted on the mounting portion 23 of the supporting metal fitting 21. As a result, the column 3 and the beam 80 are in a directly connected state, so that the force applied to the joint portion between the column 3 and the beam 80 can be effectively dispersed.

As shown in FIG. 12, the fixing portion 22 of the support hardware 21 has a plurality of tubular portions 22a protruding toward the shaft member 4, and these plurality of tubular portions 22a are formed on the shaft member 4. Can be fitted into multiple holes (not shown). As a result, when the support hardware 21 is fixed to the shaft member 4, the tubular portion 22a can be fixed by a fixing tool such as a lug screw bolt or a coach screw bolt from the state where the tubular portion 22a is fitted into the hole of the shaft member 4 and temporarily attached. , It is easy to install the support hardware 21. Further, since both the tubular portion 22a and the fixture bite into the shaft member 4, the mounting strength of the support hardware 21 can be improved.

According to this modification, the columns 3 and the beams 80 can be reliably joined without using the conventional heavy metal joints, and the upper floors of small buildings such as single-family homes and middle- and high-rise buildings. It is possible to provide the optimum building structure for constructing the floor part. Moreover, when the building frame 1 is constructed using the beams 80 as described above, the cost can be reduced because the material constituting the beams 80 is less than that of the beams 8 in the above-described embodiment. ..

[Modification 3]
In this modification, the floor slab 30 is adopted as the horizontal structure. The floor slab 30 has the same structure as the floor slab 17 in the above-described embodiment, has a face material attached to the upper surface of the frame body, and has a hollow internal structure.
Then, in this modification, as shown in FIG. 13, the floor slab 30 is supported by the support hardware 31 fixed to the pillar 3. In other words, the floor slab 30, which is a horizontal structure, is attached to the shaft member 4 of the columns 3.
Support hardware 31 is fixed to each of the adjacent shaft members 4 and 4, and the floor slab 30 is attached across both support hardware 31 and 31.

The support hardware 31 is configured in the same manner as the support hardware 11 in the above-described embodiment, and the floor slab 30 is in a state of being placed on the placement portion 13 of the support hardware 11. Therefore, the frame body of the floor slab 30 is appropriately formed with a slit into which the engaged portion 14 of the supporting hardware 11 is inserted and a recess in which the mounted portion 13 matches.

According to this modification, the pillar 3 and the floor slab 30, which is a horizontal structure, can be reliably joined without using the heavy metal joints as in the conventional case, and a small building such as a detached house can be reliably joined. In addition, it is possible to provide an optimum building structure for constructing an upper floor portion in a middle-high-rise building.

[Modification example 4]
The building structure in this modified example is a middle-high-rise building, and as shown in FIG. 14, the lower floor portion is constructed by joining the columns 40 and the beams 41 with the conventional heavy joint hardware 42, 43, 44. The upper floor portion is constructed by using the pillars 3 and beams 8 and the like in the above-described embodiment. That is, the building structure in this modified example is a mixed structure mixed with the conventional building structure.

The lower floor portion of the building structure in this modification is composed of columns 40 and beams 41 joined by metal joints 42, 43, 44.
The pillar 40 is arranged between the shaft members 40a at the four corners and the shaft members 40a and 40a adjacent to each other, and is configured to include four sets of building panels 40b in a two-ply structure that connects the shaft members 40a and 40a to each other. There is. Column joining hardware 43 is attached to the upper end and the lower end of the column 40.
Similarly, the beam 41 is configured to include the shaft members 41a at the four corners and four sets of building panels 41b in which the shaft members 41a and 41a are connected to each other. Beam joining metal fittings 44 are attached to both ends of the beam 41 in the length direction.
A column-beam joining metal fitting 42 for joining the column 40 and the beam 41 is attached to the upper end portion of the column joining metal fitting 43 attached to the upper end portion of the column 40.

The beam-column joint metal fitting 42 is a substantially rectangular parallelepiped (vertically long) metal fitting arranged at an intersection on the extension of the column 40 and the beam 41, and the inside is hollow. That is, the column-beam joint metal fitting 42 is formed in a substantially square tubular shape.
Further, the beam-column joint metal fitting 42 has a rectangular parallelepiped receiving block 42a at each of its eight corners, and the vertically separated receiving blocks 42a and 42a are connected by a square tubular vertical member 42b. The receiving blocks 42a and 42a, which are separated from each other in the front, rear, left and right directions, are connected by a square tubular horizontal member 42c, respectively.

The column joining metal fitting 43 and the beam joining metal fitting 44 have box-shaped metal fittings at four corners and a connecting member for connecting the box-shaped metal fittings, similarly to the column base metal fitting 6 in the above-described embodiment. Each connecting member is formed in a substantially H shape by joining two channel steel webs to each other.
Further, in these column-beam joint metal fittings 43 and beam joint metal fittings 44, bolts passed through through holes formed in the box-shaped metal fittings 42 are screwed into screw holes formed in the receiving block 42a of the column-beam joint metal fittings 42. As a result, it is joined to the beam-column joining metal fitting 42.

In the building frame in the lower floor portion shown in FIG. 14, the column joining metal fitting 43 is attached to the upper end of the column 40 in the lower floor portion, and the column beam joining metal fitting 42 is joined on the column joining metal fitting 43, and further, the length is further increased. The beam 41 to which the beam joining metal fittings 44 are attached to both ends in the longitudinal direction is joined to the side surface of the column-beam joining metal fitting 42.

The column 3 to which the column base metal 6 is attached to the lower end is joined on the column-beam joint metal 42 of the lower floor portion configured as described above.
More specifically, the vertical and horizontal dimensions in the cross section of the pillar 3 in the upper floor portion are set to be substantially equal to the vertical and horizontal dimensions in the cross section of the pillar 40 in the lower floor portion. Along with this, the size of the column base metal fitting 6 attached to the lower end of the column 3 in the upper floor portion also corresponds to the size of the column-beam joint metal fitting 42 in the lower floor portion. Then, in the pillar 3 of the upper floor portion, the bolt passed through the through hole 64 formed in the box-shaped metal fitting of the column base metal fitting 6 is a screw formed in the receiving block 42a of the beam-column joint metal fitting 42 of the lower floor portion. By being screwed into the hole, it is joined to the column-beam joint metal fitting 42 in the lower floor portion.
Further, a floor slab 17 is installed on the upper surface of the beam 41 in the lower floor portion so as to avoid the pillar 3 in the upper floor portion. Further, at a position along the outer peripheral edge of the building frame, a body difference 17a joined to the outer end surface of the floor slab 17 is provided.

In this modification, the vertical and horizontal dimensions in the cross section of the pillar 3 in the upper floor portion are substantially equal to the vertical and horizontal dimensions in the cross section of the pillar 40 in the lower floor portion, and the size of the column base metal fitting 6 in the upper floor portion is also the lower floor. Since it corresponds to the size of the column-beam joint metal fitting 42 of the portion, it is possible to join the column 3 to which the column base metal fitting 6 is attached to the lower end portion on the column-beam joint metal fitting 42 of the lower floor portion. However, it is not limited to this. That is, the through hole formed in the box-shaped metal fitting 6 in the column base metal fitting 6 of the column 3 in the upper floor portion corresponds to the position of the screw hole formed in the receiving block 42a in the column-beam joint metal fitting 42 in the lower floor portion. Just do it. Therefore, even if there is a slight difference in the cross-sectional dimensions of the columns 3 and 40 and the size of the column base metal fitting 6 and the beam-column joint metal fitting 42, the column 3 in the upper floor portion is replaced with the column-beam joint metal fitting 42 in the lower floor portion. It suffices if it can be joined.

The lower floors of the middle-high-rise building in this modified example are building panels 40b and 41b in which columns 40 and beams 41 are stacked in two layers, and heavy joint hardware 42, 43 and 44 are used at the joints. It is robust because it is. Therefore, it is suitable for constructing a lower floor portion in a middle-high-rise building. On the other hand, the upper floors employ columns 3 and beams 8 that are lighter than the columns 40 and beams 41 in the lower floors, and are therefore most suitable for constructing the upper floors in middle- and high-rise buildings. is there. Since the columns 3 in the upper floors can be joined to the beam-column joining hardware 42 in the lower floors, it is less likely to hinder the realization of a mixed structure mixed with the conventional building structure, and it is easy to construct.

1 Building frame 3 Pillars 4 Shafts 5 Building panels 6 Pillar bases 8 Beams 9 Shafts 9a Slits 9b Recesses 10 Building panels 11 Supporting hardware 12 Fixing parts 13 Mounting parts 14 Engagement parts 16 Drift pins 17 Floor Edition

Claims (3)

In a building structure having a building skeleton formed by columns and horizontal structures attached to the columns.
The pillar is mainly composed of a shaft member provided between the upper and lower floors and a plurality of hollow building panels fixed along the shaft member.
The plurality of building panels are stacked one above the other along the length direction of the shaft member, and the upper end surface of the lower building panel is in contact with the lower end surface of the upper building panel. Ori
The shaft member is a square timber having a core that is not hollow, and a support metal fitting for supporting the horizontal structure is fixed to the shaft member.
The support metal fitting has a plate-shaped fixing portion fixed to the shaft member, a mounting portion on which the horizontal structure is mounted, and a state in which the horizontal structure is mounted on the mounting portion. and a engaged portion engaging portion are engaged provided on the horizontal structure at the fixing portion, a bolt fixed to an arbitrary height position on the side surface of the shaft member of said post Has been
The horizontal structure is attached to the shaft member of the pillar via the support metal fitting .
The engaged portion is a plate-shaped portion provided from the fixed portion to the mounted portion and connecting the fixed portion and the mounted portion.
The engaging portion is provided in a slit provided at the lengthwise side end portion of the horizontal structure into which the engaged portion is inserted, and is inserted into the lengthwise side end portion of the horizontal structure and the slit. It has a drift pin that penetrates the engaged portion.
The support hardware further includes a plate-shaped set hardware provided while ensuring a gap for inserting the engaged portion into the slit.
The set hardware is joined and fixed to the engaged portion with bolts and nuts.
The building structure is characterized in that the drift pin penetrates the set hardware together with the lengthwise side end portion of the horizontal structure and the engaged portion. In the building structure according to claim 1,
A recess is formed on the lower surface of the horizontal structure so that the mounting portion matches.
A building structure characterized in that the lower surface of the horizontal structure and the lower surface of the mounting portion are flush with each other in a state where the mounting portion is aligned with the recess. In a building structure having a building skeleton formed by columns and horizontal structures attached to the columns.
The pillar is mainly composed of a shaft member provided between the upper and lower floors and a plurality of hollow building panels fixed along the shaft member.
The plurality of building panels are stacked one above the other along the length direction of the shaft member, and the upper end surface of the lower building panel is in contact with the lower end surface of the upper building panel. Ori
The shaft member is a square timber having a core that is not hollow, and a support metal fitting for supporting the horizontal structure is fixed to the shaft member.
The support metal fitting includes a plate-shaped fixing portion to be fixed to the shaft member, and the fixing portion is from the side surface of the shaft member with respect to an arbitrary height position on the side surface of the shaft member of the pillar. Is also bolted in a state of protruding to the side,
The horizontal structure is attached to the shaft member of the pillar via the support metal fitting.
Of the horizontal structure, the side surface of the shaft member is located above the support hardware and projects toward the shaft member, and the horizontal structure is attached to the shaft member via the support hardware. Status
The building structure is characterized in that a protruding portion in contact with the shaft member is provided.

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