JP4998500B2 - Brace fixing hardware for seismic reinforcement - Google Patents

Description

  The present invention relates to the structure of a brace fixing hardware, and more particularly to the structure of a brace fixing hardware for seismic reinforcement used for walls of existing buildings.

As can be seen from the results of major earthquakes that occurred in the past, buildings (wooden houses) prior to the 1950 Building Standards Act were not required to install braces to increase earthquake resistance. There are many weak ones.
For this reason, with the recent increase in awareness of earthquake resistance, there is an increasing demand for reinforcement of buildings by newly providing braces for existing buildings to improve earthquake resistance.

  On the other hand, when constructing a new building, it has been proposed to provide a brace by installing brace fixing hardware described in Patent Document 1 below. This bracing fixing hardware includes first and second fixing portions having L-shaped planes that are L-shaped and can be brought into surface contact with the inner surfaces of the column and beam that are perpendicular to each other, and the first and second fixing portions thereof. The part is fixed to the framework. In addition, a third fixing portion formed perpendicularly to both the inner surfaces of the first and second fixing portions is formed, and the end portion of the bracing and the third fixing portion are overlapped together by two bracing fixing members. The bracing end portion and the third fixing portion are joined by being pinched and fixed.

JP-A-8-277588

  However, the brace fixing hardware described in Patent Document 1 is a bracing fixing hardware for attaching the brace to the frame when newly constructing a building, and when installed in an existing building, there are walls, windows and sashes on the frame. Since it has already been incorporated, there is a problem that the brace fixing hardware cannot be attached.

  The present invention has been made to solve the above-described problems of the prior art, and it is an object of the present invention to provide a seismic reinforcing brace fixing hardware that can be attached to an existing building in which windows and sashes are incorporated. Is.

In order to solve the above-mentioned problem, the present invention according to claim 1 is a brace fixing hardware used for adding braces as a seismic reinforcement to a frame composed of columns and beams of an existing building, A plate-like fixed base material which is arranged at the corners of the frame where the pillar and the beam are orthogonal to each other and fixed to the pillar and the beam, and is arranged on the surface of the fixed base material in a direction along the bracing. The reinforcing member is integrally fixed to the fixing base and the end of the bracing is fixed, and the base end is fixed to the reinforcing member, and the bracing end is fixed to the distal end. that Ri Na comprises a spacer member, said spacer member, together with the female screw portion is formed at an upper end portion, a distal end portion of the inserted through bolts from the back side to the reinforcing member of said anchoring substrate, the female screw Screwed into the Substrate and those characterized that you have been fixed to the reinforcing member.

Further, the present invention according to claim 2 is a brace fixing hardware used to add bracing as a seismic reinforcement to a frame constituted by columns and beams of an existing building, and the longitudinal length of the columns or beams. A flat fixed base material fixed along the direction, and disposed on the surface of the fixed base material so as to extend over the entire length of the fixed base material and integrally fixed to the fixed base material. a reinforcing member end of the brace is fixed, together with the base end portion is fixed to the reinforcing member, Ri Na includes a spacer member which the end of the brace is fixed to the distal end portion, the spacer member A female screw portion is formed at the upper end portion, and a front end portion of a bolt inserted into the reinforcing member from the back surface side of the fixed base material is screwed into the female screw portion, whereby the fixed base material and Rukoto is fixed to the reinforcing member It is an feature.

  Generally, in an existing building, a mortar-constructed wall is constructed by incorporating a heat insulating material in a framework composed of columns and beams, or a window frame, a sash, or the like is incorporated. For this reason, it is difficult to install braces within the framework.

In this respect, in the invention according to claim 1 or claim 2 , since the fixed base material for attaching the braces is formed in a flat plate shape, the fixed base material is changed from the outer surface side of the building to the column beam. Can be fixed. In addition, since the fixed base has a flat plate shape, it does not protrude greatly from the outer surface of the building.

  On the other hand, when the fixed base material is fixed to the column beam, the fixed base material is formed in a flat plate shape. It is difficult to connect the parts. For this reason, the bracing end is connected at a position spaced from the column beam.

  Then, at the time of an earthquake, the tensile force and compressive force acting on the bracing are transmitted from the end portion to the column and beam through the thin fixed base material. As a result, the fixed base material is There is a risk of plastic deformation and breakage.

  On the other hand, in the present invention, the reinforcing member is integrally fixed to the surface of the fixed base material in the direction along the bracing, and the end of the bracing is fixed to the reinforcing member. A tensile force and a compressive force sometimes acting on the braces can be transmitted to the column beam via the reinforcing member. As a result, there is no fear that the thin fixed substrate will be distorted due to large distortion, and high earthquake resistance can be exhibited.

  By the way, since the conventional bracing fixing hardware is incorporated into the frame, it is necessary to install the bracing fixing hardware at at least two corners of the framework. For this reason, the installation pattern of the braces incorporated in the skeleton is limited, and the windows and the sash may be blocked by the braces and may not function.

  On the other hand, in the present invention according to claim 2, since the fixing base is fixed along the longitudinal direction of the column or beam, it is possible to reliably install the bracing while avoiding the window and the sash. It is.

Moreover, in this invention of Claim 1 or 2 , since the spacer member is being fixed to the reinforcement member and the edge part of bracing is being fixed to the front-end | tip part of this spacer member, a sash frame is attached to the outer surface of a building. Even when there is a protrusion such as a ridge or a heel, a brace can be installed without interfering with the protrusion by appropriately selecting the length of the spacer member. At this time, since a bending stress acts on the spacer member in the event of an earthquake, it is preferable to use a thick cylindrical or rectangular tube member having excellent strength.

Further, according to the first or second aspect of the present invention, the female screw in which the tip of the bolt inserted through the reinforcing member from the back surface side of the fixed base member is screwed into the upper end of the spacer member. Since the portion is formed, the spacer member is fixed to the fixing base member and the reinforcing member. Thereby, since it fixes with the volt | bolt, without fixing the said fixed base material, the said reinforcement member, and the said spacer member by welding, a member can be changed according to the condition of the wall surface of a field.

1 is a front view showing a first embodiment of a brace fixing hardware according to the present invention. It is a front view which shows the fixed base material of FIG. 1A is a perspective view, FIG. 1B is a plan view, FIG. 1C is a front view, and FIG. 1 shows the attachment state of the bracing of the brace fixing hardware of FIG. 1, (a) AA sectional view showing a state where the bracing is not attached, (b) AA showing a state where the bracing is attached to the bracing fixing hardware. It is sectional drawing. FIG. 2 is an installation diagram illustrating a state in which the brace fixing hardware illustrated in FIG. 1 is fixed at a predetermined position when the bracing installation pattern is configured as a rack. It is a front view which shows 2nd Embodiment of the bracing fixed hardware which concerns on this invention. It is a front view which shows the fixed base material of FIG. It is a perspective view which shows the reinforcement member of FIG. It is a front view which shows 3rd Embodiment of the bracing fixed hardware which concerns on this invention. It is a front view which shows the fixed base material of FIG. It is a perspective view which shows the reinforcement member of FIG. FIG. 9 is an installation diagram illustrating a state in which the bracing fixing hardware illustrated in FIGS. 6 and 8 is fixed at a predetermined position when the bracing installation pattern is configured in two symmetrical K-types. FIG. 2 is a front view showing a state in which the brace fixing hardware of FIG. 1 is fixed at a predetermined position when the bracing installation pattern is configured in a K shape. FIG. 2 is a front view showing a state in which the brace fixing hardware of FIG. 1 is fixed at a predetermined position when the bracing installation pattern is configured in a V shape.

(First embodiment)
Hereinafter, a first embodiment of a brace fixing hardware according to the present invention will be described with reference to FIGS.
First, as shown in FIG. 1, the brace fixing hardware 1 of this embodiment is schematically configured by a combination of a fixing base 2, a reinforcing member 3, and a spacer member 4.

  And the fixed base material 2 is formed in square flat form, as shown in FIG. Further, a plurality of first openings 5 (25 in a regular arrangement of 5 columns in the vertical direction and 5 rows in the horizontal direction) penetrating from the front surface to the back surface are provided.

  Further, a plurality of (10 in FIG. 1) implants so as to sandwich the first openings 5 formed by four in parallel with the diagonal of the fixed base material 2 and symmetrically about the diagonal. Bolts 6 are provided.

  And the hexagon bolt 7 is inserted from the center of the back surface side of the fixed base material 2, and is fixed by the nut 22 on the front surface side of the fixed base material 2, so that the bolt head of the hexagon bolt 7 does not protrude from the back surface. A concave depression is provided in the center of the back surface side of the fixed substrate 2.

  Further, the reinforcing member 3 is provided so as to extend across the entire diagonal length of the fixed base member 2 as shown in FIG. 1, and as shown in FIG. 3, a web 8 formed in a U-shape, It is formed in a hat-shaped cross-sectional shape that forms a flange 9 at its end.

  A second opening 10 that can face the first opening 5 is formed at both ends of the web 8, and a circular spacer insertion portion for inserting the spacer member 4 at the center of the web 8. 11 is provided.

  In addition, nine bolt insertion holes 12 are formed in both flanges 9 at ½ pitch intervals of the interval between the first openings 5 on the diagonal line of the fixed base 2. And the reinforcement member 3 is being fixed to the fixed base material 2 by inserting the implantation bolt 6 of the fixed base material 2 in the bolt insertion hole 12, and connecting with the nut.

  Further, as shown in FIG. 4A, the spacer member 4 is formed in a cross-sectional cylindrical shape having a top plate at the upper end portion 13, and is inserted into the spacer insertion portion 11 of the reinforcing member 3. The front end portion 19 and the spacer insertion portion 11 are fixed by surface contact. Further, a female screw portion 14 is provided at the center of the upper end portion 13, and the hexagonal bolt 7 inserted from the back side of the fixed base member 2 is screwed into the female screw portion 14 of the spacer member 4. The spacer member 4 is also fixed to the fixed substrate 2. Moreover, the front-end | tip part of the hexagon bolt 7 is screwed together with the internal thread part 14, and protrudes from the upper end part 13 as it is, and the edge part of the brace 20 is fixed.

  As shown in FIG. 5, the brace fixing hardware 1 according to the first embodiment having the above-described configuration is a skeleton 17 in which the columns 15 and the beams 16 are orthogonal to each other with the reinforcing member 3 directed in a direction along the diagonal line of the brace 20. It arrange | positions at the corner | angular corner part 18 of. Of the first openings 5 in the regular arrangement of 5 columns and 5 rows provided in the fixed base 2, the optimal position for fixing the brace 1 to the pillars 15 and the beams 16 is shown. By selecting the first opening 5 and inserting and tightening the lag screw bolt into the first opening 5, the bracing fixture 1 is fixed to the column 15 and the beam 16.

  And as shown in FIG.4 (b), the end of the brace 20 is attached to the front-end | tip part of the hexagon bolt 7 which protruded from the upper end part 13 of the spacer member 4, and a brace is carried out by fixing with the cap nut 23. 20 fixed.

  At this time, the bracing 20 is arranged in such a manner that the bracing 10 is fixed to the diagonal corners 18 on the diagonal line from the fixing base material 2 arranged at the four corners 18 of the skeleton 17 as shown in FIG. By arranging it toward the base material 2, it is constructed as a tack.

(Second Embodiment)
Next, a second embodiment of the brace fixing hardware will be described with reference to FIGS. In addition, the thing of the same structure as 1st Embodiment, such as the spacer member 4, is abbreviate | omitted description using a same sign.

  First, the brace fixing hardware 24 of this embodiment is schematically configured by a combination of a fixing base 25, a reinforcing member 26, and a spacer member 4, as shown in FIG.

  As shown in FIG. 7, the fixed base 25 is formed in a rectangular flat plate shape. A total of a plurality penetrating from the front surface to the back surface (in FIG. 7, five at regular intervals on the longitudinal center line of the fixed base material 25 and 6 at regular intervals in the longitudinal direction of the left and right ends symmetrically with the longitudinal center line). 17) first openings 5 are provided.

  Further, a plurality of (in FIG. 7, 5 each, a total of 10 are equally spaced so as to be sandwiched between the six first openings 5 formed in the longitudinal direction of the left and right ends of the fixed base 25. Book) is provided.

  Of the five first openings 5 formed on the vertical center line of the fixed base material 25, the second and fourth first openings 5 from the upper side in the figure have a back surface of the fixed base material 25. Hexagon bolt 7 is inserted from the side, and is fixed by nut 22 on the front surface side of fixed base material 25, so that the bolt head of hexagon head bolt 7 does not protrude from the rear surface side. The portion into which 7 is inserted is provided with a concave recess.

  Further, as shown in FIG. 6, the reinforcing member 26 is provided so as to extend over the entire length of the fixed base member 25. As shown in FIG. 8, the reinforcing member 26 is similar to the reinforcing member 3 of the first embodiment. It is formed in a hat-shaped cross-sectional shape in which a web 8 formed in a letter shape and a flange 9 is formed at an end thereof.

  And the 2nd opening part 10 which can face the 1st opening part 5 is formed in the center part and both ends of the web 8, and the spacer member 4 is provided between the three 2nd opening parts 10 between them. A circular spacer insertion portion 11 for insertion is provided.

  Each of the flanges 9 is formed with six third openings 27 that can face the six first openings 5 formed in the longitudinal direction of the left and right ends of the fixed base 25.

  Further, the both flanges 9 are sandwiched between the third openings 27, and the bolt insertion holes are equidistant from the spacing of the five implanted bolts formed symmetrically with respect to the longitudinal center line of the fixed base 25. Five 12 are formed. And the reinforcement member 26 is being fixed to the fixed base material 25 by inserting the implantation bolt 6 of the fixed base material 25 in the bolt insertion hole 12, and connecting with the nut.

  Then, as shown in FIG. 4, the spacer member 4 is inserted into the spacer insertion portion 11 of the reinforcing member 26 and inserted into the spacer 19 in the same manner as the brace fixing metal 1 of the first embodiment. The part 11 is fixed by surface contact. Further, the spacer member 4 is provided with a female screw portion 14 at the center of the upper end portion 13, and the hexagon bolt 7 inserted from the back surface side of the fixed base 25 is screwed into the female screw portion 14 of the spacer member 4. By doing so, it is also fixed to the fixed substrate 25.

(Third embodiment)
Next, a third embodiment of the brace fixing hardware will be described with reference to FIGS. In addition, the thing of the same structure as 1st Embodiment and 2nd Embodiment, such as the spacer member 4, is abbreviate | omitted description using a same sign.

  First, as shown in FIG. 9, the brace fixing hardware 28 of the present embodiment is roughly configured by a combination of a fixing base material 29, a reinforcing member 30, and a spacer member 4.

  As shown in FIG. 10, the fixed base material 29 is formed in a rectangular flat plate shape like the fixed base material 25. A total of a plurality penetrating from the front surface to the back surface (in FIG. 10, five at regular intervals on the longitudinal center line of the fixed base material 29 and 6 at regular intervals in the longitudinal direction of the left and right ends symmetrically with the longitudinal center line). 17) first openings 5 are provided.

  Further, a plurality of pieces (a total of ten pieces in FIG. 10 each including five pieces) are sandwiched between the six first opening portions 5 formed in the longitudinal direction of the left and right ends of the fixed base material 29. Implantation bolts 6 are provided.

  Of the five first openings 5 formed on the vertical center line of the fixed base material 29, the third first opening 5 from the upper side in the figure has a hexagonal shape from the back side of the fixed base material 29. The bolt 7 is inserted and is fixed by the nut 22 on the front surface side of the fixed base material 29, and the hexagon bolt 7 on the back surface side of the fixed base material 29 is inserted so that the bolt head of the hexagon bolt 7 does not protrude from the back surface. The recessed portion is provided with a concave depression.

  Further, as shown in FIG. 9, the reinforcing member 30 is provided so as to extend over the entire length of the fixed base material 29, and as shown in FIG. 11, the reinforcing member 3 of the first embodiment and the second embodiment. , 26 is formed in a hat-shaped cross-sectional shape in which a web 8 formed in a U-shape and a flange 9 is formed at an end thereof.

  And the circular spacer insertion part 11 for inserting the spacer member 4 is provided in the center part of the web 8, and the 1st opening part 5 is faced between both ends and a center part and both ends. A second opening 10 is formed.

  Further, similar to the reinforcing member 26, both flanges 9 have six third openings 27 that can face the six first openings 5 formed in the longitudinal direction of the left and right ends of the fixed base material 29. It is formed one by one.

  Further, similar to the reinforcing member 26, both flanges 9 are sandwiched between the third openings 27, and the interval between the implantation bolts that are formed by five symmetrical longitudinal center lines of the fixing base material 29. Five bolt insertion holes 12 are formed at equal intervals. Then, the reinforcing member 30 is fixed to the fixed base material 29 by inserting the implantation bolt 6 of the fixed base material 29 into the bolt insertion hole 12 and coupling with the nut.

  Then, as shown in FIG. 4, the spacer member 4 is inserted into the spacer insertion portion 11 of the reinforcing member 30 and inserted into the spacer 19 in the same manner as the brace fixing metal 1 of the first embodiment. The part 11 is fixed by surface contact. Further, the spacer member 4 is provided with a female screw portion 14 at the center of the upper end portion 13, and the hexagon bolt 7 inserted from the back side of the fixed base material 29 is screwed into the female screw portion 14 of the spacer member 4. By doing so, it is also fixed to the fixed substrate 29.

  As shown in FIG. 12, the bracing fixtures 24 and 28 of the second embodiment and the third embodiment having the above-described configuration are first formed at the corner corner 18 of the frame 17 where the pillar 15 and the beam 16 are orthogonal to each other. The fixed base material 2 used in one embodiment is disposed. Of the first openings 5 regularly arranged in 5 columns and 5 rows provided in the fixed base material 2, the optimal position for fixing the fixed base material 2 to the columns 15 and the beams 16 is provided. The first base 5 is selected, and a lag screw bolt is inserted into the first opening 5 and tightened to fix the fixed base 2 to the column 15 and the beam 16.

  Then, the brace fixing hardware 24 is arranged at the intermediate portion between the left and right columns 15 so as to be along the longitudinal direction of the columns 15.

  Further, two brace fixing hardwares 28 are arranged on the upper and lower beams 16 at equal intervals along the longitudinal direction of the beam 16.

  Then, lag screw bolts are inserted and tightened into the third openings 27 of the reinforcing members 26 and 30 facing the five first openings 5 formed in the longitudinal direction of the left and right ends of the fixing bases 25 and 29. As a result, the braces and fixing hardware 24 and 28 are fixed to the column 15 and the beam 16.

  Then, as shown in FIG. 4 (b), the end of the brace 20 is attached to the tip of the hexagon bolt 7 projecting from the upper end 13 of the spacer member 4, and fixed with the cap nut 23, so that the brace 20 To fix.

  At this time, as shown in FIG. 12, the bracing 20 is arranged in such a manner that the bracing 20 is directed from the brace fixing hardware 24 provided at the intermediate portion between the left and right columns 15 to the bracing fixing hardware 28 provided on the upper and lower beams 16. By arranging them vertically symmetrically, the left and right sides of the skeleton 17 are configured in a K shape.

  In the brace fixing hardware 1, 24, 28 of the first, second, and third embodiments described above, since the fixing bases 2, 25, 29 are formed in a flat plate shape, the outer surface side of the building Since it can be fixed to the column beams 15 and 16, the brace 20 can be installed also on a wall in which a heat insulating material is incorporated and mortared, or on a wall in which a window frame or a sash is incorporated. In addition, it does not protrude greatly from the outside of the building.

  And since the spacer member 4 is fixed to the reinforcing members 3, 26 and 30, and the end of the brace 20 is fixed to the tip 19 of the spacer member 4, a sash frame, a bag or the like is formed on the outer surface of the building. Even when there is a protrusion, the brace 20 can be installed without interfering with the protrusion by appropriately selecting the length of the spacer member 4.

  Further, since the second opening 10 is formed in the web 9 of the reinforcing members 3, 26, 30, the first opening 5 can be faced, and the lag screw bolt is passed through the second opening 10. And can be inserted into the first opening 5. Thereby, after assembling the bracing fixtures 1, 24, and 28 of the first, second and third embodiments, they are arranged at the corners 17 of the columns 15 and the beams 16 and fixed with lag screw bolts. The brace fixing hardware 3, 24, 28 of the first, second and third embodiments can be attached by work. As a result, the brace fixing hardware 1, 24, 28 of the first, second, and third embodiments can be easily attached even in an environment with poor work efficiency such as a narrow place.

  Furthermore, even if a bending stress acts on the spacer member 4 from the brace 20 during an earthquake, the spacer member 4 is formed in a thick cylindrical shape, so that the strength is increased, so that the shake can be prevented. Further, since the outer periphery of the front end portion 19 and the spacer insertion portion 11 are in surface contact, and the lower end portion 21 of the spacer member 4 is also in surface contact with the fixed bases 2, 25, and 29, the spacer member 4. Therefore, it is possible to prevent the spacer member 4 from being deformed and broken.

  And since all the members of the fixing base material 2, 25, 28, the reinforcing members 3, 26, 29 and the spacer member 4 are not fixed by welding, but are fixed by bolts or nuts, the situation of the wall surface in the field It is possible to change the member according to the condition, and at the same time, it is not necessary to check the quality of the welded part like the parts being welded, and the cost can be reduced.

  On the other hand, in the brace fixing hardware 1 of the first embodiment, the reinforcing member 3 is integrally fixed to the surface of the fixing base 2 over substantially the entire length in the diagonal direction, and the end portion of the bracing 20 is attached to the reinforcing member 3. Since the tensile force and the compressive force acting on the brace 20 at the time of an earthquake can be transmitted to the column 15 and the beam 16 via the reinforcing member 3, a large thickness is applied to the fixed base material 2. There is no fear of breakage due to distortion, and high seismic performance can be exhibited.

  Then, the brace 1 of the first embodiment is arranged at the four corners 18 of the skeleton 17 and the installation pattern of the brace 20 is configured as a rack, so that the truss 20 and the column beams 15 and 16 are used as truss. Since the structure is formed, the support strength of the skeleton 17 is stabilized and the earthquake resistance is improved. As a result, higher seismic performance can be exhibited.

  Moreover, since the fixed base material 2 is provided with the first openings 5 in a regular arrangement of 5 columns and 5 rows, the bracing fixture 1 is placed at any position of the column 15 and the beam 16 of the skeleton 17. Even if it is arranged, it becomes possible to fix the brace fixing hardware 1 by inserting the lag screw bolt into the first opening 5 and tightening it at the optimum position, which is common to existing buildings of various forms. And can be fixed in a stable state.

  In addition, since the bolt insertion holes 12 are formed in the flange 9 at ½ pitch intervals of the interval between the first openings 5 on the diagonal line of the fixed base 2, the corner corner 18 side is formed on the outer surface of the building. Even when the reinforcing member 3 cannot be attached to the entire diagonal length of the fixed base member 2 because the protrusions lower than the height of the reinforcing member 3 are formed, the reinforcing member 3 is fixed to the fixed base member. Since it can be attached by shifting every 1/2 pitch in the diagonal direction of 2, the attachment position of the reinforcing member 3 can be changed according to the outer surface of the building.

  In addition, since the second opening 10 is formed at both ends of the web 9 of the reinforcing member 3, the first opening 5 can be faced even when the bracing fixture 1 is assembled. Therefore, it is possible to insert the lag screw bolt into the first opening 5 through the second opening 10. As a result, the bracing fixing hardware 1 can be attached by a simple operation of assembling the bracing fixing hardware 1 and then placing it at the corners 17 of the columns 15 and beams 16 and fixing them with lag screw bolts. Even in an environment with poor work efficiency such as a place, the bracing and fixing hardware 1 can be easily attached.

  And by the synergistic action of all these parts, it was able to withstand the horizontal force in an earthquake, and a high numerical value could be obtained in the in-plane shear test. In order to compare with the numerical value stipulated in Article 46, Paragraph 4 of the Building Standards Act Construction Order, the current numerical value is measured in a state where the brace 20 is set as a racking pattern. The wall magnification of the stake of φ9 mm reinforcing bars of the specified value is 2.0 and the wall strength magnification is 3.2, whereas the wall magnification of the staking of φ9 mm reinforcing bars of the present invention is 2.6, wall The strength magnification is very high at 5.2. This numerical value is equivalent to a wall magnification of 2,5 and a wall strength magnification of 5.0 with a JAS structural plywood thickness of 7.5 mm or more. Also from this result, for earthquake resistance reinforcement with very strong earthquake resistance It can be seen that it is a bracing fixture.

  On the other hand, in the brace fixing hardwares 24 and 28 of the second embodiment and the third embodiment, since the installation pattern of the brace 20 on both the left and right sides is configured in a K shape, the bracing is performed so as to avoid the center of the inner surface of the skeleton 17. 20 can be provided. For this reason, even if there are many windows and sashes formed at the center of the wall surface, the functions of the windows and sashes are not impaired.

  In addition, the brace fixing hardware 24 of the second embodiment is arranged at an intermediate portion between the left and right pillars 15, and the bracing fixing hardware 28 is arranged on the upper and lower beams 16 so that the installation pattern of the bracing 20 is configured in a K shape. As a result, the truss structure is formed by the brace 20 and the column beams 15 and 16 in the same manner as the installation pattern of the brace 20 is configured as a sash, so that the support strength of the frame 17 is stabilized and the earthquake resistance is improved. . As a result, high seismic performance can be exhibited.

  Furthermore, since the bracing fixtures 24 and 28 are arranged at predetermined positions, and the fixing base material 2 used in the first embodiment is arranged and attached to the corners 18 of the skeleton 17, the wall magnification and the wall strength are increased. It is possible to improve the height magnification.

  And by the synergistic action of all these parts, it was able to endure the horizontal force in an earthquake, and in the in-plane shear test, a high numerical value that was inferior to that of the first embodiment could be obtained. In order to compare with the numerical value stipulated in Article 46, Paragraph 4 of the Building Standards Act, this numerical value is measured with the bracing 20 in a K-type installation pattern. In the present embodiment, the wall magnification is 1.3 and the wall strength magnification is 2.6 while the wall magnification of the reinforcing bar of φ9 mm of the specified numerical value is 1.0 and the wall strength magnification is 1.6. I get high numbers. This figure can be obtained as the wall magnification 1.5 and wall strength magnification 2.4 of the brace 20 made of wood (with end hardware) 3cm thick and 9cm wide. From this, it can be seen that this is a brace fixing metal fitting for seismic reinforcement that is stronger in earthquake resistance than in the past.

  The brace 20 is configured as a sash when the brace fixing hardware 1 of the first embodiment is used, but in addition to the brace fixing hardware 1 of the first embodiment, a third brace fixing hardware 29 is provided. As shown in FIG. 13, the brace fixing hardware 1 is arranged at the upper and lower corners 18 of one pillar 15 and the bracing fixing hardware 28 according to the third embodiment is provided in the middle part of the other pillar 15. The brace 20 is configured in a K shape by arranging the brace, or as shown in FIG. 14, the brace fixing hardware 1 is arranged at the left and right corners 18 of the upper beam 16, and the center of the lower beam 16 is arranged. By arranging the brace fixing hardware 28 of the third embodiment in the part, it is possible to appropriately select the configuration pattern of the brace 20 such as configuring the brace 20 in a V shape.

  Thus, by appropriately selecting the brace fixing hardware 1, 24, 28 of the first, second, and third embodiments according to the situation of the wall surface, the installation pattern of the brace 20 can be applied to, for example, the wall surface. When nothing is installed, it can be configured as a K-type or V-type installation pattern when there is a window, sash, or protrusion on the wall, and the function of the window or sash is Seismic reinforcement can be carried out without loss.

1 Bracing fixed hardware (first embodiment)
2 Fixed substrate (first embodiment)
3 Reinforcing member (first embodiment)
4 Spacer member 7 Hexagon bolt (bolt)
13 Upper end portion 14 Female screw portion 15 Column 16 Beam 17 Frame 18 Corner corner portion 19 Tip portion 20 Bracing 24 Bracing fixing hardware (second embodiment)
25 Fixed substrate (second embodiment)
26 Reinforcing member (second embodiment)
28 Brace fixing hardware (third embodiment)
29 Fixed substrate (third embodiment)
30 Reinforcing member (third embodiment)

Claims (2)

It is a brace fixing hardware used to add a brace as a seismic reinforcement to a framework composed of columns and beams of an existing building,
A plate-like fixed base material which is arranged at the corners of the frame where the pillar and the beam are orthogonal to each other and fixed to the pillar and the beam, and is arranged on the surface of the fixed base material in a direction along the bracing. A reinforcing member that is integrally fixed to the fixing base and the end of the bracing is fixed, and a base end is fixed to the reinforcing member, and the bracing end is fixed to the distal end. Ri Na comprises a spacer member to be,
The spacer member is formed with a female screw portion at an upper end portion, and by screwing a front end portion of a bolt inserted into the reinforcing member from the back surface side of the fixed base member into the female screw portion. anchoring substrate and brace fixing hardware characterized that you have been fixed to the reinforcing member. It is a brace fixing hardware used to add a brace as a seismic reinforcement to a framework composed of columns and beams of an existing building,
A flat plate-like fixed base material fixed along the longitudinal direction of the pillar or beam, and is provided on the surface of the fixed base material so as to extend the entire length of the fixed base material, and is integrated with the fixed base material. A reinforcing member that is fixed to the reinforcing member and to which the end of the bracing is fixed, and a spacer member that fixes the proximal end to the reinforcing member and that fixes the bracing end to the distal end. The
The spacer member is formed with a female screw portion at an upper end portion, and by screwing a front end portion of a bolt inserted into the reinforcing member from the back surface side of the fixed base member into the female screw portion. brace fixing hardware that is fixed to the fixed substrate and the reinforcing member, characterized in Rukoto.

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