JP2017172139A - Antiseismic structure and antiseismic reinforcement method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an antiseismic structure which does not require quality control on welding and uses reduced man-hour when fixing braces to columns.SOLUTION: An antiseismic structure in this invention includes braces 31 to 34 which are arranged between a pair of columns 3 and fixed to each of the pair of columns 3. The antiseismic structure comprises: fixing parts 16, 20, 24 with bolt holes formed on them, which are part of the columns 3 or are fixed to the columns 3; and pairs of braces 31 to 34, which extend in a common direction between the pair of columns 3 and are fixed to the fixing parts 16, 20, 24. In the antiseismic structure, a common bolt 43 is inserted into the bolt hole of each of the fixing parts 16, 20, 24 and the bolt holes of each pair of the braces 31 to 34 to join the braces to the corresponding fixing part 16, 20, 24.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an earthquake resistant structure and an earthquake resistant reinforcement method.

  2. Description of the Related Art Conventionally, some buildings such as houses have a bearing wall provided with a first diagonal member and a second diagonal member that intersect each other between a pair of columns (see, for example, Patent Document 1). The first diagonal is connected to the column head of one column and the column base of the other column, and the second diagonal is connected to the column base of one column and the column head of the other column, The first diagonal member and the second diagonal member cross each other. In this bearing wall, two or more first diagonal members are provided and two or more second diagonal members are provided.

Japanese Patent Application Laid-Open No. 2015-1115

  However, in the prior art described in Patent Document 1, since the fixed portion connected to the column and the diagonal member are joined by welding, it is necessary to perform quality control of welding so as to ensure the strength of the welded portion. It also takes man-hours.

  An object of the present invention is to provide a seismic structure and a seismic reinforcement method that do not require quality control of welding and reduce the number of work steps when fixing a brace, which is an oblique material, to a column.

  The earthquake-resistant structure of the present invention is an earthquake-resistant structure in which braces are arranged between a pair of columns, and is the same between a pair of columns and a fixed portion that is fixed to a column or is a part of a column with a bolt hole formed. A pair of braces that extend in the direction of and fixed to the fixing part, and the pair of braces are bolted to the same fixing part by a common bolt inserted through the bolt hole of the fixing part. Yes.

  In this seismic structure, a pair of braces are bolted to the same fixed part by means of common bolts, not by welding, so there is no need for quality control of welding, and man-hours when joining braces Can be reduced.

  Further, the pair of braces may be configured to be bolted together with the fixed portion interposed therebetween. According to the seismic structure having this configuration, since the pair of braces are bolted together with the fixed portion sandwiched therebetween, it is possible to suppress the deviation of the structural force transmitted from the brace to the fixed portion.

  The brace includes an axial force member and a plate-like fixing piece that is provided at an end portion in the longitudinal direction of the axial force member and is fixed to the fixing portion, and the fixing piece is displaced from the axial center of the axial force member. The axial force member may be arranged at the fixed portion side of the fixed piece in the thickness direction of the wall body including the pair of columns in a state where the fixed piece is fixed to the fixed portion. Good. According to the earthquake-resistant structure having this configuration, the axial force member can be disposed on the fixed portion side, and thus the wall body including the brace can be thinned.

  The brace includes an axial force member and a plate-like fixing piece that is provided at an end portion in the longitudinal direction of the axial force member and is fixed to the fixing portion, and the fixing piece is displaced from the axial center of the axial force member. The axial force member is arranged on the side opposite to the fixed part side of the fixed piece in the thickness direction of the wall body including the pair of columns in a state where the fixed piece is fixed to the fixed part. The structure which is may be sufficient. According to the earthquake-resistant structure having this configuration, the axial force member is disposed on the side opposite to the fixed portion side, interference between the axial force members can be suppressed, and the outer diameter of the axial force member can be increased. .

  Moreover, the brace has an axial force member, and the outer diameters of the axial force members may be different from each other in the pair of braces. Thus, the axial force borne by the pair of braces can be easily adjusted according to the required structural strength.

  Moreover, the structure by which the spacer is arrange | positioned between the fixing piece and fixing | fixed part of a brace may be sufficient. Thereby, since the space | interval of a pair of axial force material becomes large, interference between axial force materials can be suppressed.

  Further, an opening corresponding to the position and diameter of the bolt hole of the fixing portion may be formed, and a configuration may be provided that includes a reinforcing member that is fixed between the fixing portion and the fixing piece to reinforce the fixing portion. Thereby, the intensity | strength of a fixing | fixed part is improved and the brace which bears a bigger axial force can be used.

  The present invention is also a seismic reinforcement method for reinforcing a building including a pair of pillars, wherein the building is formed between a pair of pillars and a fixed part formed with bolt holes and fixed to the pillars or a part of the pillars. And existing braces fixed to the pair of pillars by being bolted to the fixing portion, and the seismic reinforcement method includes a releasing step of releasing the bolt connection for fixing the existing braces, A brace installation step in which a new brace is arranged in the same direction with respect to an existing brace, and the pair of braces are bolted to the fixed portion. In the brace installation step, the bolt of the fixed portion A common bolt is inserted into the hole, and the pair of braces are bolted to the same fixed portion by the common bolt.

  In this seismic retrofitting method, it is possible to add another brace in addition to the existing brace using the existing fixed part fixed to the column or part of the column, and the building is seismically strengthened. can do.

  According to the present invention, when fixing a pair of braces to a column, it is not necessary to perform quality control of welding, and work man-hours can be reduced.

It is a front view which shows the earthquake-resistant structure of 1st Embodiment of this invention. It is a perspective view which shows the column base part in FIG. It is a side view of the column base part shown in FIG. It is a front view of the column base part shown in FIG. It is a perspective view which expands and shows the junction part of the column head of a stud in FIG. 1, and a beam. It is a perspective view which expands and shows the junction part of the through pillar and beam in FIG. It is the schematic which shows the pattern of arrangement | positioning of a pair of brace. It is a front view which shows the reinforcing material fixed to the fixing | fixed part.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention will be described in detail with reference to the drawings. In addition, in each figure, the same code | symbol is attached | subjected to the same part or an equivalent part, and the overlapping description is abbreviate | omitted.

(Overall structure)
A wall structure 1 shown in FIG. 1 is a structure used for an outer wall portion or an inner wall portion of a steel structure building (for example, a prefabricated house using standardized columns, beams, or the like). The wall structure 1 includes a housing 2, and the housing 2 is configured by joining columns 3 and beams 4. Although this embodiment demonstrates the wall structure 1 of a ground floor, this wall structure 1 is installed also in each floor of two or more floors.

  A plurality of pillars 3 are provided in the vertical direction (Z direction) and spaced apart in the horizontal direction (X direction). In FIG. 1, a pair of columns 3 including a through column 5 and an inter-column 6 is illustrated. The through pillar 5 is arranged on the right side in the figure, extends from the first floor to the second floor, and extends upward from the beam 4 supported by the inter-column 6. The stud 6 is disposed on the left side in the figure and extends in the vertical direction between the foundation 7 and the beam 4.

  The through column 5 includes a column main body 8, a column head (not shown), and a column base 9, and the inter-column 6 includes a column main body 10, a column head 11, and a column base 12.

  The beam 4 is, for example, an H-shaped steel and extends in the horizontal direction. One end side (right end portion in the figure) of the beam 4 is fixed to the through pillar 5. Further, the beam 4 is supported from below by a spacer 6.

  The pillar 3 is fixed to the foundation 7 via anchor bolts 13 protruding upward from the foundation 7 of the building. Specifically, as shown in FIGS. 2 to 4, the column base portions 9 and 12 are fixed to the foundation 7 by anchor bolts 13.

(Column base)
Next, the column base 12 will be described with reference to FIGS. In FIG. 2, the column base 12 provided at the lower end of the column main body 10 in the inter-column 6 is shown, and in FIG. 3 and FIG. 4, the column base 9 provided at the lower end of the column main body 8 in the through column 5 is shown. . The column bases 9 and 12 have basically the same configuration although there are some differences.

  The column base portions 9 and 12 include a bottom plate 14 disposed on the foundation 7, a lower end plate 15 connected to the lower end portion of the column main body 10, and a fixing portion 16 connected to the bottom plate 14 and the lower end plate 15. ing. The bottom plate 14 is a rectangular plate, and the bottom plate 14 is provided with a plurality of bolt holes through which the anchor bolts 13 are inserted. The bottom plate 14 is disposed so that the thickness direction is along the vertical direction. In addition, the fixing | fixed part 16 of the stud 6 functions as a fixing | fixed part which fixes a pair of braces 31 and 32 mentioned later. The fixing portion 16 of the through pillar 5 functions as a fixing portion that fixes a pair of braces 33 and 34 described later.

  The lower end plate 15 is a rectangular plate and is welded to the lower end portions of the column main bodies 8 and 10. The lower end plate 15 is disposed such that the thickness direction is along the vertical direction, and is spaced apart from the bottom plate 14 in the vertical direction.

  The fixing portion 16 includes a first fixing plate 17 and a second fixing plate 18 arranged so as to cross each other, and is formed so that a cut surface cut in the horizontal direction forms a cross. The first fixing plate 17 is arranged so that the thickness direction is along the thickness direction of the wall of the building (the Y direction, the direction orthogonal to the longitudinal direction of the columns and the direction orthogonal to the direction in which the pair of columns face each other). Has been. The lower end portion of the first fixed plate 17 is welded to the bottom plate 14, and the upper end portion of the first fixed plate 17 is welded to the lower end plate 15. Similarly, the lower end of the second fixed plate 18 is welded to the bottom plate 14, and the upper end of the second fixed plate 18 is welded to the lower end plate 15. Further, the first fixing plate 17 is formed with a bolt hole through which the bolt 43 is inserted when the pair of braces 31 to 34 are bolted together. The bolt hole penetrates in the thickness direction of the first fixed plate 17. Bolt holes are processed at the factory. Further, the first fixing plate 17 and the second fixing plate 18 are arranged along a plane including the central axis of the column main bodies 8 and 10.

  Moreover, as FIG.3 and FIG.4 shows, the bolt hole is provided in the 2nd fixing plate 18 of the column base part 9 provided in the lower end part of the through pillar 5. As shown in FIG. The bolt hole provided in the second fixing plate 18 is disposed at a position higher than, for example, the bolt hole provided in the first fixing plate 17.

(Pillar head)
Next, the column head will be described with reference to FIG. The column head 11 includes an upper end plate 19 connected to the upper end portion of the column main body 10, a fixing portion 20 connected to the upper end plate 19, and a joining piece 21 joined to the beam 4. The upper end plate 19 is a rectangular plate and is welded to the upper end portion of the column main body 10. The upper end plate 19 is disposed so that the thickness direction is along the vertical direction.

  The joining piece 21 has a plate shape and is disposed so that the thickness direction is along the vertical direction, and is disposed apart from the upper end plate 19 in the vertical direction. Moreover, the joining piece 21 is arrange | positioned facing the lower flange 4c of the beam 4 in the up-down direction. The joint piece 21 is provided with a bolt hole (not shown) penetrating in the vertical direction. The joining piece 21 is formed by, for example, bending the upper end portion of the first fixing plate 22 of the fixing portion 20. The joining piece 21 is bent, for example, from the center of the column main body 10 to the outdoor side. The joining piece 21 is bolted to the lower flange 4c by using a bolt 45B penetrating the joining piece 21 and the lower flange 4c.

  The fixing portion 20 includes a first fixing plate 22 and a second fixing plate 23 arranged so as to cross each other, and is formed so that a cut surface cut in the horizontal direction forms a cross. The first fixed plate 22 is arranged so that the thickness direction is along the thickness direction of the wall of the building. In other words, the thickness direction of the first fixed plate 22 is arranged in a direction orthogonal to the direction in which the beam 4 extends in plan view. The lower end portion of the first fixed plate 22 is welded to the upper end plate 19, and the upper end portion of the first fixed plate 22 is bent in the plate thickness direction to form the joining piece 21 as described above. Further, the lower end portion of the first fixed plate 22 is welded to the upper end plate 19. The first fixing plate 22 of the fixing portion 20 functions as a fixing portion that fixes the pair of braces 33 and 34. Further, the first fixing plate 22 and the second fixing plate 23 are disposed along a plane including the central axis of the column main body 10.

(Junction between through column and beam)
FIG. 6 is an enlarged perspective view showing a joint portion between the through column 5 and the beam 4. In FIG. 6, the indoor side is shown obliquely from above. Further, FIG. 6 illustrates a case where the beams 4 are arranged on both sides of the through pillar 5. 1 shows a configuration in which the beam 4 is connected to one side of the through column 5, but as shown in FIG. 6, the beam 4 is connected to both sides of the through column 5 (both sides in the X direction). It may be configured. Although not shown, a beam extending in the thickness direction (Y direction) of the wall body may be connected to the through column 5.

  The beam 4 is bolted to the through-column 5 via the column-beam bonding hardware 24 and the gusset plate 25. The column beam joint metal 24 is bolted to the side wall 8 a of the column body 8, and the gusset plate 25 is welded to the longitudinal end of the beam 4. In the case of the beam 4 arranged on the right side of the figure in FIG. 6, a gusset plate 25 is arranged on the outdoor side of the web 4a, and in the case of the beam 4 arranged on the left side of the figure, the gusset plate is arranged on the indoor side of the web 4a. 25 is arranged.

  The side wall 8 a of the column main body 8 is provided with a plurality of bolt holes for fixing the column beam joint metal 24 to the column 5 through the column beam joint metal 24. The column beam joint hardware 24 includes a column side fixed piece 26 fixed to the side wall 8 a of the through column 5 and a beam side fixed piece 27 fixed to the gusset plate 25. The column-side fixing piece 26 and the beam-side fixing piece 27 have a plate shape and are arranged so as to cross each other, and the column-beam connecting metal piece 24 has a T shape.

  The column-side fixing piece 26 is in contact with the side wall 8 a of the through column 5 and is bolted to the through column 5. The column-side fixing piece 26 extends in the vertical direction, and the upper end portion of the column-side fixing piece 26 is formed so as to protrude above the upper flange 4b of the beam 4, and the lower end portion of the column-side fixing piece 26 is It is formed so as to protrude below the lower flange 4 c of the beam 4.

  The beam side fixing piece 27 is welded to the column side fixing piece 26, for example. The plate thickness direction of the beam-side fixing piece 27 is arranged along the plate thickness direction of the web 4 a of the beam 4. The beam-side fixing piece 27 extends in the vertical direction, and the upper end portion of the beam-side fixing piece 27 is formed so as to protrude above the upper flange 4b of the beam 4, and the lower end portion of the beam-side fixing piece 27 is It is formed so as to protrude below the lower flange 4 c of the beam 4. A plurality of bolt holes 28 are formed in the beam side fixing piece 27. The column beam joint hardware 24 functions as a fixing portion that fixes the pair of braces 31 and 32. Further, the beam-side fixing piece 27 of the column-beam joining hardware 24 is arranged along a plane including the central axis of the column main body 8.

  The gusset plate 25 has a plate shape, and in the direction in which the beam 4 extends, one end is joined to the column beam joint metal 24 and the other end is welded to the web 4 a of the beam 4. The gusset plate 25 and the column beam joint metal 24 are joined by bolts. In this embodiment, the gusset plate 25 is welded to the beam 4, but may be bolted to the beam 4. In addition, the structure which the column-beam joining metal fitting 24 is directly joined to the beam 4 may be sufficient.

(Brace)
Here, the wall structure 1 is provided with braces 31 to 34 arranged to be inclined with respect to the pair of columns 3 between the pair of columns 3 (5, 8). Specifically, the wall structure 1 includes a pair of braces 31 that connect the column beam joint metal (joint portion between the through column 5 and the beam 4) 24 connected to the through column 5 and the column leg portion 12 of the intermediate column 6. , 32 and a pair of braces 33, 34 that connect the column head 11 of the intermediate column 6 and the column base 9 of the through column 5. That is, the pair of braces 31, 32 and the pair of braces 33, 34 are arranged so as to intersect each other.

  The braces 31 to 34 include brace bodies (axial force members) 35 and 36, and a battledore (fixed piece) 41 provided with longitudinal ends of the brace bodies 35 and 36. One brace 31 of the pair of braces 31, 32 has a brace body 35, and the other brace 32 has a brace body 36. Similarly, one brace 33 of the pair of braces 33, 34 has a brace body 35, and the other brace 34 has a brace body 36. The brace bodies 35, 36 are provided with turnbuckles 37 that connect the plurality of rod-like members 35a, 36a in the longitudinal direction. The rod-shaped members 35a and 36a have, for example, a columnar shape.

  The battledore 41 is disposed at a position shifted from the axis of the rod-shaped members 35a and 36a. Specifically, the battledore 41 is welded to the outer peripheral surfaces of the rod-shaped members 35a and 36a. Further, the battledore 41 projects outward from the longitudinal ends of the rod-like members 35a and 36a in the longitudinal direction.

  Further, the battledore 41 is formed with a bolt hole penetrating in the thickness direction. The battledores 41 of the pair of braces 31 and 32 are arranged with a fixed part in between. Similarly, the battledores 41 of the pair of braces 33 and 34 are arranged with the fixed part interposed therebetween. As shown in FIG. 6, the battledore 41 at the upper end of the pair of braces 31 and 32 is bolted with a beam-side fixing piece 27 serving as a fixing portion interposed therebetween. The bolts 43 for fixing the two battled plates 41 to the beam-side fixing piece 27 are inserted into the bolt holes of the two battled plate 41 and the bolt holes of the beam-side fixing piece 27, respectively.

  As shown in FIG. 2, the lower end portions of the pair of braces 31 and 32 are bolted together with the first fixing plate 17 of the fixing portion 16 interposed therebetween. Bolts 43 for fixing the two battled plates 41 to the first fixed plate 17 are inserted into the bolt holes of the two battled plate 41 and the bolt holes of the first fixed plate 17, respectively.

  As shown in FIG. 5, the battledore 41 at the upper end of the pair of braces 33 and 34 is bolted with the first fixing plate 22 of the fixing unit 20 interposed therebetween. Bolts 43 for fixing the two battled plates 41 to the first fixed plate 22 are inserted into the bolt holes of the two battled plate 41 and the bolt holes of the first fixed plate 22, respectively.

  As shown in FIGS. 3 and 4, the battledore 41 at the lower end of the pair of braces 33, 34 is bolted with the first fixing plate 17 of the fixing portion 16 interposed therebetween. Bolts 43 for fixing the two battled plates 41 to the first fixed plate 17 are inserted into the bolt holes of the battledore 41 and the bolt holes of the first fixed plate 17, respectively.

  Further, in the pair of braces 31 to 34, the outer diameters of the axial force member 35a of one brace 31, 33 and the axial force member 36a of the other brace 32, 34 are different. The outer diameter of one axial force member 35a is larger than the outer diameter of the other axial force member 36a. The outer diameter of one axial force member 35a is about 17 mm, for example, and the outer diameter of the other axial force member 36a is about 11 mm, for example. Moreover, in a pair of braces 31-34, the board thickness of the battledore 41 is the same, for example. In the pair of braces 31 to 34, the thickness of the battledore 41 may be changed according to the outer diameter of the axial force members 35a and 36a. Thus, by changing the outer diameters of the axial force members 35a and 36a, the axial force borne by the braces 31 to 34 can be easily adjusted according to the required structural strength.

  Further, in the pair of braces 31 to 34, axial force members 35a and 36a are arranged outside the battledore 41 in the thickness direction of the building wall. In the pair of braces 31 to 34, the distance between the axial force members 35a and 36a is wider than the distance between the battledores 41 in the thickness direction of the wall body.

  Moreover, the structure by which the spacer is arrange | positioned between the battledore 41 and the fixing | fixed part (1st fixing plates 17 and 22, the beam side fixing piece 27) may be sufficient. Thereby, since the space | interval of a pair of rod-shaped member 35a, 36a becomes large, interference between rod-shaped member 35a, 36a can be suppressed.

  In such a wall structure 1, since the facing clad plates 41 of the pair of braces 31 and 32 are not joined by welding to the same fixed portion but by a common bolt 43, Quality control becomes unnecessary, and the number of work steps when joining the braces 31 and 32 can be reduced. Similarly, since the opposing wing plates 41 of the pair of braces 33 and 34 are bolt-bonded to the same fixed portion, the quality control of welding becomes unnecessary, and the work man-hour when joining the braces 33 and 34 is reduced. Can be reduced.

  Further, in this wall structure 1, the bolts 43 are inserted into the bolt holes of the first fixing plates 17 and 22 and the beam-side fixing piece 27, and both sides of the first fixing plates 17 and 22 and the beam-side fixing piece 27 are sandwiched. Therefore, the bias of the structural force transmitted from the braces 33 and 34 to the first fixed plate 17 can be suppressed. The shear stress acting on the bolt 43 can be dispersed at a plurality of locations. Compared with a case where one brace is thickened and reinforced, the one reinforced with two braces can disperse the shear stress acting on the bolt 43 and suppress an increase in the bolt diameter. Can do.

(Seismic reinforcement method)
Next, the seismic reinforcement method will be described. Here, for example, a case will be described in which, in addition to existing braces 31 and 33, new new braces 32 and 34 are added and the building is subjected to seismic reinforcement at the time of extension or renovation of an existing building. As the existing braces 31, 33, the upper end of the brace 31 is bolted to the through column 5, the lower end of the brace 31 is bolted to the column base 12 of the intermediate column 6, and the upper end of the brace 33 is the head of the intermediate column 6. The lower end of the brace 33 is bolted to the column base 9 of the through column 5. The braces 31 and 33 are disposed between the pair of columns 3 so as to be inclined with respect to the pair of columns 3.

  In the existing state, the battledore 41 of the braces 31 and 33 is bolted to the fixed part. Further, the axial force member 35a is disposed on the inner side (fixed part side) than the battledore 41 in the thickness direction of the wall body. And as another new brace 32 and 34, the upper end part of the brace 32 is joined to the pillar 5 through the lower end part, the lower end part of the brace 32 is joined to the column leg part 12 of the intermediate pillar 6, and the upper end part of the brace 34 is joined to the pillar 6 part. The case where it joins to the column head 11 and joins to the column base part 9 of the pillar 5 through the lower end part of the brace 34 is demonstrated.

  In the seismic reinforcement method, first, the existing braces 31, 33 are removed. Here, the bolt nut which fixes the existing braces 31 and 33 is loosened, and the releasing step for releasing the bolt joint is performed.

  Next, the bolts 45A joined to the pillars 5 through the beam-to-column joining hardware 24 are replaced. The column beam joint 24 is fixed by a plurality of (for example, four) bolts 45A, and the bolts are replaced one by one. At this time, the bolt 45A having a higher strength than the existing bolt 45A is replaced.

  Next, the spacer 6 is exchanged. Specifically, instead of the existing pillar 6, another new pillar 6 is installed. In the column base 12 of the new stud 6, the thickness of the first fixing plate 17 and the second fixing plate 18 is thicker than that of the column base 12 of the existing stud 6. Similarly, in the column head 11 of the new stud 6, the thickness of the first fixing plate 22 and the second fixing plate 23 is thicker than that of the column head 11 of the existing stud 6. Furthermore, the bolt 45B that joins the stud 6 and the beam 4 is replaced with a bolt 45B having higher strength than the existing bolt 45B.

  In addition, in an earthquake-proof reinforcement method, you may continue using the existing volt | bolt and the stud 6 without implementing volt | bolt exchange and the exchange of the stud 6. In this case, the existing bolt holes can be reused, and the number of work steps can be reduced.

  Next, the brace installation process which installs the existing braces 31 and 33 removed and new new braces 32 and 34 with respect to a pair of pillar 3 is implemented. At this time, the existing brace 31 and the new brace 32 are arranged in the same direction as a pair of braces 31, 32, and the lower end is fixed to the beam-to-column joint 24 connected to the column 5 through the upper end. It fixes to the column base part 12 of the stud 6. Further, the existing brace 33 and the new brace 34 are arranged in the same direction as a pair of braces 33, 34, the upper end portion is fixed to the column head 11 of the intermediate column 6, and the lower end portion is passed through the column base portion of the column 5. Fix to 9.

  In the existing braces 31 and 33, in the thickness direction of the wall body, the battledore 41 is arranged on the outer side (opposite to the fixed portion), and the axial force member 35a is bonded on the inner side (fixed portion side). It was. In the brace installation process, when the pair of braces 31 to 34 are disposed, the battledore 41 is disposed on the inner side and the axial force members 35a and 36a are disposed on the outer side in the thickness direction of the wall body. In the braces 31 and 33, the arrangement of the axial force member 35a with respect to the battledore 41 in the thickness direction of the wall body is different before and after being removed.

  Further, in this brace installation process, the pair of braces 31 to 34 are attached to the fixed portion by using bolts 43 having higher strength than the existing bolts 43 instead of the bolts 43 that are joined to the existing braces 31 and 33. And bolt it together. In addition, it is not necessary to use a bolt whose strength is higher than that of an existing bolt.

  In the brace installation process, when the upper ends of the pair of braces 31 and 32 are fixed, the bolt 43 is inserted into the bolt hole of the beam-side fixing piece 27 of the beam-to-column fitting 24, and the hanger plate 41 is attached by the bolt 43. Bolts are joined to the column beam joining hardware 24. When the lower ends of the pair of braces 31 and 32 are fixed, the bolt 43 is inserted into the bolt hole of the first fixing plate 17 of the fixing portion 16, and the hanger plate 41 is attached to the first fixing plate 17 by the bolt 43. And bolt it together.

  In the brace installation process, when fixing the upper ends of the pair of braces 33, 34, the bolt 43 is inserted into the bolt hole of the first fixing plate 22 of the fixing portion 20, and the battledore 41 is moved first by the bolt 43. The fixing plate 22 is bolted. When fixing the lower ends of the pair of braces 33, 34, a bolt 43 is inserted into the bolt hole of the first fixing plate 17 of the fixing portion 16, and the blade plate 41 is attached to the first fixing plate 17 by the bolt 43. And bolt it together.

  According to such a seismic reinforcement method, a new brace 32, in addition to the existing braces 31, 33, using the existing fixed portion fixed to the column or an existing fixed portion which is a part of the column. 34 can be added and the existing building can be seismically strengthened.

  In this seismic reinforcement method, since the opposing clad plates 41 of the pair of braces 31 and 32 are bolted to the same fixed portion, the quality control of welding becomes unnecessary, and the work man-hour when joining the braces 31 and 32 is reduced. Can be reduced. Similarly, since the opposing wing plates 41 of the pair of braces 33 and 34 are bolt-bonded to the same fixed portion, the quality control of welding becomes unnecessary, and the work man-hour when joining the braces 33 and 34 is reduced. Can be reduced.

  In addition, since the existing bolt holes are used and the common bolts 43 are used to join the bolts, it is not necessary to process new bolt holes at the site, and an increase in field work can be suppressed.

  In this seismic reinforcement method, bolts 43 are inserted into the bolt holes of the first fixing plates 17 and 22 and the beam-side fixing piece 27, and the blade plates 41 are placed on both sides of the first fixing plates 17 and 22 and the beam-side fixing piece 27. Since it arrange | positions, the bias | inclination of the structural force transmitted to the fixing | fixed part from the braces 31-34 can be suppressed.

  Moreover, it is preferable that the bolt hole of the fixing | fixed part of the column base parts 9 and 12 is located above a floor slab. As a result, when new braces 32 and 34 are added, the column base portions 9 and 12 and the new braces 32 and 34 can be bolted together without removing the floor slab or the like. Is simplified.

(Placement of a pair of braces)
Next, with reference to FIG. 7, the arrangement pattern (Examples 1-5) of a pair of braces will be described. FIG. 7 illustrates a state in which the lower ends of the pair of braces 31 and 32 are joined to the column base 12 of the intermediary column 6. Moreover, in FIG. 7, the brace 31 is arrange | positioned at the indoor side and the brace 32 is arrange | positioned at the outdoor side. That is, the battledore 41 of the brace 31 is disposed on the indoor side of the first fixed plate 17, and the battledore 41 of the brace 32 is disposed on the outdoor side of the first fixed plate 17.

  Further, the pair of braces 33 and 34 that intersect with the pair of braces 31 and 32 are not shown in FIG. 7, but the brace 33 is disposed on the outdoor side and the brace 34 is disposed on the indoor side. That is, the battledore 41 of the brace 33 is disposed on the outdoor side of the first fixed plate 17, and the battledore 41 of the brace 34 is disposed on the indoor side of the first fixed plate 17. The braces 31 and 34 may be disposed on the outdoor side, and the braces 32 and 33 may be disposed on the indoor side.

  FIG. 7A shows an arrangement pattern of the first embodiment. In the first embodiment, the axial force members 35a and 36a of the pair of braces 31 and 32 are arranged on the outer side than the respective battledores 41 in the thickness direction of the wall body. Similarly, the axial force members 35a and 36a of the pair of braces 33 and 34 that intersect with the pair of braces 31 and 32 are arranged on the outer side than the respective battledores 41 in the thickness direction of the wall body. Moreover, the four braces 31-34 are arrange | positioned in order of the braces 31, 34, 32, 33 from the indoor side to the outdoor side in the part which these cross | intersect, for example.

  In the thickness direction of the wall body, the braces 31 and 34 are arranged on one side and the braces 32 and 33 are arranged on the other side with the first fixing plate 17 interposed therebetween. As described above, since the braces 31 to 34 are bolted with the first fixing plate 17 interposed therebetween, it is possible to suppress the bias of the structural force transmitted from the braces 31 to 34 to the first fixing plate 17. Further, when the axial force members 35a and 36a are arranged outside the battledore 41 in the thickness direction of the wall body, the interference between the axial force members 35a and 36a can be suppressed, and the axial force members 35a and 36a. The outer diameter can be increased. Even when the outer diameter is larger, interference between the axial force members 35a and 36a can be suppressed.

  FIG. 7B shows an arrangement pattern of the second embodiment. In the second embodiment, the axial force member 35a is disposed outside the battledore 41 (on the side opposite to the fixed portion) in the thickness direction of the wall body, and the rod-shaped member 36a is disposed on the inner side of the battledore 41 in the wall thickness direction. It is arranged on the (fixed part side). Further, in the second embodiment, a gap adjusting metal (spacer) 46 is disposed between the battledore 41 connected to the rod-shaped member 36 a and the first fixed plate 17. Thereby, the plate | board thickness of the metal fitting 46 for space | interval adjustment can be adjusted, and arrangement | positioning of the rod-shaped member 36a in the thickness direction of a wall body can be adjusted. Thus, by adjusting the position of the axial force member 36a, it is possible to prevent interference with the other rod-shaped member 35a.

  The interval adjusting hardware 46 is provided with a notch (opening) for allowing the bolt 43 to pass therethrough. Alternatively, the interval adjusting hardware may be provided at a position where it does not interfere with the bolt 43, for example, at an upper and lower position avoiding the bolt 43.

  FIG. 7C shows an arrangement pattern of the third embodiment. In the third embodiment, the arrangement pattern of the axial force members 35a and 36a is the same as that of the second embodiment, but the arrangement of the spacing adjusting hardware 47 and 48 is different. The spacing adjustment hardware 47 and 48 is about half the thickness of the spacing adjustment hardware 46, and one spacing adjustment hardware 47 is formed between the battledore 41 connected to the axial force member 36 a and the first fixed plate 17. The other gap adjusting metal 48 is disposed between the battledore 41 connected to the axial force member 35 a and the first fixed plate 17.

  FIG. 7D shows an arrangement pattern of the fourth embodiment. In the fourth embodiment, the axial force member 35a is disposed inside the battledore 41 in the wall thickness direction, and the axial force member 36a is disposed outside the battledore 41 in the wall thickness direction. Further, in the fourth embodiment, a gap adjusting metal piece 49 is disposed between the battledore 41 connected to the axial force member 36 a and the first fixed plate 17. For example, the distance adjusting metal piece 49 is thicker than the distance adjusting metal piece 46 of the second embodiment. The plate thickness here is the length along the axial direction of the bolt 43.

  Further, as a modification of the fourth embodiment, there is a configuration in which the arrangement pattern of the axial force members 35a and 36a is the same as that of the fourth embodiment, but the arrangement and thickness of the interval adjusting hardware are different. Specifically, the interval adjusting hardware having a thickness about half that of the interval adjusting metal 49 is arranged on both sides of the first fixing plate 17. Thereby, arrangement | positioning of the four braces 31-34 can be shifted suitably.

  FIG. 7E shows an arrangement pattern of the fifth embodiment. In the fifth embodiment, the axial force members 35a and 36a are disposed on the inner side of the respective battledores 41 in the thickness direction of the wall body. Further, in the fifth embodiment, the interval adjusting hardware 50 is disposed between the battledore 41 connected to the axial force member 36 a and the first fixed plate 17. For example, the distance adjusting hardware 50 is thicker than the distance adjusting metal 49 of the fourth embodiment.

  Further, as a modification of the fifth embodiment, there is a configuration in which the arrangement pattern of the axial force members 35a and 36a is the same as that of the fifth embodiment, but the arrangement and thickness of the interval adjusting hardware are different. Specifically, interval adjusting hardware having a thickness about half that of the interval adjusting metal 50 is arranged on both sides of the first fixed plate 17. Thereby, arrangement | positioning of the four braces 31-34 can be shifted suitably. As another modified example, the arrangement pattern of the axial force members 35a and 35a is the same as that of the fifth embodiment, and a configuration in which the interval adjusting hardware is not arranged may be employed. Thereby, the wall body containing a brace can be made thin.

(Reinforcing material)
Next, with reference to FIG. 8, the reinforcing material provided in the fixing portion will be described. The reinforcing member 51 is provided with an opening 51 a corresponding to the position and diameter of the bolt hole 17 a of the first fixing plate 17. The reinforcing member 51 is disposed at a position where the bolt hole 17a of the first fixing plate 17 and the opening 51a overlap each other, and is fixed between the first fixing plate 17 and the blade plate 41 of the braces 31 to 34 by tightening the bolt 43. The With the configuration including such a reinforcing material, the strength of the first fixing plate 17 is improved, and the braces 31 to 34 bearing a larger axial force can be used. The reinforcing material 51 may be joined to the first fixing plate 17 by bolts or screws, or may be fixed by welding.

  The reinforcing material 51 may be provided only on one side of the first fixed plate 17 or may be provided on both sides. With such a reinforcing member 51, the strength around the bolt hole 17a of the first fixing plate 17 can be improved. The reinforcing material 51 can also be used as the above-described spacing adjustment hardware. Further, the reinforcing member 51 may be provided for the bolt hole of the first fixing plate 22 or the bolt hole of the column beam joint hardware 24.

  The reinforcing material is not limited to the flat plate as in the present embodiment as long as the strength around the bolt hole of the first fixing plate 17 can be improved. It may be a hardware formed in a three-dimensional combination.

  The present invention is not limited to the above-described embodiments, and various modifications as described below are possible without departing from the gist of the present invention.

  In the above embodiment, the outer diameters of the axial force members 35a and 36a are different in the pair of braces 31 to 34, but the outer diameters of the axial force members 35a and 36a may be the same.

  Moreover, although said embodiment demonstrated the structure by which a pair of braces 31-34 are arrange | positioned along with the thickness direction (Y direction) of the wall body of a building, a pair of braces 31-34 are an up-down direction. You may arrange | position along with (Z direction). Moreover, a pair of braces 31-34 may be arrange | positioned along with the other direction.

  In the above-described embodiment, the configuration in which the battledore 41 provided at the ends of the axial force members 35a and 36a is disposed at a position shifted from the axial center of the axial force members 35a and 36a has been described. A configuration in which the battledore 41 is disposed on the axial center of the axial force members 35a and 36a may be employed.

  Moreover, in said embodiment, although the structure where a pair of braces 31-34 mutually cross | intersect is demonstrated, the structure by which a pair of braces 31-34 are arrange | positioned only in one direction may be sufficient. . For example, a configuration including a pair of braces 31 and 32 and not including a pair of braces 33 and 34 may be employed, or a configuration including a pair of braces 33 and 34 and not including a pair of braces 31 and 32 may be employed. Moreover, the structure which crosses with respect to a pair of braces 31 and 32 may be one. Moreover, the structure by which three or more braces are arrange | positioned in the same direction may be sufficient.

  Moreover, in the said embodiment, although the braces 31-34 are being fixed with respect to the column base parts 9,12, the column head 11, and the column beam joining metal fitting 24, the fixing | fixed part, column fixed to the column main bodies 8,10 The braces 31 to 34 are joined to other fixing parts such as a fixing part fixed to the leg parts 9 and 12, a fixing part fixed to the column head 11, and a fixing part fixed to both the column 3 and the beam 4. Also good.

  Moreover, in the said embodiment, although the case where the hung board 41 is bolt-joined with respect to the 1st fixing plates 17 and 22 is illustrated, the hung board 41 is bolt-joined with respect to the 2nd fixing plates 18 and 23. May be.

  Moreover, although the said embodiment demonstrated the structure by which the battledore 41 was provided as a plate-shaped fixing piece in the edge part of the brace main bodies 35 and 36, in the edge part of the brace main bodies 35 and 36, other The structure which the edge part of the shape of this is provided and the bolt hole for bolt joining to this edge part is formed may be sufficient. For example, a brace in which a bolt hole is formed at a prismatic, cylindrical, or semicircular end may be used.

  Moreover, in the said embodiment, although the brace main body 35 and 36 illustrated about the structure provided with rod-shaped axial force material 35a, 36a, axial force material 35a, 36a may be a plate-shaped member, and other shapes, such as prismatic shape, A shaped member may be used.

  Moreover, in the said embodiment, although illustrated about the structure by which a pair of braces 31-34 are arrange | positioned between the through pillar 5 and the interposition pillar 6 which are a pair of pillar 3, a pair of pillar 3 is the through pillar 5 adjacent. , 5 may be sufficient, and the adjacent pillars 6 and 6 may be sufficient.

  Moreover, in the said embodiment, although a pair of braces 31-34 are arrange | positioned in the 1st floor part, you may arrange | position in the 2nd floor or more part.

  DESCRIPTION OF SYMBOLS 1 ... Wall structure, 3 ... Column, 4 ... Beam, 5 ... Through column, 6 ... Intermediary column, 9, 12 ... Column base part, 11 ... Column head, 17, 22 ... 1st fixing plate (fixing part), 27 ... Beam side fixed piece (fixed part), 31-34 ... brace, 35, 36 ... brace body, 35a, 36a ... axial force material, 41 ... battledore (fixed piece), 43 ... bolt, 46-50 ... hardware for adjusting distance (Spacer).

Claims (8)

An earthquake-resistant structure in which braces are arranged between a pair of columns,
A bolt hole is formed and fixed to the column or a part of the column; and
A pair of braces extending in the same direction between the pair of pillars and fixed to the fixing portion;
An earthquake-resistant structure in which the pair of braces are bolted to the same fixed portion by a common bolt inserted into the bolt hole of the fixed portion.   The earthquake-resistant structure according to claim 1, wherein the pair of braces are bolted together with the fixed portion interposed therebetween. The brace includes an axial force member, and a plate-like fixing piece that is provided at an end portion in the longitudinal direction of the axial force member and is fixed to the fixing portion.
The fixed piece is disposed at a position shifted from the axial center of the axial force member,
The axial force member is disposed closer to the fixed portion than the fixed piece in the thickness direction of the wall body including the pair of columns in a state where the fixed piece is fixed to the fixed portion. The earthquake-resistant structure according to 1 or 2. The brace includes an axial force member, and a plate-like fixing piece that is provided at an end portion in the longitudinal direction of the axial force member and is fixed to the fixing portion.
The fixed piece is disposed at a position shifted from the axial center of the axial force member,
The axial force member is disposed on the opposite side of the fixed part from the fixed piece in the thickness direction of the wall body including the pair of columns in a state where the fixed piece is fixed to the fixed part. The earthquake-resistant structure according to claim 1 or 2. The brace has an axial force member,
The earthquake-resistant structure according to any one of claims 1 to 4, wherein in the pair of braces, outer diameters of the axial force members are different from each other.   The earthquake-resistant structure as described in any one of Claims 1-5 in which the spacer is arrange | positioned between the fixed piece of the said brace, and the said fixing | fixed part.   The opening according to the position and diameter of the said bolt hole of the said fixing | fixed part is formed, The reinforcement board which is fixed between the said fixing | fixed part and the said fixing piece, and reinforces the said fixing | fixed part is provided. The earthquake-resistant structure as described in one. A seismic reinforcement method for reinforcing a building including a pair of columns,
The building is
A fixing portion in which a bolt hole is formed and fixed to the pillar, or a part of the pillar;
An existing brace that is disposed between the pair of columns and is bolted to the fixing portion to be fixed to the pair of columns,
The seismic reinforcement method is
A releasing step of releasing the bolt joint for fixing the existing brace;
A brace installation step in which a new brace is arranged in the same direction with respect to the existing brace, and the pair of braces are bolted to the fixing portion, and
In the brace installation step, an earthquake-proof reinforcement method in which a common bolt is inserted into the bolt hole of the fixed portion, and the pair of braces are bolted to the same fixed portion by the common bolt.

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