JP2006002388A - Aseismatic reinforcing structure of building - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a strong aseismatic reinforcing structure, by applying tensional force to a rope by a tensional force adjusting means, by strongly connecting columns by the rope of an aseismatic reinforcing means, by improving working efficiency for constructing the aseismatic reinforcing structure, by adjusting the tensional force of the rope by the tensional force adjusting means disposed in a midway part of the rope, by securely connecting the columns through studs by the rope of the aseismatic reinforcing means, when constructing the aseismatic reinforcing structure in a frame body of a building. <P>SOLUTION: This building constructs the frame body of a wall part by a sill part, a girder parallel to the sill part, a plurality of columns erected up to the girder from the sill part, and the stud arranged at a predetermined interval between the columns, and is constituted so as to arrange the aseismatic reinforcing means having the rope for connecting the mutual columns via the stud and the tensional force adjusting means for adjusting the tensional force of the rope. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a seismic reinforcement structure for a building, and in particular, when constructing a seismic reinforcement structure in a frame of a building, the inter-columns are communicated with each other by means of a rope of a seismic reinforcement means, and the middle part of the rope is connected. The tension of the rope is adjusted by the tension adjusting means arranged to improve the workability of construction of the seismic reinforcement structure, and the tension between the columns is firmly connected by the rope of the earthquake-proof reinforcement means. The present invention relates to a seismic reinforcement structure for a building that imparts tension to a rope by means and maintains a strong seismic reinforcement structure.

  Last year, a large-scale earthquake occurred in the Kansai and Shikoku areas, and the situation of the earthquake was unusually large.

  In particular, emphasis is put on the earthquake-resistant structure of buildings in ordinary houses and high-rise buildings, which are wooden houses. Among them, earthquake-resistant structures are not only made for ordinary houses when they are newly built, but also when existing buildings are renovated. There are measures such as applying

JP 2003-097083 A JP 2003-147857 A JP 2003-227236 A JP 2003-232133 A JP 2004-019161 A Japanese Patent No. 3289710 Japanese Patent No. 3401747

  By the way, in conventional buildings, especially ordinary houses, a concrete foundation is laid, a wooden foundation is installed above the concrete foundation, and a plurality of pillars are erected on the foundation. The upper part of the wall is connected with a girder to construct the frame of the wall.

  That is, as shown in FIGS. 5 and 6, the parallel base portion 102 and the girder 104 are connected by a plurality of pillars 106 to form a frame body 108, and a predetermined interval between the pillars 106 of the frame body 108, for example, A stud 110 is provided every 45 cm.

  At this time, in the formation state of the wall portion of the ordinary house, as shown in FIG. 7, the pillar 106 is covered with the wall portion 116 composed of the inner wall 112 and the outer wall 114, or as shown in FIG. Some have a structure in which a wall 116 is attached between them.

  However, in the structure described above, that is, the structure in which the pillars 110 are arranged at predetermined intervals, for example, every 45 cm, between the pillars 106 of the frame body 108, when a horizontal vibration occurs in FIG. As shown, the pillars 106 and the intermediate pillars 110 of the frame 108 are deformed, and it cannot be said that they have an earthquake-resistant structure.

  In order to solve this problem, as shown in FIG. 9, a wooden brace 218 is provided diagonally between the columns 206 of the frame body 208, or diagonally between the columns 306 of the frame 308 as shown in FIG. In some cases, a metal wire 320 and a turnbuckle 322 are provided.

  In the brace 218 and the wire 320 described above, generally, in order to obtain an oblique state, a part of the studs 210 and 310 disposed between the pillars 206 and 306 is cut off, and the brace 218 is fixed to the stud 210, Measures are taken to avoid interference between the wire 320 and the stud 310.

  However, in the above-mentioned structure for handling bracing, it can be used at the time of new construction, but at the time of reconstruction, the bracing cannot be attached to the surface of the wall or it is difficult to work in a small space. There is an inconvenience that it is necessary to remove and then perform construction.

  In addition, the wire handling structure can naturally cope with new construction, and at the time of renovation, it can be reduced by removing the small-area wall part of the bracket part that fixes both ends of the wire and the installation part of the turnbuckle. Although it is possible to cope with work in a space, improvement is desired because it is impossible to cope with a case where wood or the like is deformed due to secular change and the wire is loosened.

  Therefore, in order to eliminate the above-mentioned inconveniences, the present invention provides a base part, a girder parallel to the base part, a plurality of columns erected from the base part to the girder, and a predetermined interval between the pillars. In the building which constructs the frame of the wall portion with the studs arranged on the bridge, the bridge has a cord connecting the pillars via the stud and tension adjusting means for adjusting the tension of the cord. It is characterized by providing seismic reinforcement means.

  As described above in detail, according to the present invention, a base portion, a girder parallel to the base portion, a plurality of columns erected from the base portion to the girder, and a predetermined interval between the columns are arranged. In the building that constructs the frame of the wall portion with the studs that are made, the seismic reinforcement means that has the ropes that connect the pillars via the studs and the tension adjustment means that adjusts the tension of the ropes is provided Therefore, the seismic reinforcement structure can be easily built in the frame body, the workability can be improved, and the ropes of the seismic reinforcement means of this seismic reinforcement structure can be firmly connected between the columns, and the balance It is possible to provide a flexible structure with a high tenacity by allowing the entire support to be removed, and the tension adjusting means can apply a tension to the rope and maintain a strong seismic reinforcement structure. Also, when constructing the seismic reinforcement structure in the frame, there is no problem at the time of new construction, and at the time of reconstruction, there is a need for a wall part, that is, the fixing of both ends of the rope of the seismic reinforcement means and the seismic reinforcement means. Since it is possible to cope with work in a small space by removing only the attachment site of the tension adjusting means and changing the installation position of the tension adjusting means, it copes with seismic reinforcement of existing buildings Therefore, a highly versatile seismic reinforcement structure can be realized.

  As a result of the invention as described above, when constructing a seismic reinforcement structure in the frame body, the tension adjusting means arranged in the middle part of the rope by connecting the pillars via the studs by the rope of the earthquake-proof reinforcement means By adjusting the tension of the rope.

  Embodiments of the present invention will be described below in detail with reference to the drawings.

  FIG. 1 shows a first embodiment of the present invention. 1 (a) and 1 (b), 2 is a seismic reinforcement structure built in a frame (not shown) of a building (not shown), 4 is a space formed in the frame (not shown), and 6 is a pillar ( (Not shown in the figure), a stud 8 is provided between the inner wall 10 constituting a part of the wall part, and the outer wall 10 constituting a part of the wall part.

  Here, although this 1st Example is explaining the state after taking necessary measures, such as excision of only a necessary part of a wall part at the time of reconstruction, or positioning a turnbuckle near the excision part, In order to facilitate the process, it is described that the display of the cut position of the wall portion is omitted. And, of course, it can be used when building a new building.

  The frame includes a wooden base portion, a girder parallel to the base portion, a plurality of columns erected from the base portion to the girder, and a stud 6 disposed at predetermined intervals between the columns. The space part 4 appears inside.

  And it is set as the structure which provides the seismic reinforcement means 16 which has the rope 12 which connects between the said pillars via the said pillar 6, and the tension | tensile_strength adjustment means 14 which adjusts the tension | tensile_strength of this rope 12. FIG.

  More specifically, as shown in FIG. 1, the seismic reinforcement means 16 includes two first and second pulleys 18-1 and 18-2 disposed in the space 4 between the columns, and One rope 12 wound around the first and second pulleys 18-1 and 18-2 and connecting the pillars via the stud 6, and the rope 12 urged in the tension direction 12 tension force adjusting means 14 for adjusting the tension force.

  That is, in the space portion 4, the first and second pulleys 18-1 and 18-2 are disposed on the left and right upper portions of the space portion 4, and the rope 12 having one end fixed to the lower right portion is connected to the upper left first portion. The first pulley 18-1 is wound, and then the second upper pulley 18-2 is wound, and the other end is fixed to the lower left portion.

  At this time, when fixing the first and second pulleys 18-1 and 18-2, it is possible to use a pillar or a girder to attach the pulleys. Since the pulling force in the direction of the center position of the portion 4 acts on the first and second pulleys 18-1 and 18-2, the first and second pulleys 18 that can counter the pulling force by examining a known mounting method. -1, 18-2 needs to be attached.

  Since the strip 12 passes through the center height portion and the upper portion of the stud 6, the first cut portion 20 is formed at the center height portion of the stud 6 as shown in FIG. The second excision 22 is formed.

  In addition to the measures for forming the first and second cutout portions 20 and 22 in the stud 4, a through-hole portion (see the one-dot chain line portion in FIG. 1 (b)) is formed in the stud 6. Is also possible.

  Further, a tension adjusting means 14 is provided in the vicinity of the other end of the lower left portion of the rope 12. The tension force adjusting means 14 includes a spring that urges the rope 12 in the tension direction by a contraction force and adjusts the tension of the rope 12.

  Further, a turnbuckle 24 for adjusting the length of the rope 12 is provided in the middle of the rope 12 in order to impart tension to the rope 12.

  In addition, in the 1st cutting part 20, in the 1st cutting part 20, when the rope 12 contacts, the treatment which changes the attachment position of the 1st, 2nd pulley 18-1, 18-2 to the inner wall 8 or the outer wall 10 side. Alternatively, if the first and second pulleys 18-1 and 18-2 are inclined with respect to the inner wall 8 or the outer wall 10, it is possible to avoid contact with the rope 12.

  Next, the operation will be described.

  When constructing the seismic reinforcement structure 2 in the space portion 4 formed in the frame of the building, one end of the rope 12 is fixed to the lower right portion of the space portion 4, and the rope 12 is attached to the space portion 4. The first pulley 18-1 fixed to the upper left part of the space 4 is wound after passing through the first excision 20 of the stud 6 located at the intermediate part.

  Then, the rope 12 is passed from the first pulley 18-1 fixed to the upper left part of the space part 4 to the second pulley 18-2 side of the upper right part via the second excision part 22 of the intermediate pillar 6, and the space After the first pulley 18-2 fixed to the upper right part of the part 4 is wound, the rope 12 is passed through the first excision part 20 of the stud 6 positioned at the intermediate part of the space part 4, and the other end is space. It fixes to the lower left part of the part 4.

  At this time, a turnbuckle 24 is interposed in the middle of the rope 12 between the first pulley 18-2 and the first cutout portion 22 of the intermediate post 6, and between the first cutout portion 22 of the intermediate post 6 and the other end. The tension adjusting means 14 is interposed in the middle of the rope 12.

  In addition, when the winding operation of the rope 12 to the first and second pulleys 18-1 and 18-2 and the fixing of both ends are completed, against the urging force of the tension adjusting means 14, The turnbuckle 24 is rotated to adjust the length of the rope 12, and tension is applied to the rope 12.

  At this time, when the rope 12 is loosened due to deformation of wood or the like due to secular change, the looseness of the rope 12 is avoided by the urging force of the tension adjusting means 14, that is, the contraction force.

  Thus, the frame 12 is provided with the seismic reinforcement means 16 having the rope 12 that communicates between the pillars via the spacer 6 and the tension adjusting means 14 that adjusts the tension of the rope 12. The seismic reinforcement structure 2 can be easily constructed in the space 4 formed in the body, workability can be improved, and the rope 12 of the seismic reinforcement means 16 of the seismic reinforcement structure 2 can firmly fix the columns. The tension can be applied to the rope 12 by the tension adjusting means 14 and the tension can be applied to the cord 12 by the tension adjusting means 14. The seismic reinforcement structure 2 can be maintained.

  Further, when the seismic reinforcement structure 2 is constructed in the space portion 4 formed in the frame body, there is no problem at the time of new construction, and at the time of reconstruction, the inner wall 8 or the outer wall 10 constituting a part of the wall portion is necessary. By excision of the location, that is, the both ends fixing portion of the rope 12 and the attachment portions of the first and second pulleys 18-1 and 18-2, and changing the installation position of the tension adjusting means 14 and the turnbuckle 24, etc. If this is dealt with, it is possible to cope with work in a small space, so that it is possible to deal with seismic reinforcement of existing buildings, and it is possible to realize a highly versatile seismic reinforcement structure 2.

  Further, the tension adjusting means 14 is constituted by a spring that urges the rope 12 in a tension direction by a contracting force and adjusts the tension of the rope 12, thereby providing the tension provided only at one place. The force adjusting means 14 can maintain the tension of the rope 12 in an appropriate state by the contraction force that urges the rope 12 in the tension direction, and can maintain the solid state of the seismic reinforcement structure 2. In addition, even if the rope 12 is loosened due to deformation of wood or the like due to aging, although the tension force is slightly reduced, the rope 12 is urged by the urging force of the tension adjusting means 14, that is, the contraction force. Can be avoided, which is practically advantageous.

  FIG. 2 shows a second embodiment of the present invention. In the second embodiment, portions that perform the same functions as those of the first embodiment will be described with the same reference numerals.

  The feature of the second embodiment is that the seismic reinforcing means 32 is provided with one pulley 34 provided at the central height portion of the intermediate pillar 6 disposed in the space 4 between the pillars, and the pulley 34. Two first and second ropes 36-1 and 36-2 that are wound and communicated with each other through the pillars 6 and the first and second ropes 36-1 and 36-2 are connected to each other. There exists in the point which comprised in the tension | tensile_strength adjustment means 38 which urges | biass in a tension | tensile_strength direction and adjusts the tension | tensile_strength of the 1st, 2nd strip 36-1, 36-2.

  That is, as shown in FIG. 2, a cut portion 40 is formed at the central height portion of the stud 6, and the pulley 34 of the seismic reinforcement means 32 is fixed to the cut portion 40.

  As shown in FIG. 2 (b), the pulley 34 is of a double type having two winding positions. On the other hand, on the inner wall 8 side of the pulley 34, one end is formed at the upper left portion of the space portion 4. The first rope 36-1 that winds the other end to the upper right portion of the space portion 4 is wound and provided, and on the other side, that is, on the outer wall 10 side of the pulley 34, the lower right portion of the space portion 4 is provided. The second rope 36-2 is fixed by winding one end and the other end is fixed to the lower left portion of the space 4 by winding.

  At this time, the tension adjusting means 38 is provided in the vicinity of the upper right portion of the first rope 36-1 and in the vicinity of the lower left portion of the second rope 36-2. The tension adjusting means 38 urges the first and second ropes 36-1 and 36-2 in the tension direction by the contraction force, and the first and second ropes 36-1 and 36-2. The first and second springs 42-1 and 42-2 for adjusting the tension force are included.

  Moreover, in order to give tension | tensile_strength to these 1st and 2nd strands 36-1 and 36-2 in the middle site | part of each of the said 1st strand 36-1 and the 2nd strand 36-2. First and second turnbuckles 44-1 and 44-2 for adjusting the lengths of the first and second ropes 36-1 and 36-2 are provided.

  Then, as in the case of the first embodiment, the seismic reinforcement structure 2 can be easily constructed in the space 4 formed in the frame, and the workability can be improved. The first and second ropes 36-1 and 36-2 of the two seismic reinforcement means 32 can firmly connect the columns, and can provide a balanced overall support and a flexible structure with high tenacity In addition, tension is applied to each of the first and second ropes 36-1 and 36-2 by the first and second springs 42-1 and 42-2 of the tension adjusting means 38. And a strong seismic reinforcement structure 2 can be maintained.

  Further, when the seismic reinforcement structure 2 is constructed in the space portion 4 formed in the frame body, there is no problem at the time of new construction, and at the time of reconstruction, the inner wall 8 or the outer wall 10 constituting a part of the wall portion is necessary. In other words, excision of only the fixed portions of both ends of the first and second ropes 36-1 and 36-2 and the attachment portion of the pulley 34, and the tension adjusting means 38 and the first and second turnbuckles 44-1 , 44-2 can be dealt with by changing the installation position, etc., as in the case of the first embodiment described above, it is possible to cope with work in a small space. Therefore, a highly versatile seismic reinforcement structure 2 can be realized.

  Further, the tension adjusting means 38 urges the first and second ropes 36-1 and 36-2 in the tension direction by contraction force, and the first and second ropes 36-1 and 36- The tension force adjusting means 38 provided by being divided into two portions, the upper part and the lower part of the space part 4, by comprising the first and second springs 42-1 and 42-2 that adjust the tension force of the two. The first and second cords 36-1 and 36-2 are contracted by the contracting force that urges the first and second cords 36-1 and 36-2 in the tension direction. , 36-2 can be maintained in an appropriate state, the seismic reinforcement structure 2 can be maintained in a solid state, and the first, Even if the second ropes 36-1 and 36-2 are loose, the tension is slightly reduced. The looseness of the first and second ropes 36-1, 36-2 can be avoided by the biasing force of the first and second springs 42-1, 42-2 of the tension adjusting means 38, that is, the contraction force, This is practically advantageous.

  FIG. 3 shows a third embodiment of the present invention.

  The third embodiment is characterized in that, in the inter-column 6 disposed in the space 4 formed between the columns, the earthquake-proof reinforcing means 52 is provided at the central height portion of the inter-column 6 and the elasticity is increased. The point is that a tension adjusting means 54 is used.

  That is, as shown in FIG. 3, the seismic reinforcement means 52 includes two first and second pulleys that are slidably arranged in a vertical direction on a cut portion 56 formed at a central height portion of the stud 6. 58-1 and 58-2, and two first and second strips 60 wound around the first and second pulleys 58-1 and 58-2 and communicating between the pillars via the stud 6. -1, 60-2 and the two first and second strips 60-1, 60-2 in the tension direction to urge the two first and second strips 60-1, 60-2 The tension force adjusting means 54 for adjusting the tension force.

  Then, between these first and second pulleys 58-1, 58-2, as shown in FIG. 3, a tension adjusting means 54 made of a spring is disposed, that is, the upper first pulley 58-. 1 is provided with a first strip 60-1 which is fixed at one end to the lower left portion of the space portion 4 and fixed at the other end to the lower right portion of the space portion 4; The pulley 58-2 is provided with the second rope 60-2 wound around the upper right portion of the space portion 4 and having the other end fixed to the upper left portion of the space portion 4 by winding.

  At this time, turnbuckles 62 for adjusting the lengths of the first and second ropes 60-1 and 60-2 are respectively connected to the first rope 60-1 and / or the second rope 60-2. Provided in the middle of the second rope 60-2, against the resilience of the tension adjusting means 54 comprising a spring contracted between the first and second pulleys 58-1, 58-2, The turnbuckle 62 is rotated, the distance between the first and second pulleys 58-1 and 58-2 is adjusted by the elastic force of the tension adjusting means 54, and the first and second ropes 60-1 and 60- are adjusted. Secure the tension of 2.

  Then, as in the first and second embodiments described above, the seismic reinforcement structure 2 can be easily constructed in the space 4 formed in the frame, and the workability can be improved. The first and second ropes 60-1 and 60-2 of the earthquake-resistant reinforcement means 52 of the earthquake-resistant reinforcement structure 2 can firmly connect the columns, and can achieve a balanced overall support and a high tenacity. Furthermore, the tension adjusting means 54 can apply tension to each of the first and second ropes 60-1 and 60-2, and maintain a strong seismic reinforcement structure 2. Can do.

  Further, when constructing the seismic reinforcement structure 2 in the space portion 4 formed in the frame body, there is no problem at the time of new construction, and at the time of reconstruction, a necessary part of the inner wall or the outer wall constituting a part of the wall portion, That is, excision of only the fixed portions of the first and second ropes 60-1 and 60-2 and the mounting portions of the first and second pulleys 58-1 and 58-2, the tension adjusting means 54 and the turn If this is dealt with by changing the installation position of the buckle 62 and the like, the work in a small space can be handled in the same way as in the first and second embodiments described above. Therefore, a highly versatile seismic reinforcement structure 2 can be realized.

  Further, the elastic force of the tension adjusting means 54 formed of a spring contracted between the two first and second pulleys 58-1 and 58-2 slidably arranged in the vertical direction causes the first 1. By adjusting the distance between the second pulleys 58-1 and 58-2 and securing the tension of the first and second ropes 60-1 and 60-2, the seismic reinforcement structure 2 While maintaining a firm state, even if the first and second ropes 60-1 and 60-2 are loosened due to deformation of wood or the like due to secular change, the tension is slightly reduced. However, the distance between the first and second pulleys 58-1 and 58-2 is adjusted by the urging force of the tension adjusting means 54, that is, the elastic force, and the first and second ropes 60-1, 60- The loosening of 2 can be avoided, which is practically advantageous.

  FIG. 4 shows a fourth embodiment of the present invention.

  The feature of the fourth embodiment is that the seismic reinforcement means 72 is provided with two first and second pulleys 74-1 and 74-2 provided on the column side in the space 4 between the columns, and these Two first and second strips 76- that are wound around the first and second pulleys 74-1 and 74-2 and communicate with each other through the pillars 6 arranged at the central portion of the space 4 are provided. 1, 76-2 and these first and second ropes 76-1, 76-2 are urged in the tension direction to adjust the tension of the first and second ropes 76-1, 76-2. The tension force adjusting means 78 is configured.

  That is, as shown in FIG. 4, first and second excision portions 80-1 and 80-2 are formed at the upper and lower portions of the stud 6.

  And the 1st, 2nd pulleys 74-1 and 74-2 of the said earthquake-proof reinforcement means 72 are fixed to the center height site | part of each pillar located in the right-and-left site | part of the said space part 4, and FIG. ), One end of the first pulley 74-1 fixed to the left column is fixed to the upper right portion of the space portion 4 and the other end is fixed to the lower right portion of the space portion 4. One end is fixed to the upper left portion of the space portion 4 and the other end of the second pulley 74-2 is wound around the first rope 76-1 and fixed to the other side, that is, the right column. The said 2nd strip 76-2 fixed to the lower left part of 4 is wound and provided.

  At this time, the tension adjusting means 78 is provided in the vicinity of the lower right portion of the first rope 76-1 and in the vicinity of the lower left portion of the second rope 76-2. The tension adjusting means 78 urges the first and second ropes 76-1, 76-2 in the tension direction by the contraction force, and the first and second ropes 76-1, 76-2 It consists of first and second springs 82-1 and 82-2 for adjusting the tension.

  In addition, the first and second strips 76-are disposed in the vicinity of the first pulley 74-1 of the first rope 76-1 and in the vicinity of the second pulley 74-2 of the second rope 76-2. First and second turnbuckles 84-1 and 84-2 for adjusting the lengths of the first and second ropes 76-1 and 76-2, respectively, in order to give tension to 1 and 76-2. Provide.

  Further, when the first and second pulleys 74-1 and 74-2 are attached at the same position in the seismic reinforcement means 72, the first and second pulleys 74-1 and 74-2 are not damaged. Since the rotated first and second strips 76-1 and 76-2 are in contact with each other at the inter-column 6 portion, as shown in FIG. 4B, the first pulley 74-1 is positioned on the inner wall 8 side. The second pulley 74-2 is positioned on the outer wall 10 side.

  When the first and second excision portions 80-1 and 80-2 are formed in the upper and lower portions of the stud 6 in accordance with the mounting positions of the first and second pulleys 74-1 and 74-2, FIG. As shown in (b), the first excision 80-1 is formed on the inner wall 8 side of the stud 6 and the outer wall side first excision 80a-1 is formed on the outer wall 10 of the stud 6. The second cut portion 80-2 is formed on the inner wall 8 side of the intermediate pillar 6 and the outer wall side second formed on the outer wall 10 side of the intermediate pillar 6 is formed. And 2 excision parts 80b-2.

  Then, like the above-described first to fourth embodiments, the seismic reinforcement structure 2 can be easily constructed in the space portion 4 formed in the frame body, and workability can be improved. The first and second ropes 76-1 and 76-2 of the earthquake-resistant reinforcement means 72 of the earthquake-resistant reinforcement structure 2 can firmly connect the columns to each other, enabling a balanced overall support and high tenacity. Further, the first and second cords 76-1, 76-2 can be tensioned by the first and second springs 82-1 and 82-2 of the tension adjusting means 78. It can be applied and a strong seismic reinforcement structure 2 can be maintained.

  Further, when the seismic reinforcement structure 2 is constructed in the space portion 4 formed in the frame body, there is no problem at the time of new construction, and at the time of reconstruction, the inner wall 8 or the outer wall 10 constituting a part of the wall portion is necessary. Locations, that is, both end fixing portions of the first and second ropes 76-1, 76-2, attachment portions of the first and second pulleys 74-1, 74-2, and the first and second excisions of the stud 6 If the countermeasure is taken by excision of only the portions where the portions 80-1 and 80-2 are formed, and by changing the installation position of the tension adjusting means 78 and the first and second turnbuckles 84-1, 84-2, the above-mentioned As in the case of the first to fourth embodiments, it is possible to cope with work in a small space, so that it is possible to cope with seismic reinforcement of existing buildings, and realize a highly versatile seismic reinforcement structure 2. be able to.

  Further, the tension adjusting means 78 urges the first and second ropes 76-1, 76-2 in the tension direction by the contraction force, and the first and second ropes 76-1, 76- The first and second springs 82-1 of the tension adjusting means 78 provided in the space portion 4 are constituted by the first and second springs 82-1 and 82-2 that adjust the tension force of the second. , 82-2 has the appropriate tension force of the first and second strips 76-1, 76-2 by the contraction force that urges the first and second strands 76-1, 76-2 in the tension direction. The seismic reinforcement structure 2 can be maintained in a solid state, and the first and second ropes 76-1, 76- can be maintained by deformation of wood due to secular change. Even if the looseness occurs in 2, the tension force slightly decreases, but the first and second tension adjusting means 78. Biasing force of the pulling 82-1 and 82-2, i.e. the first, it is possible to avoid loosening of the second rope 76-1 and 76-2 by the contraction force, which is advantageous in practical use.

  The present invention is not limited to the first to fourth embodiments described above, and various application modifications can be made.

  For example, in the first embodiment of the present invention, the seismic reinforcement structure is constructed between the inner wall and the outer wall that constitute a part of the wall part and the wall part formed from the base part, the girder, and the column. It is also possible to adopt a special configuration in which the seismic reinforcement structure is constructed on the inner wall or part of the outer wall that forms part of the wall of the building.

  That is, in a building, there may be no problem even if the seismic reinforcement structure appears in a visible part, and the versatility of the seismic reinforcement structure is increased.

  Then, work such as excising the wall portion of the building can be made unnecessary, which can contribute to reduction in work efficiency and work cost.

  And in the seismic reinforcement structure that appears in the visible part, if the camouflage color is given, it is possible to reduce the visual confirmation degree of the seismic reinforcement structure, and conversely, if the clear coloring is given, the building It is possible to bring out a kind of unique appearance as a design attached to.

  Further, in the first to fourth embodiments of the present invention, the seismic reinforcement means is constituted by the wire which is a metal wire and the tension adjusting means, but instead of the wire, other than a steel belt or the like. It is also possible to adopt a special configuration using these members.

  That is, instead of the wire being a metal wire, a steel belt or a synthetic fiber wire or belt is used.

  In the case of a steel belt, it is possible to obtain a sufficient strength and maintain a strong seismic reinforcement structure in the same manner as a wire that is a metal wire. In the case of the belt, it is lightweight and can be handled in an acute angle state, which can contribute to facilitating layout change and improving attachment workability.

1 shows a first embodiment of the present invention, (a) is a schematic front view of a space portion formed in a frame of a building, and (b) is a schematic right side view of a space portion formed in the frame of a building. It is. The 2nd Example of this invention is shown, (a) is a schematic front view of the space part formed in the frame of a building, (b) is the schematic right side view of the space part formed in the frame of a building It is. It is a principal part enlarged view of the earthquake-proof reinforcement means provided in the center site | part of the space part formed in the frame of the building which shows 3rd Example of this invention. 4A and 4B show a fourth embodiment of the present invention, in which FIG. 4A is a schematic front view of a space portion formed in a building frame, and FIG. 4B is a schematic right side view of a space portion formed in a building frame. It is. It is a schematic front view of the frame of the building which shows the 1st prior art of this invention. It is a schematic front view which shows the state at the time of the vibration of the frame of a building. It is a schematic plan view which shows the 1st example at the time of frame formation. It is a schematic plan view which shows the 2nd example at the time of frame formation. It is a schematic front view of the state which arranged the braces in the frame of the building which shows the 2nd prior art of this invention. It is a schematic front view of the state which has arrange | positioned the wire and the turnbuckle in the frame of the building which shows the 3rd prior art of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 2 Seismic reinforcement structure 4 Space part 6 Spacer 8 Inner wall 10 Outer wall 12 Strip 14 Tension force adjustment means 16 Seismic reinforcement means 18-1 1st pulley 18-2 2nd pulley 20 1st cutting part 22 2nd cutting part 24 Turnbuckle

Claims (4)

  A frame part of the wall part is formed by a base part, a girder parallel to the base part, a plurality of columns erected from the base part to the girder, and a stud arranged at predetermined intervals between the pillars. In the building to be constructed, there is provided a seismic reinforcement means having a rope connecting the pillars via the studs and a tension adjusting means for adjusting the tension of the ropes. Seismic reinforcement structure.   The seismic reinforcement means includes at least one pulley disposed between the columns, at least one rope wound around at least one pulley and communicating between the columns via the intermediate columns, and at least one 2. The earthquake-proof reinforcement structure for a building according to claim 1, comprising tension force adjusting means for adjusting the tension force of at least one rope by urging the rope in the tension direction.   The said tension | tensile_strength adjusting means consists of a spring which is provided in the middle of a rope and urges a rope in a tension direction by contraction force, and adjusts the tension of a rope. Seismic reinforcement structure for buildings described in 1.   The tension adjusting means is provided between two pulleys arranged between the pillars, and includes a spring that adjusts a distance between the pulleys by a resilient force and ensures tension of the rope. The earthquake-proof reinforcement structure for a building according to claim 1 or 2, characterized by the above.

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