JP4858834B2 - Building with vibration control device - Google Patents

Description

  The present invention relates to a building such as a building and a vibration control device applied to the building.

  Conventionally, as a seismic isolation device applied to a building such as a building, for example, a plurality of elastic plates and steel plates each formed of rubber are provided, and the elastic plates and steel plates are alternately stacked in the vertical direction. There is something. This seismic isolation device is arrange | positioned, for example between the lower end part of a building, and the surface of the ground.

  According to this seismic isolation device, for example, when an external force such as an earthquake acts on a building, it is possible to reduce the vibration of the building in the horizontal direction by the seismic isolation device (see, for example, Patent Document 1).

JP-A-6-248712

  By the way, in some buildings, for example, as shown in FIG. The main body 92 has at least a pair of main pillars 91a and 91b erected on the ground. The pair of main pillars 91a and 91b constitutes a vertical plane extending in the vertical direction between them. The overhanging portion 93 is disposed on the main body portion 92 in such a manner that it protrudes from the vertical plane formed by the pair of main pillars 91a and 91b and is separated from the ground.

  Here, even if the seismic isolation device is applied to this building, when external forces such as earthquakes act on the building, the seismic isolation device does not consider the reduction of vertical vibration. Will vibrate in the vertical direction. When the building vibrates in the vertical direction, the overhanging portion is separated from the ground, and thus vibrates along the vertical direction like a cantilever beam. The vibration of the overhang portion 93 increases as the distance from the vertical plane increases.

This invention is made in view of the above, Comprising: Even if external force, such as an earthquake, acts on a building, the building provided with the damping device which can reduce the vibration of the perpendicular direction in an overhang | projection part Is to provide.

In order to solve the above-described problems and achieve the object, the invention according to claim 1 is a main body having a pair of main pillars standing on the ground and having a vertical plane extending in the vertical direction. And a projecting device that is applied to a building that projects from the vertical surface and that projects from the ground in a manner spaced from the ground. A brace that connects the small beam that constitutes the projecting portion and the stud that constitutes the overhanging portion, and the side pillars that are located on both sides of the overhanging portion, and the main pillar that corresponds to the side studs. A rigid body is disposed therebetween, and the vibration control device is configured by a damper interposed between a lower end portion of a stud disposed between the side studs and the main pillar corresponding to the stud. And

  According to this invention, since the damper is interposed between the lower end portion of the studs constituting the overhanging portion and the main pillar, when an external force such as an earthquake acts on the building, the damper causes the overhanging portion in the vertical direction. Vibration can be reduced.

  Embodiments of a vibration control device according to the present invention will be described below in detail with reference to the drawings. FIG. 1 is a perspective view showing a housing of a building (building) to which the vibration control device according to the present invention is applied.

  As shown in FIG. 1, a foundation 1 is constructed at a site where a building is constructed on the surface of the ground. The building also includes a main body portion 100 and overhang portions 200a and 200b.

  This building extends in the vertical direction and constitutes the main body 100, and supports a beam to be described later, and includes a plurality of main pillars erected on the ground via the foundation 1. There are 20 books (20 in this embodiment). More specifically, in FIG. 2, the eleventh pillar 11, the twelfth pillar 12, the thirteenth pillar 13, the fourteenth pillar 14, and the fifteenth pillar 15 are arranged at equal intervals in the left-right direction. Are erected on the ground via the foundation 1.

  In addition, as shown in FIG. 1, the twenty-first pillar 21, the twenty-second pillar 22, the twenty-third pillar 23, the twenty-four pillar 24, and the twenty-fifth are shown in FIG. The main pillars 25 are erected on the ground via the foundation 1. The distance in the depth direction in FIG. 2 of the eleventh pillar 11 to the twenty-first pillar 21, the distance in the depth direction in FIG. 2 of the twelfth pillar 12 to the twenty-second pillar 22, and the thirteenth to the twenty-third pillar 23. 2 in the depth direction in FIG. 2 of the main pillar 13, the distance in the depth direction in FIG. 2 of the fourteenth pillar 14 with respect to the twenty-fourth pillar 24, and the depth direction in FIG. 2 of the fifteenth pillar 15 with respect to the twenty-fifth pillar 25. Are equal to each other.

  Further, as shown in FIG. 1, the 31st pillar 31, the 32nd pillar 32, the 33rd pillar 33, the 34th pillar 34, and the 35th are shown in FIG. The main pillars 35 are erected on the ground via the foundation 1. The distance in the depth direction in FIG. 2 of the 21st pillar 21 with respect to the 31st pillar 31, the distance in the depth direction in FIG. 2 of the 22nd pillar 22 with respect to the 32nd pillar 32, and the 23rd with respect to the 33rd pillar 33. 2 in the depth direction in FIG. 2 of the main pillar 23, the distance in the depth direction in FIG. 2 of the 24th pillar 24 relative to the 34th pillar 34, and the depth direction in FIG. 2 of the 25th pillar 25 relative to the 35th pillar 35. Are equal to each other.

  Also, in FIG. 2, the forty-first column 41, the forty-second column 42, the forty-third column 43, the forty-four column 44, and the forty-five column as shown in FIG. The pillars 45 are respectively erected on the ground via the foundation 1. 2 in the depth direction in FIG. 2 with respect to the 41st pillar 41, the distance in the depth direction in FIG. 2 with respect to the thirty-second pillar 42, and the 33rd with respect to the 43rd pillar 43. 2 in the depth direction in FIG. 2 of the main pillar 33, the distance in the depth direction in FIG. 2 of the 34th pillar 34 relative to the 44th pillar 44, and the depth direction in FIG. 2 of the 35th pillar 35 relative to the 45th pillar 45. Are equal to each other.

  Concrete bodies 80 formed of a plate made of steel and concrete are disposed at the lower ends of these main pillars. For example, as shown in FIG. 5, a concrete body 80 is disposed at the lower end portion of the fifteenth pillar 15, and as shown in FIG. It is arranged.

  A seismic isolation device 2 is disposed between the concrete body 80 and the foundation 1. For example, as shown in FIG. 5, the seismic isolation device 2 includes a plurality of elastic plates 2a and steel plates 2b formed of rubber, and is constructed by alternately stacking the elastic plates 2a and the steel plates 2b in the vertical direction. It is. A first flange 2c attached to the foundation 1 is disposed at the lower end of the seismic isolation device 2, and a second flange attached to the concrete body 80 of each main pillar is provided at the upper end of the seismic isolation device 2. 2d is arranged.

  Further, a first vertical surface extending in the vertical direction is formed between the pair of main pillars 11 and 41, and extending in the vertical direction between the pair of main pillars 15 and 45. A second vertical plane is configured. The one overhanging portion 200a is disposed on the main body portion 100 so as to protrude from the first vertical surface and be separated from the ground. Moreover, the other overhang | projection part 200b is arrange | positioned in the main-body part 100 in the aspect which protrudes from a 2nd vertical surface and is spaced apart from the ground.

  Further, this building includes a plurality of beams (25 in this embodiment) extending in the horizontal direction and spanning a plurality of (four in this embodiment) the main pillars. More specifically, the 111th beam 111, the 112th beam 112, the 113th beam 113, the 114th beam spanning the 11th column 11, the 21st column 21, the 31st column 31, and the 41st column 41. A beam 114 and a 115th beam 115 are provided in the vertical direction.

  Furthermore, the 121st beam 121, the 122nd beam 122, the 123rd beam 123, the 124th beam 124, and the 12th main column 12, the 22nd main column 22, the 32nd main column 32, and the 42nd main column 42, and The 125th beam 125 is provided in the up-down direction.

  In addition, the 131st beam 131, the 132nd beam 132, the 133th beam 133, the 134th beam 134, and the 13th main column 13, the 23rd main column 23, the 33rd main column 33, and the 43rd main column 43, and The 135th beam 135 is provided in the up-down direction.

  Furthermore, the 141st beam 141, the 142nd beam 142, the 143rd beam 143, the 144th beam 144, and the 14th column 14, the 24th column 24, the 34th column 34, and the 44th column 44, and The 145th beam 145 is provided in the up-down direction.

  Further, the 151st beam 151, the 152th beam 152, the 153th beam 153, the 154th beam 154, and the 15th column 15, the 25th column 25, the 35th column 35, and the 45th column 45, and The 155th beam 155 is provided in the up-down direction.

  These beams 111, 112, 113, 114, 115, 121, 122, 123, 124, 125, 131, 132, 133, 134, 135, 141, 142, 143, 144, 145, 151, 152, 153, 154 , 155 constitute the main body 100.

  In addition, as shown in FIG. 1 and FIG. 2, the building extends in the horizontal direction, and a plurality of (in this embodiment, five) beams (in this embodiment) 24) in the form. More specifically, the 211th beam 211, the 212th beam 212, the second beam spanning the eleventh column 11, the twelfth column 12, the thirteenth column 13, the fourteenth column 14, and the fifteenth column 15. A 213 beam 213, a 214th beam 214, a 215th beam 215, and a 216th beam 216 are provided in the vertical direction. The 213 beam 213, the 214 beam 214, the 215 beam 215, and the 216 beam 216 are longer than the horizontal interval between the eleventh pillar 11 and the fifteenth pillar 15 and are identical to each other. The length is set such that one end projects to the left of the eleventh pillar 11 and the other end projects to the right of the fifteenth pillar 15. The overhanging lengths of the 213 beam 213, the 214 beam 214, the 215 beam 215, and the 216 beam 216 with respect to the eleventh pillar 11 are the same, and the 213 beam 213 with respect to the fifteenth pillar 15, The overhanging lengths of the 214 beam 214, the 215th beam 215, and the 216th beam 216 are the same.

  In addition, as shown in FIG. 1, the 221st beam 221, the 22nd beam 25, the 22nd beam 22, the 23rd beam 23, the 24th beam 24, and the 25th beam 25 span the 221st beam 221 and the 222nd beam. 222, 223 beam 223, 224 beam 224, 225 beam 225, and 226 beam 226 are provided in the vertical direction. The 223 beam 223, the 224 beam 224, the 225 beam 225, and the 226 beam 226 are longer than the horizontal distance between the 21st column 21 and the 25th column 25 and have the same length. One end projects to the left of the twenty-first column 21, and the other end projects to the right of the twenty-fifth column 25. The horizontal lengths of the 223 beam 223, the 224 beam 224, the 225 beam 225, and the 226 beam 226 are the same as the 213 beam 213, the 214 beam 214, the 215 beam 215, and the 216 beam 216. Is the same as the horizontal length. The overhanging lengths of the 223 beam 223, the 224 beam 224, the 225 beam 225, and the 226 beam 226 with respect to the 21st column 21 are the same, and the 223 beam 223 with respect to the 25th column 25 is also present. The overhanging lengths of the 224 beam 224, the 225 beam 225, and the 226 beam 226 are the same.

  Furthermore, a 231 beam 231, a 232 beam 232, a 233 beam 233 spanning the 31st pillar 31, the 32nd pillar 32, the 33rd pillar 33, the 34th pillar 34, and the 35th pillar 35. A 234 beam 234, a 235 beam 235, and a 236 beam 236 are provided in the vertical direction. The 233 beam 233, the 234 beam 234, the 235 beam 235, and the 236 beam 236 are set longer than the horizontal interval between the 31st pillar 31 and the 35th pillar 35, The end of the first protrusion 31 protrudes to the left of the thirty-first pillar 31, and the other end protrudes to the right of the thirty-fifth pillar 35. The horizontal lengths of the 233 beam 233, the 234 beam 234, the 235 beam 235, and the 236 beam 236 are the same as the 223 beam 223, the 224 beam 224, the 225 beam 225, and the 226 beam 226. Is the same as the horizontal length. The overhanging lengths of the 233 beam 233, the 234 beam 234, the 235 beam 235, and the 236 beam 236 with respect to the 31st pillar 31 are the same, and the 233 beam 233 with respect to the 35th pillar 35 is also present. The overhanging lengths of the 234 beam 234, the 235 beam 235, and the 236 beam 236 are the same.

  The 41st main pillar 41, the 42nd main pillar 42, the 43rd main pillar 43, the 44th main pillar 44, and the 45th main pillar 45, the 241st beam 241, the 242nd beam 242, the 243rd beam 243, A 244 beam 244, a 245 beam 245, and a 246 beam 246 are provided in the vertical direction. The 243 beam 243, the 244 beam 244, the 245 beam 245, and the 246 beam 246 are set to be longer than the horizontal interval between the 41st column 41 and the 45th column 45, The other end projects to the left of the forty-first column 41, and the other end projects to the right of the forty-fifth column 45. The horizontal lengths of the 243 beam 243, the 244 beam 244, the 245 beam 245, and the 246 beam 246 are the same as the 233 beam 233, the 234 beam 234, the 235 beam 235, and the 236 beam 236. Is the same as the horizontal length. The overhanging lengths of the 243rd beam 243, the 244th beam 244, the 245th beam 245, and the 246th beam 246 with respect to the 41st column 41 are the same, and the 243rd beam 243 with respect to the 45th column 45 is also provided. The overhanging lengths of the 244th beam 244, the 245th beam 245, and the 246th beam 246 are the same.

  In this building, the first floor is constructed by the beams 111, 121, 131, 141, 151, 211, 221, 231, 241. Further, a second floor is constructed by the beams 112, 122, 132, 142, 152, 212, 222, 232, and 242.

  One end of each of the beams 213, 214, 215, 216, 223, 224, 225, 226, 233, 234, 235, 236, 243, 244, 245, 246 constitutes one overhang 200a It is. The other end of the beams 213, 214, 215, 216, 223, 224, 225, 226, 233, 234, 235, 236, 243, 244, 245, 246 constitutes the other overhanging portion 200b. To do.

  The beams 211, 212, 221, 222, 231, 232, 241, 242 and the beams 213, 214, 215, 216, 223, 224, 225, 226, 233, 234, 235, 236, 243, 244, 245 , 246 except for one end and the other end constitute the main body 100.

  In addition, as shown in FIGS. 1 and 3, the building has one end of the 213 beam 213, one end of the 223 beam 223, one end of the 233 beam 233, and 243 One end of the beam 243 is connected to each other, and a third beam 331 that constitutes one overhang portion 200a is provided. Further, as shown in FIGS. 1 and 4, the building includes the other end of the 213 beam 213, the other end of the 223 beam 223, the other end of the 233 beam 233, and the 243 beam. The other end portion of H.243 is connected, and a third beam 332 constituting the other overhang portion 200b is provided.

  In addition, as shown in FIGS. 1 and 3, the building has one end of the 214th beam 214, one end of the 224th beam 224, one end of the 234th beam 234, and the 244th beam. One end of 244 is connected, and a 341 small beam 341 constituting one overhanging portion 200a is provided. Further, as shown in FIGS. 1 and 4, the building includes the other end of the 214th beam 214, the other end of the 224th beam 224, the other end of the 234th beam 234, and the 244th beam. The other end portion of 244 is connected, and a 342 small beam 342 that constitutes the other overhang portion 200b is provided.

  Still further, as shown in FIGS. 1 and 3, the building has one end of the 215 beam 215, one end of the 225 beam 225, one end of the 235 beam 235, and the 245 One end of the beam 245 is connected to each other, and a first 351 small beam 351 constituting one overhanging portion 200a is provided. Further, as shown in FIGS. 1 and 4, the building includes the other end of the 215 beam 215, the other end of the 225 beam 225, the other end of the 235 beam 235, and the 245 beam. The other end of H.245 is connected, and a third 352 beam 352 constituting the other overhanging portion 200b is provided.

  In addition, as shown in FIGS. 1 and 3, the building has one end of the 216th beam 216, one end of the 226th beam 226, one end of the 236th beam 236, and the 246th beam. One end portion of H.246 is connected, and a 361 small beam 361 constituting one overhanging portion 200a is provided. Further, as shown in FIGS. 1 and 4, the building includes the other end of the 216th beam 216, the other end of the 226th beam 226, the other end of the 236th beam 236, and the 246th beam. The other end portion of the H.246 is connected, and a second 362 small beam 362 constituting the other overhanging portion 200b is provided.

  In this building, the third floor is constructed by the beams 113, 123, 133, 143, 153, 213, 223, 233, 243 and the small beams 331, 332. Further, a fourth floor is constructed by the beams 114, 124, 134, 144, 154, 214, 224, 234, 244 and the small beams 341, 342. Further, a fifth floor is constructed by the beams 115, 125, 135, 145, 155, 215, 225, 235, 245 and the small beams 351, 352. Further, a roof is constructed by the beams 216, 226, 236, 246 and the small beams 361, 362.

  In addition, as shown in FIGS. 1 and 3, the building includes one end of the 213rd beam 213, one end of the 214th beam 214, one end of the 215th beam 215, and 216th One end of the beam 216 is connected to each other, and a 401st-side spacer 401 that constitutes one overhanging portion 200a is provided. Further, as shown in FIGS. 1 and 4, the building includes the other end of the 213rd beam 213, the other end of the 214th beam 214, the other end of the 215th beam 215, and the 216th beam. The other end of 216 is connected, and a 402-th column 402 is provided that forms the other overhanging portion 200b.

  In addition, as shown in FIGS. 1 and 3, the building includes one end of the 223 beam 223, one end of the 224 beam 224, one end of the 225 beam 225, and the 226 beam. One end of the H.226 is connected, and a fourth 411 column 411 that constitutes one overhang 200a is provided. Further, as shown in FIGS. 1 and 4, the building includes the other end of the 223 beam 223, the other end of the 224 beam 224, the other end of the 225 beam 225, and the 226 beam. The other end portion of 226 is connected, and a fourth 1212 inter-column 412 that constitutes the other overhang portion 200b is provided.

  Still further, as shown in FIGS. 1 and 3, the building includes one end of a second beam 233, one end of a second beam 234, one end of a second beam 235, and a second beam 236. One end of the beam 236 is connected, and a 421 inter-column 421 that constitutes one overhang portion 200a is provided. Further, as shown in FIGS. 1 and 4, the building includes the other end of the 233 beam 233, the other end of the 234 beam 234, the other end of the 235 beam 235, and the 236 beam. 236 is provided with a 422 inter-column 422 that connects the other end of 236 and constitutes the other overhang 200b.

  In addition, as shown in FIGS. 1 and 3, the building includes one end of the 243rd beam 243, one end of the 244th beam 244, one end of the 245th beam 245, and the 246th beam. One end of H.246 is connected, and a 431-side interposition column 431 that constitutes one overhanging portion 200a is provided. Further, as shown in FIGS. 1 and 4, the building includes the other end of the 243 beam 243, the other end of the 244 beam 244, the other end of the 245 beam 245, and the 246 beam. The other end part of H.246 is connected, and the 432 side interposition pillar 432 which comprises the other overhang | projection part 200b is provided.

  The side pillars 401 and 431 are located on both sides of one overhanging portion 200a. Moreover, in one overhang | projection part 200a, the studs 411 and 412 are arrange | positioned between the side stud 401 and the side stud 431.

  The side pillars 402 and 432 are located on both sides of the other overhanging portion 200b. Further, in the other overhang portion 200 b, the studs 412 and 422 are disposed between the side studs 402 and the side studs 432.

  In addition, as shown in FIG. 3, this building includes braces 501 that connect the side studs 401 and the small beams 341, and two braces 502 that connect the studs 411 and the small beams 341. In addition, two braces 503 for connecting the inter-columns 421 and the small beams 341 are provided, and a brace 504 for connecting the side inter-columns 431 and the small beams 341 is provided.

  The building also includes a brace 511 that connects the side stud 401 and the small beam 351, and two braces 512 that connect the stud 411 and the small beam 351. Are provided with two braces 513 for connecting the side pillars 431 and the small beams 351.

  The building further includes a brace 521 that connects the side stud 401 and the small beam 361, and two braces 522 that connect the stud 411 and the small beam 361. Are provided with two braces 523 for connecting the side pillars 431 and the small beams 361.

  In addition, as shown in FIG. 4, the building includes braces 551 that connect the side studs 402 and the small beams 342, and two braces 552 that connect the studs 412 and the small beams 342, Two braces 553 are provided to connect the studs 422 and the small beams 342, and braces 554 are provided to connect the side studs 432 and the small beams 342.

  This building also includes a brace 561 that connects the side stud 402 and the small beam 352, and two braces 562 that connect the stud 412 and the small beam 352. Are provided with two braces 563 for connecting the side spacers 432 and the small beams 352.

  The building further includes a brace 571 that connects the side stud 402 and the small beam 362, and two braces 572 that connect the stud 412 and the small beam 362. Are provided with two braces 573 for connecting the side pillars 432 and the small beams 362.

  According to this building, braces 501, 502, 503, 504, 511, 512, 513, 521, 522, 523, 524 are arranged inside one overhanging part 200 a, and the other Braces 551, 552, 553, 554, 561, 562, 563, 564, 571, 572, 573, and 574 are disposed inside the protruding portion 200b, and these braces resist horizontal forces caused by earthquakes. be able to. Therefore, since this building can make the constituent materials such as main pillars and beams constituting the main body 100 as thin as possible, the internal space of the main body 100 can be widened and the internal space can be used effectively. It becomes possible.

  In addition, as shown in FIGS. 4 and 5, the building has a rigid body 601 disposed between a side column 402 and a main column 15 corresponding to the side column 402 via a small beam 332. . Further, as shown in FIG. 4, a rigid body 602 is disposed between the side pillars 432 and the main pillar 45 corresponding to the side pillars 432 via a small beam 332. These rigid bodies 601 and 602 are made of steel. Therefore, the horizontal force at the time of the earthquake is processed by the brace and transmitted to the foundation 1 through the rigid bodies 601 and 602.

  Further, as shown in FIGS. 4 and 6, a damper 701 is disposed via a small beam 332 between the lower end portion of the intermediate column 412 and the main column 25 corresponding to the intermediate column 412. Further, as shown in FIG. 4, a damper 702 is disposed via a small beam 332 between the lower end portion of the intermediate pillar 422 and the main pillar 35 corresponding to the intermediate pillar 422. These dampers 701 and 702 are viscoelastic dampers, for example, and constitute the vibration control device 60b. When an external force such as an earthquake acts on the building and the overhanging portion 200b vibrates along the vertical direction In order to dampen the vibration.

  When the amount of contraction when the rigid bodies 601 and 602 are compressed by applying a constant force and the amount of contraction when the same force is applied to the dampers 701 and 702 and compared, the amount of contraction of the dampers 701 and 702 is compared. The rigid bodies 601 and 602 and the dampers 701 and 702 are set so that the amount of contraction of the rigid bodies 601 and 602 is smaller than the amount. Further, when the amount of elongation when the rigid bodies 601 and 602 are pulled with a certain force applied is compared with the amount of elongation when the same force is applied to the dampers 701 and 702 and pulled, the dampers 701 and 702 The rigid bodies 601 and 602 and the dampers 701 and 702 are set so that the elongation amounts of the rigid bodies 601 and 602 are smaller than the elongation amounts. Therefore, when an external force such as an earthquake acts on the building and the overhanging portion 200b vibrates along the vertical direction, the rigid bodies 601 and 602 resist the force applied in the vertical direction.

  In this building, as shown in FIG. 3, a rigid body 603 is disposed between a side column 401 and a main column 11 corresponding to the side column 401 via a small beam 331. Further, a rigid body 604 is disposed between the side post 431 and the main post 41 corresponding to the side post 431 via a small beam 331. These rigid bodies 603 and 604 are made of steel. Therefore, the horizontal force at the time of the earthquake is processed by the brace and transmitted to the foundation 1 through the rigid bodies 601 and 602.

  Furthermore, a damper 703 is disposed via a small beam 331 between the lower end portion of the intermediate column 411 and the main column 21 corresponding to the intermediate column 411. Further, a damper 704 is disposed between the lower end portion of the intermediate pillar 421 and the main pillar 31 corresponding to the intermediate pillar 421 through a small beam 331. These dampers 703 and 704 are viscoelastic dampers, for example, and constitute the vibration control device 60a. When an external force such as an earthquake acts on the building and the overhanging portion 200a vibrates along the vertical direction In order to dampen the vibration.

  When the amount of contraction when the rigid bodies 603 and 604 are compressed by applying a certain force and the amount of contraction when the same force is applied to the dampers 703 and 704 and compared, the amount of contraction of the dampers 703 and 704 is compared. The rigid bodies 603 and 604 and the dampers 703 and 704 are set so that the amount of contraction of the rigid bodies 603 and 604 is smaller than the amount. Further, when the amount of elongation when a certain force is applied to the rigid bodies 603 and 604 and the amount of extension when the same force is applied to the dampers 703 and 704 and the amount of elongation is compared, the dampers 703 and 704 are compared. The rigid bodies 603 and 604 and the dampers 703 and 704 are set so that the elongation amount of the rigid bodies 603 and 604 is smaller than the elongation amount of the rigid bodies 603 and 604. Therefore, when an external force such as an earthquake acts on the building and the overhanging portion 200a vibrates along the vertical direction, the rigid bodies 603 and 604 resist the force applied in the vertical direction.

  According to the vibration control devices 60a and 60b according to the present invention, since the dampers 701, 702, 703, and 704 are provided, when the external force such as an earthquake acts on the building, the overhanging portions are formed by the dampers 701, 702, 703, and 704. The vibration in the vertical direction of 200a and 200b can be reduced. For example, when the same vertical vibration is applied to a building to which the vibration control devices 60a and 60b are applied and a building that does not have the vibration control devices 60a and 60b, the overhang portions 200a and 200b are applied. The acceleration applied to the tip of each was simulated. The result is shown in FIG. As can be seen from FIG. 7, a maximum of 392 gal acceleration is applied to the third floor of the overhanging portions 200a, 200b of the building to which the vibration control devices 60a, 60b are applied, a maximum 504 gal acceleration is applied to the fourth floor, and a maximum of 581 gal is applied to the fifth floor. Acceleration was added. On the other hand, a maximum of 689 gal acceleration was added to the third floor of the overhanging part of the building not equipped with the vibration control devices 60a and 60b, a maximum of 667 gal acceleration was added to the fourth floor, and a maximum of 671 gal acceleration was added to the fifth floor. Also from this result, the effect of the vibration control devices 60a and 60b according to the present invention can be understood.

  In addition, according to the building according to the present invention, the overhang portion 200a includes the braces 501, 502, 503, 504, 511, 512, 513, 514, 521, 522, 523, and 524. The strength of the portion 200a can be increased. Therefore, since the braces provided in the main body 100 can be reduced, the internal space of the main body 100 can be increased. Furthermore, according to the building according to the present invention, the overhang portion 200b includes the braces 551, 552, 553, 554, 561, 563, 564, 571, 572, 573, and 574. The strength of 200b can be increased. Therefore, since the braces provided in the main body 100 can be reduced, the internal space of the main body 100 can be increased.

  Furthermore, in the building according to the present invention, the rigid bodies 603 and 604 are arranged between the side pillars 401 and 431 located on both sides of the projecting portion 200a and the main pillars 11 and 41 corresponding to the side pillars 401 and 431, respectively. The dampers 703 and 704 are respectively interposed between the lower ends of the intermediate columns 411 and 421 disposed between the side columns 401 and 431 and the main columns 21 and 31 corresponding to the intermediate columns 411 and 421. is there. Further, rigid bodies 601 and 602 are disposed between the side pillars 402 and 432 located on both sides of the projecting portion 200b and the main pillars 15 and 45 corresponding to the side pillars 402 and 432, and the side pillars 402, Dampers 701 and 702 are respectively interposed between the lower ends of the inter-columns 412 and 422 disposed between 432 and the main columns 25 and 35 corresponding to the inter-columns 412 and 422. Therefore, when an external force such as an earthquake acts on the building, the vertical vibrations of the overhang portions 200a and 200b can be reduced.

It is a perspective view which shows the housing of the building to which the vibration damping device concerning this invention is applied. It is a front view of the housing of the building shown in FIG. It is a perspective view which shows a part of housing of the building shown in FIG. It is a perspective view which shows a part of housing of the building shown in FIG. It is a side view which shows a part of housing of the building shown in FIG. 1, and shows the rigid body with which the building is provided. It is a side view which shows a part of the housing of the building shown in FIG. 1, and shows the damper with which the building is equipped. It is a graph which shows the relationship between the vibration of the vertical direction of the building which applied the damping device concerning this invention, and the vibration of the vertical direction of the building which does not apply the damping device. It is a perspective view which shows a part of conventional housing of a building.

Explanation of symbols

11 main columns 15 main columns 41 main columns 45 main columns 60a vibration control device 60b vibration control device 100 main body portion 200a overhang portion 200b overhang portion 331 small beam 332 small beam 341 small beam 342 small beam 351 small beam 352 small beam 361 Small beam 362 Small beam 401 Side space column 402 Side space column 411 Space column 421 Space column 412 Space column 422 Space column 421 Space column 422 Space column 431 Side space column 432 Side space column 601 Rigid body 602 Rigid body 603 Rigid body 604 Damper 703 Damper 702 Damper 702 Damper 702 Damper 702

Claims (1)

A main body having a pair of main pillars standing between the vertical surfaces extending between the vertical surfaces extending in the vertical direction, and being disposed on the main body in a manner protruding from the vertical surfaces and spaced apart from the ground A building with a vibration control device applied to a building with a protruding portion ,
A brace that connects the small beam that constitutes the overhang portion and the studs that constitute the overhang portion is disposed,
A rigid body is disposed between the side pillars located on both sides of the projecting portion and the main pillar corresponding to the side pillars,
The vibration control device comprises a vibration control device comprising a damper interposed between a lower end portion of a stud arranged between the side studs and the main pillar corresponding to the stud. Building.

Images