JP5690129B2 - Vibration control device - Google Patents

Description

  The present invention relates to a vibration damping device for suppressing vibration of a building due to an earthquake or the like, and in particular, a vibration damping device disposed inside a quadrilateral frame formed by four components constituting the building. About.

  In Patent Document 1 below, as a device for suppressing vibration of a building due to an earthquake or the like, there is a vibration damping device disposed inside a quadrilateral frame formed by four constituent members constituting the building. It is shown. The vibration damping device includes a vibration damping device disposed inside the quadrilateral frame, and four braces extending radially from the vibration damping device and connecting the vibration damping device and the quadrilateral frame. The vibration energy that is formed and the deformation of the quadrangular frame is absorbed by the plastic deformation of the vibration damper that transmits the vibration energy via the brace, thereby suppressing the vibration.

JP 2010-95901 A

  The quadrangular frame in which the vibration damping device is disposed is generally a portion that becomes a wall of a building by housing and arranging building components such as a wall material and a heat insulating material. For this reason, since the vibration damping device is disposed inside the rectangular frame together with these building components, the building components such as wall materials can be rationally accommodated and arranged inside the rectangular frame. A damping device is required.

  An object of the present invention is to provide a vibration damping device capable of rationally storing and arranging a building component such as a wall material inside a rectangular frame.

  The vibration damping device according to the present invention includes a vibration damping device disposed inside a quadrilateral frame that is formed in a quadrangle when viewed from the front by four constituent members constituting a building, and a radial shape from the vibration damping device. The vibration energy that is extended and is formed to include the four braces that connect the vibration control tool and the quadrangular frame, and the vibration energy that deforms the quadrangular frame is transmitted through the brace. In the damping device that suppresses vibration by absorbing plastic deformation of the damping tool, a building component such as a wall material is housed and disposed inside the rectangular frame, and is orthogonal to the extending direction of the brace. The dimension of the brace in the thickness direction of the vibration damper is the same as or smaller than the thickness dimension of the vibration damper, and the brace is the same as the thickness dimension of the vibration damper. Law and is characterized in that no a not protrude from the extending damping device is supposed when the extending direction thickness extension region of the brace in the thickness direction of the vibration damping device.

  In this vibration damping device, the dimension of the brace in the thickness direction of the vibration damping tool orthogonal to the extending direction of the brace is the same as or smaller than the thickness dimension of the vibration damping tool. Because it does not protrude in the thickness direction of the damping tool from the damping tool thickness extension region that is assumed when the same dimension as the thickness of the damping tool is extended in the brace extension direction, Building components such as wall materials to be stored and placed can be placed sufficiently close to the vibration damping device without being obstructed by the brace.For this reason, according to the vibration damping device according to the present invention, It becomes possible to rationally store and arrange building components such as wall materials inside the rectangular frame.

  Further, in this vibration damping device, since the brace dimension in the thickness direction of the vibration damper perpendicular to the brace extending direction is the same as or smaller than the thickness dimension of the vibration damper, vibration energy is reduced. The volume of the vibration damping tool for absorbing the water by plastic deformation is sufficiently large, and therefore the vibration damping action by the vibration damping tool can be improved.

  In the present invention, the end of each brace on the vibration control device side is rotatably connected to the vibration control device by the first bracket, and the end of each brace on the quadrangular frame side is formed by the second bracket. When connecting to the frame in a pivotable manner, the dimensions of the first and second brackets in the thickness direction of the vibration damping tool are the same as or smaller than the thickness dimension of the vibration damping tool, It is preferable that the first and second braces are not protruded from the above-described vibration damper thickness extension region in the thickness direction of the vibration damper.

  According to this, the end of each brace on the vibration control device side is rotatably connected to the vibration control device by the first bracket, and the end of each brace on the square frame side is rotated to the quadrilateral frame by the second bracket. Even if it is movably connected, building components such as wall materials housed and arranged inside the quadrilateral frame are sufficiently close to the vibration control device without being disturbed by the first and second brackets. Can be arranged.

  Of the four second brackets, at least one second bracket is provided with two pins, and one of these pins is connected to the second bracket coupled to the rectangular frame. It is good also as a pin for connecting freely, and it is good also considering the other pin as a pin for prescribing | regulating the angle which a brace rotates centering on said one pin.

  According to this, when performing the operation | work which connects the edge part by the side of a damping device of a brace to a damping tool by the said 1st bracket, it is said that said brace will rotate large centering | focusing on said one pin. Therefore, the work of connecting the end portion of the brace on the vibration damping device side to the vibration damping device by the first bracket can be easily performed.

  In the present invention, if the vibration energy that deforms the rectangular frame can be absorbed by the plastic deformation of the vibration damper that transmits the vibration energy through the brace and the vibration can be suppressed, the vibration damper is arbitrary. The material may be formed of a material, and an example of the material is aluminum or an aluminum alloy, that is, the vibration control device may be made of aluminum or an aluminum alloy.

  Further, the vibration damping device according to the present invention may be a cast product that is integrally molded by a casting method, or may be a machined product produced by machining, or may be produced by combining a plurality of parts. A combined product may be used.

  In addition, the shape of the vibration damping device according to the present invention is also arbitrary. For example, the vibration damping device includes a main body portion having a quadrangular shape or a substantially quadrangular shape having four corners in front view, and the main body portion. Each of the corners has a projecting portion formed so as to project from the main body portion in the extending direction of the brace.

  In this way, the vibration control device protrudes from the main body portion in the direction of extending the brace into the main body portion having a quadrangular or substantially quadrangular shape having four corner portions when viewed from the front, and the respective corner portions of the main body portion. Each of the protrusions is connected to the ring-shaped part to which the first bracket is connected, and the ring-shaped part is connected to the main body part. When the main body portion is deformed so that the angle of the corner portion is changed by vibration energy, the connecting portion is deformed so that the width dimension of the connecting portion changes in front view. Also good.

  According to this, since the vibration energy is absorbed by the vibration control device not only in the main body portion of the vibration control device but also in the connecting portion of the protruding portion, the vibration control effect of the vibration control device can be further improved. become able to.

  In the above-described present invention, the building component housed and arranged inside the rectangular frame may be a wall material, a heat insulating material, an electric wiring, a base material for attaching the wall material, or an arbitrary building. It can be a component.

  Moreover, the said structural member which forms the said square frame may be made of wood or metal. That is, the vibration damping device according to the present invention can be applied to a wooden building and can also be applied to a steel building.

  According to the present invention, it is possible to obtain an effect that a building component such as a wall material can be rationally accommodated and arranged inside the quadrangular frame.

FIG. 1 is a front view showing the shape of the vibration damping device according to one embodiment of the present invention as viewed from the front. FIG. 2 is an enlarged front view showing a vibration damping tool among the members constituting the vibration damping device shown in FIG. 3 is a cross-sectional view taken along line S3-S3 of FIG. 4 is a cross-sectional view taken along line S4-S4 of FIG. FIG. 5 is an enlarged front view showing the second bracket among the members constituting the vibration damping device shown in FIG. 1. FIG. 6 is a view similar to FIG. 1 showing a case where the rectangular frame shown in FIG. 1 is deformed by a lateral load due to vibration. FIG. 7 is a view similar to FIG. 2 showing the deformation of the vibration damper in the case of FIG. FIG. 8 is a plan cross-sectional view showing a first embodiment in which building components are housed and arranged inside a rectangular frame. FIG. 9 is a plan sectional view showing a second embodiment in which building components are housed and arranged inside a rectangular frame. FIG. 10 is a plan cross-sectional view showing a third embodiment in which building components are housed and arranged inside a rectangular frame.

  EMBODIMENT OF THE INVENTION Below, the form for implementing this invention is demonstrated based on drawing. FIG. 1 shows a quadrangular frame 5 formed by four structural members 1 to 3 of a building. The building according to the present embodiment is a wooden frame-type wooden building, and the quadrangular frame 5 whose shape in front view is shown in FIG. 1 forms a wall portion on the first floor of the wooden building. Since the structural member 1 is formed of a structural material, the structural member 1 is a wooden base fixedly installed on the upper surface of the foundation concrete, and the two structural members 2 are wooden pillars erected on the base 1 with a space therebetween. The structural member 3 is a wooden beam spanned between the upper ends of these pillars 2.

  The damping device 10 according to the present embodiment is disposed inside the rectangular frame 5, and the damping device 10 is connected to the damping tool 11 and the damping tool 11 via the first bracket 12. The four braces 13 that are connected and extend radially from the vibration control device 11, and the second bracket 14 that is provided for each of the braces 13 and connects the brace 13 to the pillar 2.

  FIG. 2 shows the shape of the vibration control device 11 as viewed from the front. The vibration control device 11 disposed inside the rectangular frame 5 is a cast product made of aluminum or aluminum alloy, which is integrally formed by a die casting method, which is a casting method, and the vibration control device 11. Projecting from the main body 15 in the extending direction of the brace 13 to the main body 15 which is a quadrangle or substantially quadrilateral having four corners 15A in front view, and the respective corners 15A of the main body 15. And a projecting portion 16 formed. Each protrusion 16 includes a ring-shaped portion 16A for connecting the first bracket 12 and a connecting portion 16B for connecting the ring-shaped portion 16A to the main body portion 15.

  As shown in FIG. 3, which is a cross-sectional view taken along line S <b> 3-S <b> 3 of FIG. It is smaller than the dimension W2 in the thickness direction. The main body 15 has a frame shape in which a rectangular or substantially rectangular cavity 15B is formed.

  4 is a cross-sectional view taken along line S4-S4 of FIG. 1. As shown in FIG. 4, the first bracket 12 coupled to the end of the brace 13 on the vibration damping device 11 side is bifurcated. It is a shaped member. The ring portion 16A of the projecting portion 16 of the vibration control device 11 is inserted into the opening between the two forks of the first bracket 12, and the pins 17 inserted between the first bracket 12 and the ring portion 16A are inserted, The vibration control device 11 and the first bracket 12 are connected by a pin 17 and fixed to the brace 13 by being fixed to the ring portion 16A with a push screw (not shown) screwed in from the outside to the inside of the ring portion 16A. The end on the tool 11 side is rotatable about the pin 17 with respect to the vibration control tool 11.

  Further, as shown in FIG. 4, each brace 13 to which the first bracket 12 is coupled to the end on the vibration damping device 11 side includes a pipe body 18 and a rectangular frame 5 of the body 18. It is composed of an extension member 19 made of a plate material provided extending from the end on the side, and this extension member 19 is fixed to the main body 18 by welding or the like after being inserted into the groove 20 formed in the main body 18, Coupled with the body 18.

  Further, as shown in FIG. 5, the second bracket 14 includes a plate-like base member 21 disposed on the side surface of the pillar 2 and an extension member 19 of the brace 13 as shown in FIG. 4. A pair of connecting members 22 made of plate material disposed on both sides of the base member 22, the connecting members 22 are a base portion 22 </ b> A that is parallel to the base member 21, and bends at a right angle from the base portion 22 </ b> A. It is L-shaped consisting of the bent portion 22B. As can be seen from FIG. 5, the base member 21 and the base portion 22 </ b> A of each connecting member 22 are overlapped and fastened to the column 2 by a fastening tool 4 such as a nail. Further, as shown in FIG. 4, an extension member 19 of the brace 13 is inserted between the bent portions 22 </ b> B of the respective connecting members 22, and this extension member 19 is provided on the second bracket 14. The first and second pins 23 and 24 are connected to the bent portion 22B of the pair of connecting members 22.

  As shown in FIG. 5, the bent portion 22 </ b> B of each connecting member 22 has a hole 25 for inserting the first pin 23, and the extension member 19 of the brace 13 also has the first A hole 26 for inserting one pin 23 is formed. In addition, a hole 27 for inserting the second pin 24 is formed in the bent portion 22B of each connecting member 22, and the second pin 24 is also inserted into the extension member 19 of the brace 13. A hole 28 is formed.

  The first and second pins 23 and 24 are bolts, and these bolts are inserted from the holes 25 and 27 of the bent portion 22B of one of the connecting members 22 and connected to the other of the pair of connecting members 22. The nut 29 is screwed into the end of the bolt shaft protruding from the holes 25 and 27 of the bent portion 22B of the member 22, thereby connecting the bent portion 22B of the connecting member 22 and the extension member 19 of the brace 13. .

  Of the holes 25 to 28, the holes 25, 26, and 28 are round holes, but the hole 27 formed in the bent portion 22 </ b> B of the connecting member 22 for inserting the second pin 24 is the first pin 23. It is an arc-shaped long hole centered at. For this reason, the end of the brace 13 on the quadrangular frame 5 side is rotatable about the first pin 23 of the second bracket 14, and the first pin 23 is coupled to the quadrangular frame 5. 2 A pin for pivotally connecting the brace 13 to the bracket 14. On the other hand, the second pin 24 is a pin for defining the size of the angle at which the brace 13 can rotate around the first pin 23.

  The first and second pins 23 and 24 and the hole 27 that is an arc-shaped elongated hole are provided in all of the four second brackets 14 shown in FIG.

  When performing the operation of disposing the vibration damping device 10 according to the present embodiment inside the quadrangular frame 5, after the respective second brackets 14 are first coupled to the pillars 2, the braces 13 are attached to these second brackets 14. The extension member 19 is connected by the first and second pins 23, 24, and then the first bracket 12 provided at the end of each brace 13 on the vibration control device 11 side is connected to the protruding portion 16 of the vibration control device 11. To each other by a pin 17.

  Thus, when performing the operation | work which arrange | positions the damping device 10 inside the square frame 5, the 2nd pin 24 inserted in the hole 27 which is an arc-shaped long hole as mentioned above is respectively Since the brace 13 is a pin for defining the size of the angle at which the brace 13 can be rotated around the first pin 23, the first brace 13 is provided at the end of the brace 13 on the vibration damping device 11 side. When the bracket 12 is connected to the projecting portion 16 of the vibration control device 11 by the pin 17, the direction of the braces 13 can be set to be substantially directed toward the vibration control device 11. In other words, the second pin 24 can restrict the braces 13 from pivoting about the first pin 23. For this reason, the operation | work which connects the 1st bracket 12 provided for every brace 13 to the protrusion part 16 of the damping tool 11 with the pin 17 can be performed easily.

  Note that an arc-shaped long hole is formed in the extension member 19 of the brace 13 instead of the bent portion 22B of the connecting member 22, and the second pin 24 is inserted into the bent portion 22B of the connecting member 22. The hole for this purpose may be formed as a round hole.

  In this embodiment, as can be seen from FIG. 1, the main body portion 15 of the vibration damper 11 and the rectangular frame 5 have a similar relationship in front view. That is, when the front shape of the quadrangular frame 5 is reduced, it becomes the same as or substantially the same as the front shape of the main body portion 15 of the vibration damper 11.

  In the present embodiment, of the four braces 13 in total, two braces that are not in a relationship of being opposed to each other with the vibration control device 11 in between are in the embodiment of FIG. The two braces 13 </ b> A arranged on the lower side of the swing tool 11 are provided with length adjusting means 30. This length adjusting means 30 is disposed between two divided main bodies 18A and 18B formed by dividing the main body 18 of the brace 13A, and one side is a right-hand thread and the other is a left-hand thread. A turnbuckle means comprising a screw shaft member 30A and two nut members 30B, 30C into which the right and left screws of the screw shaft member 30A are screwed and coupled to the divided main bodies 18A, 18B; It has become.

  For this reason, when the screw shaft member 30A is rotated forward and backward with a tool, the length of the brace 13A expands and contracts, and the length of the brace 13A can be adjusted. And by this length adjustment, the arrangement | positioning position of the damping tool 11 inside the square frame 5 can be set to the exact or substantially exact center position of the square frame 5 by front view.

  In FIG. 2, an extension line N of the brace 13 that connects the vibration control device 11 and the rectangular frame 5 via the first and second brackets 12 and 14 is shown. The extension line N passes through the connecting portion 16B of the protruding portion 16 provided in the corner portion 15A of the main body portion 15 of the vibration control device 11. That is, the connecting portion 16B has a width dimension T through which the extension line N passes in the front view shown in FIG.

  In the above, as shown in FIG. 4, the dimension of the second bracket 12 in the thickness direction of the vibration control device 11 orthogonal to the extending direction of the brace 13 is W4, and the dimension of the brace 13 is W5. The dimension of the second bracket 14 is W6. On the other hand, the thickness dimension of the damping tool 11 is W3, and this dimension W3 is the same as the dimension W2 described in FIG. The dimensions W4, W5, and W6 are the same as or smaller than the dimension W3. In this embodiment, the dimension W4 is the same as the dimension W3, and the dimensions W5 and W6 are smaller than the dimension W3. Thus, making the dimension W4 the same as the dimension W3 means that the dimension W1 of the protruding portion 16 of the vibration control device 11 to which the first bracket 12 having a bifurcated shape is coupled as described in FIG. This can be achieved by making the size smaller than the dimension W2 of the main body 15 of the vibration control device 11.

  As described above, by making the dimensions W4, W5, and W6 the same as the dimension W3 or smaller than the dimension W3, as shown in FIG. 4, the same dimension as the thickness dimension W3 of the vibration control tool 11 is obtained. Assuming a vibration damper thickness extension region S extending in the extending direction of the brace 13, the first bracket 12, the brace 13, and the second bracket 14 are controlled by the vibration damper thickness extension region S. 11 does not protrude in the thickness direction.

  Further, as described above, the vibration control device 11 of the present embodiment is made of aluminum or aluminum alloy, whereas the first and second brackets 12 and 14 and the brace 13 are made of steel. The rigidity of the swinging tool 11 is smaller than the rigidity of the first and second brackets 12 and 14 and the brace 13.

  FIG. 6 shows a case where a lateral load W due to an earthquake or the like is applied to the rectangular frame 5, and FIG. 7 shows the vibration damping tool 11 at this time. The deformation of the rectangular frame 5 due to the lateral load W is transmitted to the vibration control device 11 through the second bracket 14, the brace 13 and the first bracket 12, and the vibration energy is controlled by plastic deformation of the vibration control device 11. The vibration of the rectangular frame 5 is suppressed by being absorbed by the vibration tool 11.

  As shown in FIG. 7, the absorption of vibration energy by the vibration control device 11 is a plastic deformation with a variable angle in which the angle of each corner portion 15A of the main body portion 15 of the vibration control device 11 changes in front view. In the present embodiment, as described with reference to FIG. 2, each corner portion 15 </ b> A is formed to connect the second bracket 14 to the vibration damper 11. Connecting portions 16B of the protruding portions 16 are provided, and these connecting portions 16B have a width dimension T through which the extension line N of the brace 13 passes, and the main body portion 15 of the vibration control device 11 is viewed from the front. When plastic deformation with a variable angle that changes the angle of the corner portion 15A is performed, the connecting portion 16B performs plastic deformation in which the width T of the connecting portion 16B changes in front view.

  For this reason, the vibration energy is absorbed in both the main body 15 and the protrusion 16 of the vibration control device 11, thereby increasing the energy absorbed by the vibration control device 10 according to the present embodiment. Can be made.

  Further, since the vibration control device 11 is a cast product made of aluminum or aluminum alloy in which the main body portion 15 and the protruding portion 16 are integrally formed, the main body portion 15 has a variable angle that changes the angle of the corner portion 15A. When plastic deformation is performed, it is possible to reliably cause plastic deformation in which the width dimension T changes in the connecting portion 16B.

  Furthermore, in the present embodiment, as described above, the dimensions W4, W5, and W6 are the same as or smaller than the dimension W3. In other words, the thickness dimension W3 of the vibration control device 11 is concrete. Since the thickness dimension W2 of the main body 15 is the largest dimension among the dimensions W3 to W6 of the members constituting the vibration damping device 10 according to the present embodiment, the vibration energy is reduced by plastic deformation. The volume of the damping device 11 for absorbing is sufficiently large, so that the damping action by the damping device 11 can be improved.

  Further, as described above, since the first bracket 12, the brace 13, and the second bracket 14 do not protrude from the damping tool thickness extension region S in the thickness direction of the damping tool 11, the damping device 10 is arranged. When a building component such as a wall material is housed and placed inside the provided rectangular frame 5, the building component can be housed and placed until it is sufficiently close to the vibration control device 11. That is, the building components housed and arranged inside the rectangular frame 5 are arranged sufficiently close to the vibration control device 11 without being obstructed by the first bracket 12, the brace 13 and the second bracket 14. Therefore, it is possible to rationally store and arrange the building components inside the rectangular frame 5.

  8-10 has shown embodiment which accommodated and arrange | positioned the building component inside the square frame 5 in which the damping device 10 is arrange | positioned as mentioned above.

  The embodiment of FIG. 8 is a case where the square frame 5A forms a large wall of the outer wall by the plywood bearing wall 50 attached to the outer surface of the pillar 2A. The heat insulating material 51 which is a building component is housed and arranged inside the quadrangular frame 5A, and the gypsum board 52 which is a wall material of the building constituent is located on the inner side of the vibration control device 10 in the rectangular frame 5A. Is housed inside.

  The embodiment of FIG. 9 is a case where the pillar 2B of the quadrangular frame 5B is a true wall pillar of the inner and outer walls, and the mortar layer 60 that is a building component and a plywood made inside the quadrangular frame 5B. A heat-insulating material 63 as a building component is housed and arranged on the indoor side of the load-bearing wall 61 attached to the base material 62 coupled to the pillar 2B. On the indoor side of the vibration control device 10, a gypsum board 64, which is a wall material of a building component, is housed and disposed inside the rectangular frame 5A.

  The embodiment of FIG. 10 is a case where the pillars 2C of the square frame 5C are pillars of the true wall of the inner wall, and on both sides of the vibration damping device 10, a gypsum board 70 which is a wall material of a building component and plywood are used. The load-bearing wall 71 is housed and arranged inside the rectangular frame 5C, and the load-bearing wall 71 is attached to the base material 72 coupled to the pillar 2C.

  As can be seen from these embodiments, the building components to be housed and arranged inside the rectangular frame 5 in which the vibration damping device 10 is arranged can be arbitrarily selected according to the arrangement position, usage, etc. of the rectangular frame 5 in the building. Can be.

  INDUSTRIAL APPLICABILITY The present invention can be used for suppressing vibration of a wooden building or a steel building due to an earthquake or the like.

DESCRIPTION OF SYMBOLS 1 Wooden base which is a structural member of a building 2,2A, 2B, 2C Wooden pillar which is a structural member of a building 3 Wooden beam which is a structural member of a building 5,5A, 5B, 5C Quadrilateral frame 10 Damping device 11 Damping tool 12 1st bracket 13 Brace 14 2nd bracket 15 Main body part 16 Protrusion part 16A Ring part 16B Connection part 23 1st pin which is one pin 24 2nd pin which is the other pin 50-52, 60-64 , 70-72 Building component W3 Thickness dimension of damping device W4 Dimensions of first bracket in thickness direction of damping device W5 Brace size in thickness direction of damping device W6 Thickness direction of damping device Dimension of second bracket at S S Vibration damping thickness extension region

Claims (2)

A vibration damping device disposed inside a quadrangular frame formed in a square shape in front view by the four structural members constituting the building, and extending radially from the vibration damping device, the vibration damping The vibration energy that is deformed by the quadrangular frame is absorbed by plastic deformation of the vibration damping tool that is transmitted through the brace. In a vibration control device that suppresses vibration,
A building component such as a wall material is housed and arranged inside the rectangular frame, and the size of the brace in the thickness direction of the vibration control device orthogonal to the extending direction of the brace is the vibration control device. The thickness of the damper is assumed when the brace is extended in the extension direction of the brace by the same dimension as the thickness of the damper. It does not protrude from the extension region in the thickness direction of the vibration damper ,
The end of each brace on the vibration control device side is rotatably connected to the vibration control device by a first bracket, and the end of each brace on the square frame side is connected by a second bracket. The first and second brackets in the thickness direction of the vibration damper are connected to the rectangular frame so as to be rotatable, and the thickness dimension of the first and second brackets is the same as or smaller than the thickness dimension of the vibration damper. The first and second brackets do not protrude in the thickness direction of the damping tool from the damping tool thickness extension region,
Of the four second brackets, at least one second bracket is provided with two pins, and one of the pins is connected to the second bracket coupled to the rectangular frame. A pin for rotatably connecting the brace, and the other pin is a pin for defining an angle at which the brace rotates around the one pin. Shaker. 2. The vibration damping device according to claim 1 , wherein the vibration damping tool is a cast product integrally formed by a casting method.

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