JP4850482B2 - Damping brace structure - Google Patents

Description

  The present invention relates to a seismic brace structure.

  Various types of seismic brace structures used for buildings and structures have been provided, but they absorb energy when pulling and perform seismic control, and do not buckle when compressed. A seismic brace that can be realized at low cost has not yet been provided.

  In view of the above problems, the present invention provides a vibration control brace that absorbs energy during tension to perform vibration control and does not buckle during compression, and that can be realized at low cost. It is an object to provide a structure.

The above-mentioned problem is that the spacing part in the direction orthogonal to the brace axis direction is unchanged,
A viscoelastic body installed between the restraining portions;
A vibration control mechanism portion provided with a wedge portion installed between the viscoelastic body and one restraint portion is provided,
When the brace is pulled, the wedge part advances between the viscoelastic body and the restraining part, and by the advancement, the viscoelastic body undergoes shear deformation, and the wedge part, the restraining part, and / or the viscoelasticity. The body and the restraining part are pressed against each other to resist pulling by frictional force,
When the compressive force acts on the brace, the wedge part moves backward between the viscoelastic body and the restraining part, and the backward movement causes the wedge part and the restraining part, and / or the viscoelastic body and the restraining part to move to the brace. It is solved by a seismic control brace structure characterized in that the brace is shortened by sliding in the axial direction.

  In this seismic control brace, at the time of pulling, the viscoelastic body undergoes shear deformation by the advancement of the wedge part, so that energy is absorbed and the seismic control action is performed. At that time, when the wedge part and the restraint part and / or the viscoelastic body and the restraint part slip against the frictional force caused by the pressing, energy is absorbed by the slip and the vibration control action is performed. .

  Further, during compression, the wedge part and the restraining part and / or the viscoelastic body and the restraining part slide in the direction of the brace to shorten the brace due to the backward movement of the wedge part. Bending is prevented. At that time, when the wedge part and the restraint part and / or the viscoelastic body and the restraint part slip against the frictional force caused by the pressing, energy is absorbed by the slip, and the damping action is also exerted even during compression. Done.

  And since it implement | achieves by the connection of the above restraint parts, a viscoelastic body, and a wedge part, realization at low cost is attained.

  Since the vibration control brace of the present invention is as described above, it absorbs energy during tension to perform vibration control, and does not buckle during compression, and can be realized at low cost. it can.

  Next, the best mode for carrying out the present invention will be described with reference to the drawings.

  The seismic brace structure of the first embodiment shown in FIG. 1 is applied to a seismic control wall used in a building or the like. In FIG. 1 (a), reference numeral 1 denotes a steel wall panel frame assembled in a rectangular ring shape. , 2 and 2 are pairs of braces, and each brace 2 is made of a strip-shaped steel plate, and one brace 2 is connected between the diagonal portions of the panel frame 1 to connect the diagonal portions. The other brace 2 crosses the one brace and extends between the other diagonal portions of the panel frame 1 to connect the diagonal portions.

  Each brace 2 is provided with vibration control mechanisms 3 and 3 at two locations spaced in the middle in the direction of the brace axis, and the brace 2 is divided at each vibration control mechanism 3 and 3, and the brace shaft It consists of three brace members 2a ... in the direction.

  As shown in FIGS. 1 (b) and 1 (c), each of the vibration control mechanisms 3 is a restraining portion in which the distance dimension in the direction orthogonal to the brace axis direction is fixed by the connecting plates 4 and 4 on both sides. A pair of restraining plates 5, 5, a viscoelastic body 6 installed between the restraining plates 5, 5, and a wedge material 7 as a wedge portion installed between the viscoelastic body 6 and one of the restraining plates 5. And.

  Then, between the viscoelastic body 6 and the other restraining plate 5, one divided brace material 2a is installed, and between the wedge material 7 and the one restraining plate 5 is divided. The other brace material is installed, and the brace material 2 a between the viscoelastic body 6 and the restraint plate 5 is integrated with the viscoelastic body 6 and is slidable with respect to the restraint plate 5. On the other hand, the brace material 2 a between the wedge material 7 and the restraint plate 5 is integrated with the wedge material 7 and is slidable with respect to the restraint plate 5. Reference numerals 8 and 8 are stoppers for holding the restraining plates 5 and 5 in position on the vibration control mechanism 3.

  In the above-mentioned vibration control wall, as shown in FIG. 2 (a), when a tensile force is applied to the brace 2 by a horizontal force caused by the earthquake, the wedge material 7 advances between the viscoelastic body 6 and the restraint plate 5. By the advance, the viscoelastic body 6 undergoes shear deformation to absorb energy and perform a vibration control action.

  Further, by the advancement, the wedge material 7 and the restraint plate 5 and the viscoelastic body 6 and the restraint plate 5 are pressed against each other to resist pulling by the frictional force. At that time, the wedge material 7 and the restraint plate 5 and / or the viscoelastic body 6 and the restraint plate 5 may be made to slide against the frictional force caused by the pressing, and the slip does not occur. However, when slipping occurs, energy is also absorbed by the slipping and a vibration control action is performed.

  On the other hand, as shown in FIG. 2 (b), when a compressive force is applied to the brace 2 by a horizontal force caused by an earthquake, the wedge material 7 moves back between the viscoelastic body 6 and the restraint plate 5, It is prevented that the wedge material 7 and the restraint plate 5 and / or the viscoelastic body 6 and the restraint plate 5 slide in the brace axis direction, the brace 2 is shortened, and the brace 2 is prevented from buckling.

  In the second embodiment shown in FIGS. 3A and 3B, the brace 2 is divided into an outer cylinder brace material 2b and an inner cylinder brace material 2c, and the end of the inner cylinder brace material 2c is the outer cylinder brace material 2b. The damping mechanism part 3 is incorporated in the overlapping part. That is, the vibration control mechanism 3 uses the inner cylinder brace material 2c and the outer cylinder brace material 2b as restraints, and the viscoelastic body 6 is annularly installed in the annular space between them, and the viscoelastic body A wedge material 7 is annularly installed in an annular space between 6 and the inner cylinder brace material 2c. The wedge material 7 has a short cylindrical shape with an outer peripheral cone, and a slit 9 is inserted in one place in the circumferential direction. The diameter is reduced using the slit 9 and the inner cylinder brace material 2c is reduced. It is made to be able to be in a pressed state with respect to the outer peripheral surface.

  The viscoelastic body 6 is integrated with the outer cylinder brace material 2b, and the wedge material 7 is slidable with the inner cylinder brace material 2c. A stopper 10 is provided on the inner cylinder brace material 2c and moves the wedge material 7 forward when a tensile force acts on the brace 2. Others are the same as the damping wall of 1st Embodiment.

  In the vibration control wall provided with the vibration control mechanism 3, as shown in FIG. 3 (c), when a tensile force is applied to the brace 2 by the horizontal force caused by the earthquake, the wedge material 7 becomes the stopper of the inner cylinder brace material 2c. 10 is applied to advance between the viscoelastic body 6 and the inner cylinder brace material 2c, and the advancement causes the viscoelastic body 6 to undergo shear deformation to absorb energy and perform a vibration control action.

  Further, by the advancement, the wedge material 7 is reduced in diameter using the slit 9, and the inner peripheral surface of the wedge material 7 and the outer peripheral surface of the inner cylinder brace material 2c are pressed against each other to resist pulling by frictional force. .

  On the other hand, as shown in FIG. 2 (d), when a compressive force is applied to the brace 2 by a horizontal force caused by an earthquake, the wedge material 7 is displaced in a direction of retreating between the viscoelastic body 6 and the inner cylinder brace material 2c. Then, the wedge material 7 is restored and expanded in diameter due to the backward displacement, and the inner cylinder brace material 2c slips and leaves the wedge material 7, and advances to the inside of the outer cylinder brace material 2b to shorten the brace 2. 2 is prevented from buckling deformation. At that time, when the wedge material 7 and the inner cylinder brace material 2c are made to slip against the friction force between them, the energy is absorbed by the slip and the vibration control action is performed. Is called.

  Moreover, when the viscoelastic body 6 and the wedge material 7 are integrated, when the compressive force acts on the brace 2 by the horizontal force caused by the earthquake, as shown in FIG. Due to the backward displacement, the viscoelastic body 6 undergoes shear deformation, absorbs energy, and performs a vibration control action. In addition, it is arbitrary to perform the vibration control action when the brace is compressed, and the viscoelastic body 6 and the wedge material 7 may not be integrated. Further, even when the viscoelastic body 6 and the wedge material 7 are not integrated, the viscoelasticity at the time of brace compression is due to the adhesion of the wedge material 7 and the viscoelastic body 6 due to the advancement of the wedge material 7 at the time of brace tension. The body 6 may be subjected to shear deformation so as to perform a vibration control action.

  Although the embodiment of the present invention has been described above, the present invention is not limited to this, and various modifications can be made without departing from the spirit of the invention. For example, in the second embodiment, the case where a cylindrical wedge material with a slit in one circumferential direction is used as the wedge material is shown, but a plurality of wedge materials are provided in the circumferential direction. It may be of a structure installed with a certain interval. Moreover, although each said embodiment showed the case where it used for the brace for damping walls, it may be used for braces, such as a floor and a ceiling. Further, the brace is not limited to a strip steel plate shape or a cylindrical shape, and may be in various forms.

The seismic brace structure of 1st Embodiment is shown, A figure (A) is a front view in the state used as the brace of a damping wall panel, A figure (B) is II sectional view taken on the line of FIG. The figure and figure (C) are the II-II line arrow directional views of figure (I). Fig. (A) is a sectional front view showing the operating state of the vibration control mechanism when the brace is pulled, and Fig. (B) is a sectional front view showing the operation state of the vibration control mechanism when the brace is compressed. FIG. 2A shows a second embodiment, FIG. 1A is a cross-sectional front view of the vibration control mechanism, FIG. 2B is a cross-sectional view taken along line III-III of FIG. 1A, and FIG. A sectional front view showing the operating state of the seismic mechanism portion, and FIG. (D) is a sectional front view showing the operating state of the seismic control mechanism portion during brace compression.

Explanation of symbols

2 ... Brace 3 ... Damping mechanism part 5 ... Restraint plate (restraint part)
6. Viscoelastic body 7. Wedge material (wedge part)
2b ... Outer cylinder brace material (restraint part)
2c ... Inner cylinder brace material (restraint part)

Claims (6)

A bracing mechanism is provided in the middle part of the brace made of strip steel plate in the brace axis direction, and the brace is divided in the damping mechanism part.
The vibration control mechanism includes a pair of restraint plates in which a distance dimension in a direction perpendicular to the brace axis direction is fixed by a coupling plate on both sides, a viscoelastic body installed between the restraint plates, and the viscous plate. A wedge material installed between the elastic body and one restraint plate,
One split brace material is installed between the viscoelastic body and the other restraint plate, and another split brace material is installed between the wedge material and the one restraint plate. ,
While the brace material between the viscoelastic body and the other restraint plate is integrated into the viscoelastic body, the brace material is made slidable with respect to the other restraint plate,
The brace material between the wedge material and the one restraint plate is integrated with the wedge material, and is slidable with respect to the one restraint plate,
When a tensile force acts on the brace, the wedge material advances between the viscoelastic body and the one restraint plate, and by the advancement, the viscoelastic body undergoes shear deformation and absorbs vibration energy, and the wedge material And the one restraint plate, and the viscoelastic body and the other restraint plate are pressed against each other via a brace material to resist tension by a frictional force,
When a compressive force acts on the brace, the wedge material moves back between the viscoelastic body and the one restraint plate 5, and the backward movement causes the wedge material and the one restraint plate and / or the viscoelastic body to move. A seismic control brace structure characterized in that the other restraining plate slides in the direction of the brace axis so that the brace is shortened .   The seismic damping brace structure according to claim 1, wherein each brace member is provided with a stopper that holds the pair of restraining plates in a damping mechanism part.   When a tensile force acts on the brace, the wedge material and the one restraint plate, and the viscoelastic body and the other restraint plate are made to slide against the frictional force caused by the pressing, The seismic brace structure according to claim 1 or 2, wherein the vibration energy is absorbed also by the slip.   The brace is divided into the outer cylinder brace material and the inner cylinder brace material, the end of the inner cylinder brace material is inserted into the end of the outer cylinder brace material, and the vibration control mechanism is incorporated in the overlapping part ,
  The vibration control mechanism includes the inner cylinder brace material and the outer cylinder brace material as a restraining portion, and a viscoelastic body is annularly installed in the annular space between them, and the viscoelastic body and the inner cylinder brace The wedge material is installed in a ring shape in the annular space between the materials,
  The wedge material has a short cylindrical shape with an outer peripheral cone, and a slit is inserted at one or a plurality of locations in the circumferential direction, and the diameter is reduced using the slit, and the inner cylinder brace material is reduced in diameter. It is made to be able to be pressed against the outer peripheral surface of the
  The viscoelastic body is integrated with the outer cylinder brace material, the wedge material is slidable on the inner cylinder brace material, and when the tensile force acts on the inner cylinder place material, the wedge material is There is a stopper to move forward,
  When a tensile force acts on the brace, the wedge material is urged by the stopper of the inner cylinder brace material and advances between the viscoelastic body and the inner cylinder brace material, and the advancement causes the viscoelastic body to undergo shear deformation. The wedge material is reduced in diameter using the slit, and the inner peripheral surface of the wedge material and the outer peripheral surface of the inner cylinder brace material are pressed against each other so that the frictional force resists pulling. Has been made,
  When compressive force is applied to the braces, the wedge material is displaced in the direction of retreating between the viscoelastic body and the inner cylinder brace material, and the wedge material is restored and expanded in diameter by the backward displacement, and the inner cylinder brace material slides. The seismic brace structure is characterized in that it leaves the wedge material and advances into the outer cylinder brace material to shorten the brace.   When the compression force acts on the brace, the wedge material and the inner cylinder brace material are caused to slip against the friction force between them, and the vibration energy is absorbed by the slip. The seismic brace structure according to claim 4, which is made.   The viscoelastic body and wedge material are integrated, and when compressive force is applied to the brace, the viscoelastic body undergoes shear deformation due to the backward displacement of the wedge material and absorbs vibration energy. Item 6. A seismic brace structure according to item 4 or 5.

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