JP2717144B2 - Friction damper - Google Patents

Description

[Detailed description of the invention] "Industrial application field" This invention is arranged inside a frame composed of columns and beams of a building, and is used for the purpose of suppressing the shaking of this building such as seismic motion. Friction damper to be used.

"Conventional technology and its problems" In recent years, many high-rise buildings have been constructed in Japan. In this case, Japan is one of the world's leading earthquake nations, and in addition to ensuring seismic safety, such as preventing buildings from collapsing in the event of a major earthquake, damping the building as much as possible during a small or medium-sized earthquake.・
It is desired that the building be provided with a seismic isolation function to alleviate the psychological uneasiness given to residents.

In recent years, as typified by intelligent buildings, important devices such as electronic computers, OA devices, and communication facilities are increasingly housed in buildings. if,
If these important devices were destroyed by an earthquake, the social consequences of them would be immense, but not all of them were designed to be seismic. It is necessary for the side to take some measures.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a friction damper capable of efficiently suppressing a shaking of a building due to seismic motion or the like.

Means for Solving the Problems The present invention relates to a frictional damper arranged at a crossing portion of a pair of braces crossed in a frame composed of columns and beams of a building as a whole having a quadrangular shape. A link mechanism is formed, and each side of the link mechanism is formed by laminating a plurality of flat plate-like friction plates, and ends of the friction plates on each side are formed by adjacent other sides. The end portions of the friction plates are alternately laminated and pressed by a fastening means in a relatively rotatable state, and a friction material is provided on the contact surfaces of the friction plates, and the brace is provided. Are relatively rotatably connected to the friction plate by the fastening means.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

1 to 3 are views showing a friction damper according to one embodiment of the present invention. In these figures, reference numeral 1
Is a column, and reference numeral 2 is a beam, both of which are formed of steel. And, on a diagonal line L inside the frame constituted by the pair of columns 1, 1 and beams 2, 2, a pair of braces 3,
The friction dampers 4 of this embodiment are arranged at the intersections of the braces 3 and 3.

The friction damper 4 forms a quadrilateral link mechanism as a whole as shown in FIG. Each side of the link mechanism is formed by laminating a plurality of flat friction plates 5, 5,... As shown in FIG.
The ends of the friction plates 5, 5 ... on each side are alternately stacked on the ends of the friction plates 5, 5, ... forming the other adjacent sides, and are relatively rotatable. In this state, they are pressed against each other by bolts 6 and nuts 7 (fastening means).

As shown in FIG. 3, flat plate-like friction members 8, 8,..., Which are square in plan view, are adhered to at least one of the surfaces of the friction plates 5, 5 which are in contact with each other. As the friction material 8, for example, phosphor bronze, brass, carbon graphite, a sintered material or the like formed in a thin plate shape is used. If the material can prevent seizure due to frictional heat and obtain a uniform frictional force, it is well known. May be appropriately selected from the above materials. Or,
Of course, a brake lining material may be used for the purpose of improving the frictional force. In addition, the area of the friction material 8 to be adhered is also arbitrary, and may be appropriately selected according to the friction force to be obtained by the friction damper 4.

The brace 3 is divided into two diagonal members 9, 9. And the friction damper 4
The pillars 1 and 1 and the beams 2 and 2 are connected via the diagonal members 9
It is connected to. One end of the diagonal member 9 is pin-connected to a gusset plate 10 attached to a column / beam joint C, and the other end is pin-connected to the friction damper 4 via the bolt 6 and the nut 7. In order to make the rotation of these oblique members 9, 9, ... smooth, the bolt 6,
Grease is applied between the nut 7 and the diagonal members 9 or an oil-impregnated bearing member is interposed. Of course, other well-known means may be used.

Next, the operation of the friction damper 4 having the above-described configuration will be described.

When seismic force acts on the building to which the friction damper 4 is attached, the frame composed of the columns 1, 1 and the beams 2, 2 is deformed, and compressive force or 9 Tensile force acts. Therefore, as shown in FIG. 4, the friction damper 4 is deformed into a parallelogram as a whole. Assuming that the amount of expansion and contraction occurring in the diagonal members 9 is a, each corner of the friction damper 4 (that is, each end of the friction plate 5) is Just rotate. Since the frictional surfaces are generated by the rotation of the friction plates 5 and 5 (the surfaces of the friction materials 8 and 8), a part of the vibration energy of the building is opposed to the frictional forces and the friction plates 5 Is consumed by the energy to rotate 5,
This energy is converted into heat energy in the friction members 8 and absorbed. Thereby, the vibration energy of the building is absorbed by the friction damper 4, and the vibration of the building is suppressed.

Here, assuming that the number of stacked friction plates 5,... Is n, the number of friction surfaces at each corner of the friction damper 4 is also n, and therefore the total number of friction surfaces is 4n. For example, when n = 16, the total number of friction surfaces is 64. Therefore, if the tightening force of each bolt 6 and nut 7 is 1 t, the friction damper 4 as a whole
A friction force equivalent to 64t can be obtained, thereby improving the energy absorption efficiency of the above-mentioned friction.

As shown in FIG. 5, a square friction material 8 having one side b
Is lost on the friction surface when is rotated by the angle θ
Is P and the friction coefficient is μ. Becomes That is, the energy consumed by the friction damper 4 is proportional to the rotation angle θ and the total pressure P. The total pressure P is a pressure introduced by the tightening force of the bolts 6 and the nuts 7 connecting the friction plates 5 and 5 to each other. Therefore, it is necessary to tighten the bolts 6 and the nuts 7 so that a predetermined axial force is introduced into the friction plates 5 and 5. In practice, a calibration test of the tightening torque and the axial force is performed in advance, and a predetermined axial force is introduced to the friction plates 5, 5 by bolting with the predetermined tightening torque.

FIG. 6 shows the history characteristics of the frictional force F and the rotation angle θ. The area of the hysteresis characteristic corresponds to the energy lost in one cycle. As shown in the figure, the friction damper 4 is characterized in that the area of the hysteresis characteristics is larger than that of the viscous damper such as another oil damper or the hysteretic damper such as a steel rod damper, and therefore, the energy absorbing capacity is large.

The detailed configuration of the friction damper 4 of the present invention is not limited to the above embodiment, and various modifications are possible.
As an example, if a tightening force is appropriately applied to the bolts 6 and the nuts 7 in accordance with the swing of the building by hydraulic control, a large fastening force may be applied only when a large-amplitude shake due to an earthquake or the like occurs in the building, and If the tightening force is reduced just before the shaking stops, the phenomenon that the friction plates 5, 5 are locked with each other can be suppressed, which is very preferable. When the distance between the columns 1 and 1 is relatively narrow, as described above,
It is sufficient that one friction damper 4 is attached to the frame composed of the beam 1 and the beams 2 and 2. However, when the distance between the columns 1 and 1 is widened, the braces 3 intersecting each other as shown in FIG. By providing a plurality of sets and a plurality of friction dampers 4 and 4, respectively, a plurality of sets can be attached to the frame.

[Effects of the Invention] As described in detail above, according to the present invention, a friction damper arranged at the intersection of a pair of braces intersecting in a frame composed of columns and beams of a building As a whole, constitute a quadrilateral link mechanism, each side of the link mechanism is formed by laminating a plurality of flat plate-like friction plates, and both ends of the friction plates on each side are adjacent to each other. Alternately stacked on the ends of the friction plates constituting the other side and pressed against each other by a fastening means in a relatively rotatable state, and a friction material is applied to the contacting surfaces of these friction plates. And the brace is connected to the friction plate by the fastening means so as to be relatively rotatable, so that when the seismic force acts on the building, the entire friction damper is rotated and deformed around the fastening means so that the friction plate is rotated. Rotates. Then, since the rotation of these friction plates generates a frictional force on the surface of the friction material provided on the surface in contact with the friction plate, a part of the vibration energy of the building is converted into heat energy of the friction material and absorbed, and The vibration of the object is suppressed. Moreover, since the ends of the friction plates are alternately laminated with respect to the ends of the friction plates constituting the other sides adjacent to each other, the total number of friction surfaces increases, so that the energy due to the above-described friction is reduced. The absorption efficiency is improved. Therefore, according to the present invention, it is possible to realize a friction damper that can efficiently suppress the shaking of a building due to seismic motion or the like.

[Brief description of the drawings]

1 and 2 are views showing a friction damper according to an embodiment of the present invention, wherein FIG. 1 is a front view showing a state of being attached to a building, and FIG. 2 is II in FIG. 3 is a front view showing a mounted state of the friction material, FIG. 4 is a schematic view showing a deformed state of the friction damper, and FIG. 5 is a view showing a force acting on the friction damper. Diagram for explaining,
FIG. 6 is a diagram showing hysteresis characteristics of the friction damper, and FIG. 7 is a sectional view showing a friction damper according to another embodiment of the present invention. DESCRIPTION OF SYMBOLS 1 ... pillar, 2 ... beam, 3 ... brace, 4 ... friction damper, 5 ... friction plate, 6 ... bolt, 7 ... nut (all fastening means), 8 ... friction material, 9 …… Slanting material.

Claims (1)

(57) [Claims] 1. A friction damper disposed at a crossing portion of a pair of braces crossed in a frame composed of columns and beams of a building, wherein the friction damper has a quadrangular link as a whole. Each side of the link mechanism is formed by laminating a plurality of flat plate-like friction plates, and the ends of the friction plates on each side are connected to other adjacent sides. The end portions of the friction plates are alternately stacked and pressed by a fastening means in a relatively rotatable state, and a friction material is provided on the surfaces of the friction plates that are in contact with each other. The brace is connected to the friction plate by the fastening means so as to be relatively rotatable.