JP6628923B1 - Sliding seismic isolation device - Google Patents

Abstract

An object of the present invention is to eliminate a stainless steel sliding plate and a stopper ring attached to a concave to reduce manufacturing costs, to prevent damage to a friction material due to heat generated by a slider, and to prevent a decrease in durability. Providing equipment. A concave slider (20, 30) having first sliding surfaces (21, 31) and a metallic slider (10) having second sliding surfaces (12, 13) abutting on the first sliding surfaces (21, 31). And at least a friction material 40 made of PTFE is fixed to the first sliding surfaces 21 and 31, and the second sliding surfaces 12 and 13 are exposed metal surfaces. is there. [Selection diagram] FIG.

Description

  The present invention relates to a sliding seismic isolation device.

  In Japan, which is an earthquake-prone country, various structures such as buildings, bridges, elevated roads, and detached houses have various seismic resistance technologies, such as technologies to resist seismic force and technologies to reduce seismic force entering structures. Technology, seismic isolation technology, and vibration control technology have been developed and applied to various structures. Above all, the seismic isolation technology is a technology for reducing the seismic force itself entering the structure, so that the vibration of the structure during an earthquake is effectively reduced. An outline of this seismic isolation technology is that a seismic isolation device is interposed between the foundation, which is the lower structure, and the upper structure to reduce the transmission of the vibration of the foundation due to the earthquake to the upper structure, and to reduce the vibration of the upper structure. To assure structural stability. In addition, this seismic isolation device is effective not only at the time of an earthquake but also at reducing the influence of traffic vibrations that always act on the structure on the upper structure.

There are various types of seismic isolation devices, such as a laminated rubber bearing device containing a lead plug, a high damping laminated rubber bearing device, a device combining a laminated rubber bearing and a damper, and a sliding seismic isolation device. Among them, there are two types of sliding seismic isolation devices: a flat sliding seismic isolation bearing and a spherical sliding seismic isolation bearing. The flat sliding seismic isolating bearing has no restoring force, but the spherical sliding seismic isolating bearing has a restoring force. It has a self-centering function at the time. By the way, in the conventional sliding seismic isolation device, since the reference surface pressure of Teflon (registered trademark) and the like interposed in the device is 20 N / mm ² (20 MPa), the load capacity is increased due to the increase in the height of the structure. When the weight became heavy, the size of the sliding seismic isolation device had to be increased in order to make the sliding seismic isolation device of a plane size corresponding to this load. For this reason, cost competitiveness is lower than that of different types of seismic isolation devices such as a laminated rubber seismic isolation device, and as a result, the frequency of use is low.

Therefore, for example, a high-performance sliding seismic isolation device having a slider that achieves a surface pressure of 60 N / mm ² (60 MPa) has been proposed. Specifically, an upper shoe (upper concave) and a lower shoe (lower concave) provided with a sliding surface having a curvature, and an upper surface and a lower surface having a curvature in contact with each shoe between the upper and lower shoes. And a steel slider provided with a sliding door. The upper and lower surfaces of the slider are provided with a double woven fabric layer composed of PTFE fibers and fibers having higher tensile strength than PTFE fibers (for example, see Patent Document 1).

Japanese Patent No. 5521096

According to the sliding seismic isolation device described in Patent Literature 1, it is possible to provide a sliding seismic isolation device having high seismic isolation performance against surface pressure of about 60 N / mm ² . By the way, the configuration of the conventional (spherical) sliding seismic isolation device described in Patent Document 1 is shown in FIG. As shown in FIG. 5, the sliding seismic isolation device SI is configured such that a slider S is slidably disposed between a lower surface B11 of an upper concave B1 and an upper surface B21 of a lower concave B2. In order to prevent the slider S from falling off, stopper rings B12 and B22 are attached to both the lower surface B11 of the upper concave B1 and the upper surface B21 of the lower concave B2.

  The upper concave B1 and the lower concave B2 are generally formed of a steel material, and a stainless steel sliding plate C1 having excellent rust resistance is attached to the lower surface B11 and the upper surface B21 of the upper concave B1 and the lower concave B2. The sliding plate C1 is manufactured by bending a stainless steel plate, and after the sliding plate C1 is attached to each of the upper concave B1 and the lower concave B2, mirror finishing such as buffing is performed, and the finished surface is coated with fluorine. Etc. are applied. Although the sliding plate C1 is excellent in rust prevention as described above, its surface is exposed to the air. Rust occurs. In addition, for example, when the sliding seismic isolation device SI is applied to a building such as a coastal area, the salt contained in the outside air adheres to the surface of the sliding plate C1, so that the sliding plate C1 is easily rusted.

  As described above, rust is generated on the surface of the sliding plate C1, and there is a possibility that the friction coefficient of the sliding seismic isolation device SI increases. Therefore, the space between the upper concave B1 and the lower concave B2 is shielded from the outside air by interposing a ring seal material R made of rubber, for example, between the upper and lower stopper rings B12 and B22, thereby preventing rust on the sliding plate C1. I try to suppress it.

  However, the sliding plate C1 made of stainless steel is attached over the entire area (the entire area of the sliding surface) of the lower surface B11 of the upper concave B1 and the upper surface B21 of the lower concave B2, and furthermore, the ring seal material R is attached. The production cost of SI increases. In particular, if the thickness of the sliding plate C1 made of stainless steel is too small, wrinkles are likely to occur when the sliding plate C1 is attached to the upper concave B1 or the lower concave B2. In addition, it is necessary to perform machining and mirror finishing, and these various kinds of processing on the slide plate C1 are major factors that increase manufacturing costs.

  Further, in the sliding seismic isolation device SI, a friction material C2 such as a double fabric layer made of PTFE fiber and other fibers is attached to the upper surface S1 and the lower surface S2 of the slider S formed of a steel material such as stainless steel. I have. When the slider S slides between the upper concave B1 and the lower concave B2 during an earthquake, the temperature of the slider S increases. In the case of an earthquake motion in which vibration continues for a long time, such a rise in the temperature of the slider S becomes even more remarkable. When the temperature of the slider S rises, the friction material C2 attached to the upper and lower surfaces of the slider S may be damaged by heat from the slider S, which is a heat source. Damage to the friction material C2 leads to a decrease in the durability of the sliding seismic isolation device SI.

  The present invention has been made in view of the above problems, and can eliminate a stainless steel sliding plate and a stopper ring attached to a concave to reduce a manufacturing cost, and suppress a damage of a friction material due to heat generation of a slider. It is an object of the present invention to provide a sliding seismic isolation device that can prevent a decrease in durability.

In order to achieve the above object, one embodiment of the sliding seismic isolation device according to the present invention includes:
A concave seismic isolation device having a concave having a first sliding surface and a metal slider having a second sliding surface abutting on the first sliding surface,
A friction material made of at least PTFE is fixed to the first sliding surface,
The second sliding surface is an exposed metal surface.

  According to this aspect, the stainless steel sliding plate provided on the sliding surface of the concave in the conventional sliding seismic isolation device is abolished, and at least the sliding surface (first sliding surface) of the concave is made of PTFE. Since the friction material is fixed, there is no problem that rust is generated on the sliding plate and the friction coefficient of the sliding seismic isolation device is increased.

  In addition, since there is no problem of rusting of the sliding plate, the ring seal material can be eliminated, and in combination with the elimination of the sliding plate, the production cost of the sliding seismic isolation device can be reduced.

  Further, at least the friction material made of PTFE is not fixed to the sliding surface (second sliding surface) of the slider that comes into contact with the friction material, unlike the conventional sliding seismic isolation device, and the metal surface is exposed. Therefore, the problem that the friction material fixed to the slider surface is damaged by the heat from the slider that generates heat when sliding along the sliding surface of the concave during an earthquake, and the friction material is damaged Therefore, the durability of the sliding seismic isolation device is not reduced. That is, although at least a friction material made of PTFE is attached to the sliding surface of the concave, the portion of the friction material that comes into contact with the slider that slides during an earthquake changes as needed with the sliding of the slider. The same portion of the material does not receive the heat from the slider constantly, and the damage of the friction material due to the heat transfer from the slider is suppressed.

  The metal slider is formed of, for example, steel or stainless steel. Even when the slider is made of stainless steel, the metal surface of the slider, such as the stainless steel surface, which is the sliding surface of the slider, is in constant contact with the friction material, so the metal surface of the slider in contact with the friction material must be exposed to air. No rust on the metal surface.

  Further, “at least a friction material made of PTFE” means a friction material made of only PTFE (Polytetrafluoroethylene, polytetrafluoroethylene), a friction material made of a composite material of PTFE and another resin, and a material made of PTFE A friction material having a laminated structure of a friction material made of a friction material and another resin, a friction material made of a woven fabric such as a double woven fabric made of PTFE fibers and other resin fibers, and the like are included. In the form in which the friction material is stuck to the sliding surface of the concave, the metal finishing surface is only the surface of the slider that comes into contact with the friction material.

Further, in another aspect of the sliding seismic isolation device according to the present invention, the concave includes an upper concave and a lower concave both having a first sliding surface,
The slider is a double pendulum type having upper and lower second sliding surfaces that contact upper and lower first sliding surfaces on upper and lower surfaces thereof.

  According to this aspect, by eliminating the sliding plate, the problem of rust can be solved and the manufacturing cost can be reduced.Furthermore, the damage of the friction material due to heat transfer from the slider is suppressed. A double pendulum-type sliding seismic isolation device can be provided.

Further, another aspect of the sliding seismic isolation device according to the present invention includes one concave
A single pendulum type including a cradle for holding the slider while the second sliding surface of the slider is in contact with the first sliding surface.

  According to this aspect, by eliminating the sliding plate, the problem of rust can be solved and the manufacturing cost can be reduced.Furthermore, the damage of the friction material due to heat transfer from the slider is suppressed. A single pendulum-type sliding seismic isolation device can be provided.

  In another aspect of the present invention, the friction material is a woven fabric containing PTFE fibers.

According to this aspect, since the woven fabric containing PTFE fiber is attached to the sliding surface of the concave, the slidability of the sliding seismic isolation device under a high surface pressure of about 60 N / mm ² is improved. Here, as the “woven fabric containing PTFE fibers”, for example, a double woven fabric having PTFE fibers and fibers having higher tensile strength than the PTFE fibers is exemplified. In this double woven fabric, it is desirable that the PTFE fiber is disposed so as to be located on the slider side. When a friction material made of a double woven fabric containing PTFE fibers is applied, the PTFE fibers having a relatively low tensile strength and thus a low crush resistance under a load are subjected to repeated vibrations under pressure (pressure sliding force). It is easy to collapse when it receives. However, since the crushed PTFE fiber has a higher tensile strength and therefore stays in the fiber having high crush resistance, at least a part thereof can face the sliding surface of the slider. Slidability can be enjoyed. This leads to an improvement in the durability of the sliding seismic isolation device having the desired seismic isolation performance.

  In another aspect of the sliding seismic isolation device according to the present invention, the slider is made of stainless steel, and the metal surface is a mirror-finished surface of stainless steel.

  According to this aspect, the metal surface of the slider in contact with the friction material fixed to the first sliding surface of the concave is a mirror-finished surface made of stainless steel (mirror-finished surface). The rust resistance of the surface is improved, and smooth sliding of the slider is ensured. As described above, since the metal surface (stainless steel surface) of the slider in contact with the friction material is constantly in contact with the friction material, the metal surface of the slider in contact with the friction material is not exposed to air, Rust on the surface is suppressed.

  As can be understood from the above description, according to the sliding seismic isolation device of the present invention, the production cost can be reduced by eliminating the stainless steel sliding plate and the stopper ring attached to the concave, and the friction caused by the heat generated by the slider can be reduced. It is possible to provide a sliding seismic isolation device capable of suppressing damage to materials and preventing a decrease in durability.

FIG. 2 is an exploded perspective view of the sliding seismic isolation device according to the first embodiment. It is a longitudinal section of a sliding seismic isolation device concerning a 1st embodiment. It is a schematic diagram explaining the structure of an example of a friction material made of a double woven fabric together with a mode of attachment to a concave. It is a longitudinal section of a sliding seismic isolation device concerning a 2nd embodiment. It is a longitudinal section of the conventional sliding seismic isolation device.

  Hereinafter, the sliding seismic isolation device according to each embodiment will be described with reference to the accompanying drawings. In the specification and the drawings, substantially the same components are denoted by the same reference numerals, and redundant description may be omitted.

[Sliding Seismic Isolation Device According to First Embodiment]
First, an example of the sliding seismic isolation device according to the first embodiment will be described with reference to FIGS. 1 to 3. Here, FIG. 1 is an exploded perspective view of the sliding seismic isolation device according to the first embodiment, and FIG. 2 is a longitudinal sectional view of the sliding seismic isolation device according to the first embodiment. FIG. 3 is a schematic diagram illustrating the structure of an example of a friction material made of a double woven fabric, together with a manner of attachment to a concave.

  The sliding seismic isolation device 100 includes an upper concave 20 (an example of a concave) and a lower concave 30 (an example of a concave) provided with a sliding surface (first sliding surface) having a curvature, the upper concave 20 and the lower concave 30. Between the upper surface 12 and the lower surface 13 having the same curvature as the lower surface 21 which is the first sliding surface of the upper concave 20 and the upper surface 31 which is the first sliding surface of the lower concave 30. And a metal slider 10 having a moving surface).

  Each of the upper concave 20 and the lower concave 30 is a plate having a square shape in a plan view, and is a rolled steel material for welding steel (SM490A, B, C, or SN490B, C, or S45C), or a stainless steel (SUS material), a cast steel, or a cast iron. Etc. are formed. The first sliding surfaces provided on the lower surface 21 of the upper concave 20 and the upper surface 31 of the lower concave 30 are curved in a circular shape in plan view, and a friction material 40 is attached to both first sliding surfaces. I have.

  As shown in FIG. 3, the friction material 40 is formed of a double woven fabric, and the double woven fabric 40 includes a PTFE fiber 43 (polytetrafluoroethylene, polytetrafluoroethylene) and a fiber 47 (higher tensile strength) than the PTFE fiber 43. Strength fibers). Then, on both the lower surface 21 of the upper concave 20 and the upper surface 31 of the lower concave 30, the double woven fabric 40 is formed such that the PTFE fiber 43 is located on the slider 10 side and the lower surface 21 of the upper concave 20 and the upper surface of the lower concave 30. 31.

  Here, the “fiber having higher tensile strength than PTFE fiber” includes polyamides such as nylon 6.6, nylon 6, and nylon 4.6, polyethylene terephthalate (PET), polytrimethylene terephthalate, polybutylene terephthalate, and polyethylene na. Examples include polyester such as phthalate and fibers such as para-aramid. Further, fibers such as meta-aramid, polyethylene, polypropylene, glass, carbon, polyphenylene sulfide (PPS), LCP, polyimide, and PEEK can be used. Further, fibers such as heat fusion fibers, cotton, and wool may be applied. Among them, PPS fibers excellent in chemical resistance and hydrolysis resistance and having extremely high tensile strength are desirable. Therefore, a description will be given below, taking up a form in which the friction material 40 made of a double woven fabric is formed by the PTFE fiber 43 and the PPS fiber 47.

  In the structure of the double fabric 40, the weft 45 of the PPS fiber 47 is disposed on the upper concave 20 and the lower concave 30 side, and the warp 46 of the PPS fiber 47 is woven so as to be wound around. Above these (positions on the side of each slider 10), the weft 41 of the PTFE fiber 43 is arranged, and the warp 42 of the PTFE fiber 43 is woven so as to wind the weft 41 of the PTFE fiber 43, and the PTFE fiber 43 Is woven so that the weft 45 of the lower PPS fiber 47 is also wound. Then, the double woven fabric 40 as a friction material is fixed to the lower surface 21 of the upper concave 20 and the upper surface 31 of the lower concave 30 so that the PTFE fibers 43 are disposed on the slider 10 side. Here, as a method of fixing the double fabric 40 to the upper concave 20 and the lower concave 30, adhesion through an adhesive 49 such as an epoxy resin adhesive can be applied. Since the PPS fiber 47 has much better adhesion to the surface of the steel upper concave 20 and the lower concave 30 than the PTFE fiber 43, the friction material composed of the double fabric 40 is applied to the PTFE fiber 47, The fibers 43 are arranged on the lower surface 21 of the upper concave 20 and the upper surface 31 of the lower concave 30 so as to be located on the slider 10 side, and the PPS fibers 47 are arranged on the respective main body sides of the upper concave 20 and the lower concave 30. It is preferable to fix to the concave 20 and the lower concave 30.

  Further, since the PTFE fiber 43 has a relatively low tensile strength, the friction material made of the double woven fabric 40 is easily crushed when subjected to repeated vibrations (pressing sliding force) in a pressurized state. However, the crushed PTFE fiber 43 stays in the PPS fiber 47 having a higher tensile strength and therefore a higher crush resistance, so that at least a part of the PTFE fiber 43 is the upper surface 12 which is the second sliding surface of the slider 10. And the lower surface 13, it is possible to enjoy good slidability of the PTFE fiber 43.

  Stopper rings 22, 32 for preventing the slider 10 from falling off are fixed to the outer edges of the sliding surfaces of the lower surface 21 of the upper concave 20 and the upper surface 31 of the lower concave 30. And, as described above, in the upper concave 20 and the lower concave 30, the PTFE fiber 43 and the tensile strength higher than the PTFE fiber 43 are used instead of the stainless steel sliding plate attached in the conventional sliding seismic isolation device. A friction material 40 formed of a double fabric having fibers 47 is attached.

  As described above, in the sliding seismic isolation device 100, the stainless steel sliding plates provided on the lower surface of the upper concave and the upper surface of the lower concave in the conventional sliding seismic isolator are abolished, and the lower surface 21 of the upper concave 20 and the lower concave are removed. Since at least the friction material 40 made of PTFE is fixed on the upper surface 31 of the upper surface 30, there is no problem that rust is generated on the sliding plate and the friction coefficient of the sliding seismic isolation device 100 is increased. Also, since there is no problem of rusting of the sliding plate, the ring seal material used in the conventional sliding seismic isolation device can be eliminated. 100 manufacturing costs can be reduced.

  The friction material 40 made of PTFE at least may be a woven fabric containing PTFE fibers other than the double woven fabric, a friction material made of PTFE only, or a friction material made of a composite material of PTFE and another resin Alternatively, a friction material having a laminated structure of a friction material made of PTFE and a friction material made of another resin may be used. Then, in the friction material having a laminated structure, similarly to the case of the double fabric, the friction material made of PTFE is fixed to the upper concave 20 and the lower concave 30 so that the friction material is disposed on the slider 10 side. Is good.

On the other hand, the slider 10 has a slider body 11 having a substantially cylindrical shape, and the slider body 11 has an upper surface 12 and a lower surface 13 having the same curvature as the lower surface 21 of the upper concave 20 and the upper surface 31 of the lower concave 30. ing. Similarly to the upper concave 20 and the lower concave 30, the slider body 11 is also a rolled steel material for welding steel (SM490A, B, C, or SN490B, C, or S45C), or a stainless steel (SUS material), cast steel, or cast iron. And has a load bearing strength of about 60 N / mm ² (60 MPa).

  The metal surface is exposed on the upper surface 12 and the lower surface 13 of the slider 10. For example, when the slider body 11 is made of stainless steel, a metal surface made of a stainless steel surface is exposed on the upper surface 12 and the lower surface 13. When the slider body 11 is made of steel other than stainless steel, a stainless steel plate having a curvature may be attached to the upper and lower surfaces of the slider body 11 to form upper and lower metal surfaces. The metal surface made of a stainless steel surface is preferably a mirror-finished surface.

  As described above, since the upper surface 12 and the lower surface 13 of the slider 10 are metal surfaces made of a stainless steel surface, the rust resistance of the upper and lower surfaces of the slider 10 is improved, and the slider between the upper concave 20 and the lower concave 30 is improved. 10 smooth sliding is ensured. Furthermore, since the metal surfaces (stainless steel surface) of the upper surface 12 and the lower surface 13 of the slider 10 are constantly in contact with the lower surface 21 of the upper concave 20 and the upper surface 31 of the lower concave 30, the upper and lower metal surfaces of the slider 10 are exposed to air. There is no exposure and rust on the metal surface is suppressed.

  In the sliding seismic isolation device 100, at least the friction material 40 made of PTFE is attached to the lower surface 21 of the upper concave 20 and the upper surface 31 of the lower concave 30, but the friction material 40 comes into contact with the slider 10 that slides during an earthquake. The location changes as the slider 10 slides. Therefore, the same portion of the friction material 40 does not receive heat constantly from the slider 10, and damage to the friction material 40 due to heat transfer from the slider 10 is suppressed. In this manner, the durability of the sliding seismic isolation device 100 with high durability is formed by both the suppression of the damage of the friction material 40 due to the heat transfer from the slider 10 during the earthquake and the suppression of the rusting of the upper and lower metal surfaces of the slider 10. .

  According to the present inventors, the stainless steel sliding plate is eliminated from the upper concave 20 and the lower concave 30, and the ring seal material used in the conventional sliding seismic isolation device is eliminated, and the like, so that the conventional sliding is achieved. It has been estimated that the manufacturing cost of the sliding seismic isolation device 100 can be reduced by about 20% to 30% compared to the seismic isolation device.

[Sliding seismic isolation device according to second embodiment]
Next, an example of the sliding seismic isolation device according to the second embodiment will be described with reference to FIG. Here, FIG. 4 is a longitudinal sectional view of the sliding seismic isolation device according to the second embodiment.

  The sliding seismic isolation device 200 is made of a metal having a concave 50 having a lower surface 51 (first sliding surface) having a curvature and an upper surface 72 (second sliding surface) having the same curvature as the lower surface 51. And a cradle 60 that slidably accommodates the slider 70 of the present invention.

  The receiving table 60 has a substrate 61 and a columnar body 62 protruding upward from the substrate 61 at a center position of the substrate 61, and the substrate 61 and the columnar body 62 are integrally formed. A concave spherical surface 63 that is recessed downward is formed at the upper end of the columnar body 62. The concave 50 and the substrate 61 are both plate members having a square shape in plan view, and the concave 50, the receiving base 60, and the slider 70 are all formed of the same material as the upper concave 20 and the lower concave 30.

  The slider 70 having the lower surface 71 (convex spherical surface) having the same curvature as the concave spherical surface 63 and the upper surface 72 having the same curvature as the lower surface 51 of the concave 50 is formed on the concave spherical surface 63 of the cylindrical body 62. It is slidably housed and held on the spherical surface 63. The metal surface is exposed on the upper surface 72 of the slider 70.

  On the other hand, on the lower surface 51 of the concave 50, the friction material 40 made of a double woven fabric is placed on the lower surface of the concave 50 so that the PTFE fiber 43 is located on the slider 70 side in the same manner as in the mode of attachment to the lower surface 21 of the upper concave 20. It is fixed to 51. A stopper ring 52 is fixed to the outer edge of the lower surface 51 of the concave 50 to prevent the cylindrical body 62 that slidably accommodates the slider 70 from falling off. As in the case of the sliding seismic isolation device 100, the friction material 40 may be a friction material made of at least PTFE, and may be a woven fabric containing PTFE fibers other than the double woven fabric.

  Thus, also in the sliding seismic isolation device 200, the stainless steel sliding plate provided in the conventional sliding seismic isolation device is abolished, and at least the friction material 40 made of PTFE is fixed on the lower surface 51 of the concave 50. Thus, there is no problem that rust is generated on the sliding plate and the friction coefficient of the sliding seismic isolation device 200 is increased. Also, since there is no problem of rusting of the sliding plate, the ring seal material used in the conventional sliding seismic isolation device can be eliminated, and in conjunction with the elimination of the stainless steel sliding plate, the sliding The manufacturing cost of the seismic isolation device 200 can be reduced.

  The illustrated sliding seismic isolation device 200 has a configuration in which the concave 50 is disposed on the upper side. However, there is a cradle provided with a slider on the upper side, and the concave is disposed on the lower side. May be a sliding seismic isolation device having an upside down configuration.

  It should be noted that other embodiments in which other components are combined with the configuration and the like described in the above embodiment may be adopted, and the present invention is not limited to the configuration shown here. This can be changed without departing from the spirit of the present invention, and can be appropriately determined according to the application form.

10: Slider 11: Slider body 12: Upper surface (second sliding surface)
13: Lower surface (second sliding surface)
20: Upper concave (concave)
21: Lower surface (first sliding surface)
30: Lower concave (concave)
31: Upper surface (first sliding surface)
40: Friction material (double woven fabric)
43: PTFE fiber 47: Fiber having higher tensile strength than PTFE fiber (PPS fiber)
50: concave 51: lower surface (first sliding surface)
Reference numeral 60: cradle 61: substrate 62: cylindrical body 63: concave sphere 70: slider 71: lower surface (convex sphere)
72: Upper surface (second sliding surface)
100: Sliding seismic isolation device (double pendulum type sliding seismic isolation device)
200: Sliding seismic isolation device (Single pendulum type sliding seismic isolation device)

Claims (5)

A concave seismic isolation device having a concave having a first sliding surface and a metal slider having a second sliding surface abutting on the first sliding surface,
A friction material made of at least PTFE is fixed to the first sliding surface,
Wherein the second sliding surface Ri exposed metal surfaces der, the entire surface of said second sliding surface, characterized that you have constantly contact with the friction member, sliding isolation device. The concave includes an upper concave and a lower concave both having a first sliding surface,
2. The slider according to claim 1, wherein the slider is a double pendulum type having upper and lower second sliding surfaces abutting on the upper and lower first sliding surfaces on upper and lower surfaces thereof. 3. Sliding seismic isolation device. One said concave,
2. A single pendulum type, comprising: a cradle for holding the slider while the second sliding surface of the slider is in contact with the first sliding surface. The seismic isolation device according to the above.   The sliding seismic isolation device according to any one of claims 1 to 3, wherein the friction material is a woven fabric containing PTFE fibers.   5. The sliding seismic isolation device according to claim 1, wherein the slider is made of stainless steel, and the metal surface is a mirror-finished surface of stainless steel. 6.