JP2012117295A - Fireproof coating structure of base isolation slide bearing - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fireproof coating structure of a base isolation slide bearing, capable of securing a smooth operation of the base isolation slide bearing and surely protecting the base isolation slide bearing from a fire when a fire occurs.SOLUTION: The base isolation slide bearing disposed between the column and foundation of a building is covered with four fireproof coating materials 32a-32d to execute fireproof coating. A gap is provided between lower end faces of the fireproof coating materials 32a-32d and a slide plate 22, and the fireproof coating materials 32a-32d are prevented from being in contact with the slide plate 22 and blocking the operation of the base isolation slide bearing when an earthquake occurs. Also, a thermosensitive foaming material 33 is provided with a gap to the slide plate 22 on the lower end faces of the fireproof coating materials 32a-32d, and the base isolation slide bearing is surely protected from a fire by filling the gap between the fireproof coating materials 32a-32d and the slide plate 22 by the thermosensitive foaming material 33 foamed by the heat when a fire occurs.

Description

  The present invention relates to a fireproof covering structure for a seismic isolation sliding bearing that fireproofs a base isolation sliding support provided in a building.

  A building such as a building is provided with a seismic isolation device in order to absorb the horizontal shaking at the time of the earthquake and suppress the influence of the earthquake on the building. Conventionally, as such a seismic isolation device, it is provided between the upper structure and the lower structure of the building to support the load of the building, and the upper structure and the lower structure are relatively moved in the horizontal direction. Seismic isolation sliding bearings that are supported as possible are known.

  The seismic isolation sliding bearing includes a pedestal block fixed to the lower surface of the upper structure and a sliding plate fixed to the upper surface of the lower structure. For example, a sheet material made of a material having a low frictional resistance such as ethylene tetrafluoride resin is attached to the lower surface of the pedestal block, while the sliding plate is made of a metal plate having a low frictional resistance such as stainless steel. Has been. The pedestal block is arranged on the sliding plate with the sheet material abutting on the upper surface of the sliding plate. When an earthquake occurs, the upper structure is changed to the lower structure by the sheet material sliding on the upper surface of the sliding plate. The horizontal movement of the earthquake is absorbed by relative movement in the horizontal direction.

  Such a seismic isolation sliding bearing is provided with a fireproof covering structure in order to protect it from a fire in the event of a fire.

  2. Description of the Related Art Conventionally, as a fireproof covering structure for seismic isolation sliding bearings, a structure in which four sides of the seismic isolation sliding bearing are surrounded by a plate-like fireproof covering material fixed to an upper structure is known. In this case, a gap is provided between the lower end surface of each fireproof covering material and the sliding plate in order to smoothly perform the relative movement in the horizontal direction between the upper structure and the lower structure when an earthquake occurs. Yes. However, if a gap is provided between the lower end surface of the fireproof covering material and the sliding plate, flame or heat may enter through this gap, and the seismic isolation sliding bearing may not be protected from fire.

  Therefore, for example, in the fireproof coating structure disclosed in Patent Document 1, a blanket formed of ceramic fibers or the like is attached to the lower end surface of the fireproof coating material, and the blanket is slidably contacted with the sliding plate to close the gap.

  Also known is a structure in which a skirt-like fire-resistant gasket rubber is attached to a fire-resistant covering material, and the fire-resistant gasket rubber is slidably contacted with a sliding plate to close the gap.

JP 2008-57228 A

  However, in the structure shown in Patent Document 1, when the upper structure and the lower structure are moved relative to each other in the horizontal direction due to an earthquake, the blanket also slides on the sliding plate, and the blanket is caught on the sliding plate. This could interfere with the operation of the seismic isolation sliding bearing. In addition, the blanket may be worn away by friction with the sliding plate, and its function may be reduced.

  Similarly, even in a structure in which a skirt-shaped fire-resistant gasket rubber is attached to a fire-resistant coating material, the fire-resistant gasket rubber is caught by a sliding plate when the upper structure and the lower structure are moved relative to each other in the horizontal direction due to an earthquake. Could occur, preventing the seismic isolation sliding bearing from operating.

  On the other hand, in the conventional fireproof covering structure, the fireproof covering material is fixed to the upper structure provided with the base isolation sliding bearing using a fastening member such as a bolt. For this, it was necessary to remove the fireproof coating from the superstructure. Therefore, the inspection work becomes complicated, and in some cases, the fireproof coating material is damaged during the removal work.

  An object of the present invention is to provide a fireproof covering structure for a seismic isolation sliding bearing that can ensure a smooth operation of the seismic isolation sliding bearing and can reliably protect the seismic isolation sliding bearing from fire in the event of a fire. is there.

  Another object of the present invention is to provide a fireproof covering structure for a seismic isolation sliding bearing which can easily perform maintenance, inspection and management of the seismic isolation sliding bearing.

  The fireproof covering structure of the seismic isolation sliding bearing according to the present invention is a fireproof covering structure of the base isolation sliding bearing that covers the base isolation sliding bearing provided between the upper structure and the lower structure of the building. A fireproof covering material that covers the seismic isolation sliding bearing is attached to the upper structure, and a gap is provided between a sliding plate of the seismic isolation sliding bearing provided in the lower structure and a lower end surface of the fireproof covering material, and the fireproofing A heat-sensitive foaming material is provided on the lower end surface of the covering material with a gap with respect to the sliding plate.

  The fireproof covering structure of the seismic isolation sliding bearing according to the present invention is characterized in that the fireproof covering material is attached to the upper structure so as to be freely opened and closed.

  The fireproof covering structure of the seismic isolation sliding bearing according to the present invention is such that the fireproof covering material is provided on each of the four sides of the base isolation sliding bearing, and the two fireproof covering materials opposite to each other can be opened and closed to the upper structure. It is attached, and the other two fireproof coating materials are fixed to the superstructure.

  According to the present invention, a gap is provided between the lower end surface of the fireproof covering material that covers the seismic isolation sliding bearing attached to the upper structure and the sliding plate, and a gap is provided between the lower end surface of the fireproof covering material and the sliding plate. Since the heat-sensitive foaming material is provided in the open space, it is possible to ensure the smooth operation of the seismic isolation sliding bearing, and in the event of a fire, the heat-sensitive foaming material creates a gap between the fireproof coating material and the sliding plate. It can be buried to securely protect the seismic isolation bearing from fire.

  According to the present invention, since the fireproof covering material that covers the seismic isolation sliding bearing is attached to the upper structure so as to be freely opened and closed, the seismic isolation sliding bearing can be protected from fire by the fireproof covering material. The maintenance work, inspection, management work, etc. can be easily performed by opening the fireproof covering material.

It is a perspective view which shows the seismic isolation sliding support provided in the building. It is a longitudinal cross-sectional view of the seismic isolation sliding bearing shown in FIG. It is sectional drawing which follows the AA line in FIG. (A) is sectional drawing which shows the state before foaming of the heat-sensitive foaming material attached to the fireproof coating material, (b) is the state after foaming of the heat-sensitive foaming material attached to the fireproof coating material. It is sectional drawing shown. It is a perspective view which shows the state which opened the fireproof covering material shown in FIG.

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

  1 is provided between a pillar 13 of a building 12 such as a building and a foundation 14 of the building 12, and supports the load of the building 12 between the pillar 13 and the foundation 14. At the same time, the pillar 13 and the foundation 14 are supported so as to be relatively movable in the horizontal direction, and the building 12 has a seismic isolation function.

  As shown in FIG. 2, the pillar 13 is formed of reinforced concrete into a columnar shape having a rectangular cross section, and an upper footing 15 as an upper structure having a rectangular cross section one size larger than the pillar 13 is integrally provided at the lower end thereof. . On the other hand, the foundation 14 of the building 12 is made of reinforced concrete, and a lower footing 16 as a lower structure is integrally provided on the upper side thereof. The upper footing 15 and the lower footing 16 are disposed with a space therebetween in the vertical direction, and the seismic isolation sliding bearing 11 is disposed between the upper footing 15 and the lower footing 16.

  The structure is not limited to the structure in which the foundation 14 and the lower footing 16 are integrally formed, and a structure in which a lower footing formed of a steel plate or the like separately from the foundation 14 is fixed on the foundation 14 may be employed.

  As shown in FIGS. 2 and 3, the seismic isolation sliding bearing 11 includes a pedestal block 17. The pedestal block 17 is formed in a columnar shape with a steel material or the like, and is fixed to a lower end surface of the upper footing 15 with a fastening member such as a bolt (not shown) with its axis oriented in the vertical direction. A disc-shaped rubber sheet 18 is sandwiched between the pedestal block 17 and the upper footing 15 in order to absorb vibration generated between the column 13 and the foundation 14. A sheet material 21 is attached to the lower end surface of the pedestal block 17. The sheet material 21 is formed in a disk shape having a slightly larger diameter than the pedestal block 17 by a low friction material having a small frictional resistance such as, for example, tetrafluoroethylene resin, and the center thereof is the center of the pedestal block 17. The end face of the base block 17 is attached to the end face by means such as adhesion so as to match and cover the entire downward end face.

  The sheet material 21 is not limited to ethylene tetrafluoride resin, but may be formed of other low friction material having low friction and appropriate strength, such as fluorocarbon resin.

  On the other hand, a sliding plate 22 constituting the seismic isolation sliding bearing 11 is fixed to the upper surface of the lower footing 16. The sliding plate 22 is formed in a rectangular plate shape by a metal plate having a small frictional resistance such as a stainless steel plate, and its upper surface is polished and finished smoothly.

  The pedestal block 17 is disposed on the sliding plate 22 so that the surface of the sheet material 21 is in contact with the upper surface of the sliding plate 22. As a result, the load of the pillar 13 is supported by the foundation 14 via the seismic isolation sliding support 11 and, when an earthquake occurs, the sheet material 21 slides on the upper surface of the sliding plate 22, and the pillar 13 and the foundation 14. And the horizontal movement of the earthquake is absorbed by the seismic isolation sliding bearing 11.

  A laminated rubber bearing may be provided between the pillar 13 and the foundation 14 of the building 12 in parallel with the above-described seismic isolation sliding bearing 11.

  The seismic isolation sliding bearing 11 having such a configuration is provided with a fireproof covering structure 31 (hereinafter referred to as a fireproof covering structure 31) of the seismic isolation sliding support in order to protect it from a fire in the event of a fire.

  As shown in FIGS. 1 to 3, the fireproof covering structure 31 of the present invention has four sides (peripheries) of the seismic isolation sliding bearing 11 provided between the pillar 13 and the foundation 14 as the upper footing 15 of the pillar 13. It has a structure in which it is covered with (enclosed) with the four plate-like fireproof coating materials 32a to 32d attached. Each of the fireproof covering materials 32 a to 32 d is formed into a plate shape by a fireproof material such as a calcium silicate plate or a noncombustible material such as a noncombustible board, and is attached to four surfaces of the upper footing 15. Further, a gap is provided between the sliding plate 22 and the lower end surface facing the lower side of each of the fireproof covering materials 32a to 32d. Thereby, even if the pillar 13 and the foundation 14 move relative to each other in the horizontal direction when an earthquake occurs, the fireproof covering materials 32a to 32d are in contact with the sliding plate 22 at the lower end surfaces thereof and inhibit the operation of the seismic isolation sliding bearing 11. And the smooth operation of the seismic isolation sliding bearing 11 is ensured.

  On the other hand, since a gap is provided between the lower end surface of each of the fireproof covering materials 32a to 32d and the sliding plate 22, it is necessary to prevent a flame and heat from entering through the gap during a fire. Therefore, in the present invention, the heat-sensitive foam material 33 is provided on the lower end surface of each of the fireproof covering materials 32a to 32d.

  The heat-sensitive foam material 33 is a foam material that foams when heated to a predetermined temperature or higher by heat such as a fire, and has fire resistance. As the heat-sensitive foam material 33, for example, sodium silicate type or carbon graphite type is used.

  As shown in FIGS. 3 and 4 (a), the heat-sensitive foam material 33 is formed in a long plate shape extending from one end to the other end along the lower end surface on the lower end surface of the fireproof covering materials 32a to 32d, respectively. It is formed and attached to the lower end surfaces of the corresponding fireproof coatings 32a to 32d using fastening means such as adhesives, bolts and screws. Further, the heat-sensitive foam materials 33 attached to the respective fireproof covering materials 32a to 32d are connected to each other at the end portions in the longitudinal direction, and as a result, are formed in an annular shape surrounding the seismic isolation sliding bearing 11 as a whole. Yes. Further, the thickness of the heat-sensitive foam material 33 is formed to be thinner than the gap between the fireproof coating materials 32 a to 32 d and the sliding plate 22. That is, in the normal state (the state before foaming), a gap is provided between the heat-sensitive foam material 33 and the sliding plate 22. As a result, even if the column 13 and the foundation 14 move relative to each other in the horizontal direction when an earthquake occurs, the heat-sensitive foam material 33 does not contact the sliding plate 22 and does not hinder the operation of the seismic isolation sliding bearing 11, and The smooth operation of the tremor sliding bearing 11 is ensured.

  On the other hand, at the time of a fire, as shown in FIG.4 (b), the heat-sensitive foaming material 33 foams with the heat of a fire. When the heat-sensitive foaming material 33 is foamed, the heat-sensitive foaming material in which the gap between the lower end surface of the fireproof covering materials 32 a to 32 d and the sliding plate 22 is foamed over the entire circumference surrounding the seismic isolation sliding bearing 11. 33. That is, the seismic isolation sliding bearing 11 is completely fire-resistant coated by the gap between the four fire-resistant covering materials 32a to 32d and the sliding plate 22 being blocked by the foamed heat-sensitive foam material 33. Thereby, it is prevented that a flame, heat, etc. reach the seismic isolation sliding support 11 through the clearance between the lower end surfaces of the fireproof covering materials 32a to 32d and the sliding plate 22, and the seismic isolation sliding support 11 reliably fires. Will be protected from.

  Thus, in this invention, a clearance gap is provided between the lower end surface of the fireproof coating materials 32a-32d which are attached to the pillar 13 and cover the seismic isolation sliding bearing 11, and the sliding plate 22, and under the fireproof coating materials 32a-32d. Since the heat-sensitive foam material 33 is provided with a gap with respect to the sliding plate 22 at the end face, the seismic isolation sliding bearing 11 is also provided as the fireproof coating structure 31 covering the seismic isolation sliding bearing 11 with the fireproof coating materials 32a to 32d. 11 can be secured, and in the event of a fire, the heat-sensitive foam material 33 can be used to fill the gap between the fireproof coatings 32a to 32d and the sliding plate 22 to ensure the seismic isolation sliding bearing 11 from fire. Can be protected.

  In order to facilitate the maintenance, inspection, and management work of the seismic isolation sliding bearing 11, in the present invention, the two fireproof coatings 32a and 32b out of the fireproof coatings 32a to 32d are fixed, and the two fireproof coatings are used. The covering materials 32c and 32d are movable. In the case shown in the figure, the two fireproof coating materials 32a and 32b that are opposite to each other are fixed, and the other two fireproof coating materials 32c and 32d are movable.

  In the case shown in the figure, the two fireproof coating materials 32a and 32b that are opposite to each other are fixed, and the other two fireproof coating materials 32c and 32d are movable. It suffices that at least one of the fireproof covering materials 32a to 32d is configured to be movable, and all of them may be movable.

  The fixed fireproof covering materials 32 a and 32 b are flush with the outer surface of the corresponding upper footing 15 on the opposite sides of the base-isolated sliding bearing 11, and the lower end surface is a gap between the sliding plate 22. And is fixed to the upper footing 15 by a fastening member such as a bolt (not shown).

  On the other hand, the movable fireproof covering materials 32c and 32d are flush with the outer surface of the corresponding upper footing 15 on the opposite sides of the base-isolated sliding bearing 11, and are fixed to the fixed fireproof covering materials 32a and 32b. Adjacent to each other. The movable fireproof covering materials 32c and 32d are attached to the upper footing 15 by hinges (not shown) at the upper side portions thereof. Accordingly, the movable fireproof covering materials 32c and 32d can be opened and closed upward with respect to the seismic isolation sliding bearing 11, as shown in FIG.

  A door stop 34 is provided on the inner side of the lower end of each of the fixed fireproof covering materials 32a and 32b, and the movable fireproof covering materials 32c and 32d abut against the door stop 34 to define the closed position. It has come to be.

  In order to secure fire resistance, the hinge is formed of steel, stainless steel, or the like, and the door stop 34 is formed of non-combustible board, fireproof board, or the like.

  As described above, in the present invention, a part of the fireproof coating materials 32a to 32d are attached to the upper footing 15 as movable fireproof coating materials 32c and 32d so as to be freely opened and closed by the hinges. As shown in FIG. 5, the fireproof covering structure 31 covered with the covering materials 32a to 32d is provided with the movable fireproof covering materials 32c and 32d on the upper side, as shown in FIG. By opening the door, the maintenance / inspection / management work of the seismic isolation sliding bearing 11 can be facilitated.

  It goes without saying that the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the invention. For example, in the present embodiment, the fireproof covering structure 31 of the present invention is applied to the seismic isolation sliding bearing 11 provided between the upper footing 15 of the column 13 of the building 12 and the lower footing 16 of the foundation 14. However, it is not limited to this. For example, the fireproof covering structure 31 of the present invention may be applied to a seismic isolation sliding bearing provided between a column and a floor of a seismic isolation layer provided on an intermediate floor of the building 12.

11 Seismic isolation sliding bearing 12 Building 13 Pillar 14 Foundation 15 Upper footing (superstructure)
16 Lower footing (lower structure)
17 Pedestal block 18 Rubber sheet 21 Sheet material 22 Sliding plate 31 Fireproof covering structure 32a-32d of base-isolated sliding bearing 33 Heat-resistant foaming material 34 Per door

Claims (3)

A fireproof covering structure for a base-isolation sliding bearing that fireproofs a base-isolation sliding bearing provided between the upper structure and the lower structure of the building,
A fireproof covering material covering the seismic isolation sliding bearing is attached to the upper structure,
A gap is provided between a sliding plate of the base-isolated sliding bearing provided in the lower structure and a lower end surface of the fireproof covering material,
A fireproof covering structure for a base-isolated sliding bearing, wherein a heat-sensitive foaming material is provided at a lower end surface of the fireproof covering material with a gap with respect to the sliding plate.   The fireproof covering structure for a seismic isolation sliding bearing according to claim 1, wherein the fireproof covering material is attached to the upper structure so as to be freely opened and closed.   3. The fireproof covering structure for a base-isolated sliding bearing according to claim 1 or 2, wherein the fireproof covering material is provided on each of the four sides of the base-isolating sliding bearing, and the two fireproof covering materials opposite to each other are the upper structure. A fireproof covering structure for a base-isolated sliding bearing, wherein the other two fireproof covering materials are fixed to the upper structure.

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