JP2010270581A - Around-slide board and base-isolation slider box - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a base-isolation slider box as a construction material which has a high base isolation function against an earthquake during construction of a building and is very easily installed. <P>SOLUTION: The foundation of the building is constructed, and a leg of the building is fixed in a building-leg insertion portion 12 of the base isolation slider box installed and fixed in the foundation. The respective legs are independently suspended. Transmission of vibration to an upper building is blocked by a cushion unit 11 for reducing the vibration due to vertical motion of the earthquake and by sliding a base isolation slider plate 13 based on rotation of a number of small spherical bodies against the vibration due to lateral motion. At an upper part of the base-isolation slide box, an overlapping lid 27 formed by overlapping square ring-shaped parts for protecting the upper part, and a film structure 28 jointed with the overlapping lid 27 to keep the inside of the slide box airtight are installed. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention has a built-in around slide board that can slide in a free direction with a slider plate having small iron balls sandwiched between upper and lower perforated iron plates, and a box that adjusts the vibration caused by an earthquake to the movement of the ground. The present invention relates to the provision of a slider box that effectively absorbs vibration by sliding between the building and the ground by moving the back and forth and right and left to absorb vibration energy.

Various technologies are provided to deal with earthquake rolls by escaping roll energy with seismic isolation bearings and cushioning with pitch cushions.
Prior patents after 1993 include 270 patent documents related to seismic isolation structures, 45 patent documents related to seismic isolation buildings, 26 patent documents related to seismic isolation structures, and patent literature related to seismic isolation bearings. Three patent documents relating to flat bearings are proposed for each.
In other words, for earthquake-resistant structures, there are structural improvements for beams and eaves, utilization of dampers, utilization of rubber elasticity, utilization of rollers combined vertically and horizontally, utilization of spheres, and the like.
The present invention is a system in which an object is slid based on the rotation of a bearing, and has similarities to this, and the prior applications include the inventions shown in Patent Documents 1 to 8.

  Patent Document 1 discloses that a vertical seismic isolation device, which is an existing laminated elastic rubber-steel isolation bearing, includes a coil spring or a vertical lamination rubber-steel device, a number of steel balls, and a vertical isolation device cylinder. A device capable of three-dimensional seismic isolation against horizontal and vertical seismic loads made by combining seismic isolation devices, that is, an integrated horizontal-vertical seismic isolation bearing is provided. This does not include the smooth slider.

Patent Document 2 is a seismic isolation bearing that can move arbitrarily in the horizontal direction, can support a large load, and exhibits both a load supporting element and a restoring force element at the same time. And a plurality of bearing balls interposed in the gaps between the steel plates. The intermediate steel plate has upper and lower convex surfaces having the same curvature as the concave spherical surface sandwiched between the steel plates.
In this technique, the bearing ball is held by a retainer ring to avoid contact with the bearing ball.
Patent Document 3 is a seismic isolation bearing that moves in two horizontal and vertical directions, can support a large load and simultaneously exhibits a load supporting element and a restoring force element. The ball bearing moves along the axis.

  Patent Document 4 is provided between a sphere support plate, three rigid spheres on the sphere support plate, a sphere holding plate that maintains a space between the three spheres, and the sphere holding plate and the seismic isolation structure. And a spherical isolation joint mechanism for preventing horizontal vibration acting on the spherical support plate from being transmitted to the base isolation structure, and sharing the weight with the multiple spherical bodies of the present invention. It is not a method to hold.

In Patent Document 5 and Patent Document 6, a base isolation layer is provided between the lower structure and the upper structure of the base isolation structure, and a mega structure is provided between the lower structure and the base isolation layer.
The seismic isolation layer regulates the amount of lateral sliding of the slider with the endless track-like moving body that supports the lateral sliding freely, the damper that gives resistance to the lateral sliding of the upper structure, the mega structure, and the upper structure. It has a stopper.
The slider is basically different in use purpose and structure from the present invention.

  In Patent Document 7, a fixed platen is provided on the upper building side and the concrete foundation side on the upper and lower portions of a cylindrical body made of synthetic resin or rubber having elasticity. The cylindrical body is filled with grains, and the upper and lower ends of the rope provided in the cylindrical body are connected and fixed to the restoration body fixed to the center of the fixed platen, and sandwiched between the upper building and the concrete foundation, This is a structure in which the restoring capacity is generated in the restoring body by elasticity. In this technique, granular corps are used as cylindrical packing.

  Patent Document 8 discloses a flat bearing composed of a pair of (two) dishes that are arranged opposite to each other and that are two-dimensionally relatively movable within a predetermined movable range while keeping parallel to each other, and a sphere arranged between the dishes. This is the same idea as the present invention in that it absorbs the seismic roll vibration with a large number of flat bearings, but is not a largely moving slider of the present invention.

In Patent Document 9, a cylindrical roller is sandwiched between a lower plate and an upper plate, and a pair of sliding guides fixed to both ends of the roller are engaged with an inner wall surface of a side wall member fixed to the lower plate to provide friction damping. . Non-linear springs such as viscoelastic or viscous dampers, linear springs and hardening are provided between the lower and upper plates to provide seismic isolation bearings that reduce bearing displacement, dissipate energy, or adjust the periodic operability of bearings is doing. That is, since the cylindrical roller different from this invention is used for a slider, it differs from this application.

  In Patent Document 10, the weight of a building is supported by both the rolling bearing body and the sliding bearing body, and the sliding resistance of the sliding bearing body works as the yield strength of the entire device, and a flat rubber plate is placed between the upper and lower structures. It is a seismic isolation structure system that functions as a device that bears the restoring force of the seismic isolation layer. Although it is a structure which pinches a rolling support body between an upper and lower board, it is not the structure which forms the slide disk of this invention.

  Patent Document 11 has a structure in which a silicon rubber sphere is sandwiched between a lower plate and an upper plate, and a sphere storage portion of a recess is provided at the lower portion of the upper plate to absorb earthquake vibrations by deformation and rolling of the sphere. When there is little shaking and vibration and the relative movement between the lower plate and the upper plate is within the elastic deformation range of the sphere, the sphere is elastically deformed by the surface friction force between the lower plate and the upper plate and exhibits a damping function. . When shaking and vibration are large and the relative movement between the lower plate and the upper plate exceeds the elastic deformation range of the sphere, the sphere rolls horizontally between the lower plate and the upper plate and swings as a rolling seismic isolation body. Exhibits seismic isolation that absorbs water. However, the deformed sphere is prone to failure due to long-term deformation. Therefore, it differs from the structure of the steel slide plate and slider of the present invention.

In Patent Document 12, a bearing is sandwiched between a floor surface of a building or a base and a bridge, and a recess is formed on the bottom surface of the bridge where a part of the sphere protruding from the sphere of the bearing is in contact to prevent the ball from escaping. At the same time, we are providing a base-isolated building that is in contact with the tip of the column at the spherical surface and absorbs the vibration transmitted through the column by rotating the sphere and opening and closing the slit of the frame.
However, the bearing used here is not the largely moving slider of the present invention.

In Patent Document 13, the seismic isolation bearing is installed between the base isolation structure and the foundation. Between the two end steel plates that have a concave spherical surface on one side and are arranged symmetrically in the vertical direction, one fixed to the bottom surface of the seismic isolation structure and the other to the top surface of the foundation by anchor means etc. It is composed of a plurality of ball bearings that are arranged and interposed in the gaps between the respective term plates, and each term element is composed of a combination that is in close contact with each other in a sandwich shape.
This structure is fundamentally different from the structure of the slide board of the present invention.

Patent Document 14 is a structure in which seismic isolation bearings are arranged inside a laminated body in which rigid plates having rigidity and elastic plates having elasticity are alternately laminated in the height direction.
The application of the bearing is not the seismic isolation method using the slider of the present invention.

Patent Publication 10-37516 Integrated Horizontal-Vertical Seismic Isolation Bearing Patent Publication 11-350784 Seismic Isolation Support Patent Publication 11-351319 Seismic Isolation Support Patent Publication 2000-46107 Seismic Isolation Slide Mechanism Patent Publication 2000-345730 Base-isolated building Patent Publication 2000-345731 Base-isolated building Patent Publication 2002-266519 Restoration body for base-isolated building Patent Publication 2003-74546 Flat Bearing Patent Publication 2003-232400 Seismic Isolation Bearing Patent Publication 2003-307045 Seismic Isolation System Patent Publication 2007-162751 Seismic Isolation Device, Seismic Isolation Structure, and Seismic Isolation Method Patent Publication 2007-177601 Bearing Seismic Isolation Construction Method Patent Publication 2007-197916 Seismic Isolation Structure Patent Publication 2009-47194 Laminated Seismic Isolation Bearing

The destruction of buildings due to earthquakes is due to the vibration amplitude effect of the combined force of pitch and roll. If you look at the amplitude data of a conventional large earthquake by a seismometer, the energy of a seismic wave with a seismic intensity of 7 is about 2. The reciprocal width of the 370 gal vibration is about 45 cm.
In particular, seismic waves with a large destructive force have an amplitude in the direction of rolling without support in the air.
The seismic wave in the pitching direction pushes up the ground, and the structure and the human body are drawn downward by the acceleration of gravity. As for the distortion of the structure due to the giant seismic wave, the height difference of about 10 cm at the maximum is considered for each place, and it is important to suspend each structure leg independently and to eliminate the distortion by the cushion.
Since the load is an acceleration several times the total weight, the destructive force of distortion caused by pitching can be reduced by the strength and cushioning of the building.
Actually, this pitching and rolling occur in a complex and irregular manner, so that the destructive force is amplified and not simple. That is, it is considered necessary for safety to disassemble and cope with the moment of force in the vertical and horizontal directions along the vibration direction and to support the weight in a large area at multiple points. Furthermore, the seismic isolation device is normally stationary, and the metal part is likely to be oxidized and rusted by oxygen in the atmosphere. Antioxidation measures are important.
In the present invention, the impact of an earthquake spreads in the shape of a wave swell and is not evenly applied to each position of the building. Along with the seismic isolation method, we proposed a device that prevents rust and corrosion of metals that are left stationary for a long time.
Based on the rotation of a large number of small spheres, sliding with a large destructive roll, the ground movement width is considered to be 50 cm at maximum, and the slider box moves with the building base. The mechanism was devised so that the main body of the building would hardly shake. For the pitching of the waves that are irregular, the impact on the building from the ground is not constant depending on the location.There is a rubber cushion with a built-in steel strong spring in the building leg receptacle of the slider box. We have devised a structure that absorbs shock for each thrust force applied to a monopod by an independent suspension system. As a result, the building was designed to avoid extreme impacts, although the building sways up and down in the vertical direction.

As shown in Fig. 1, the foundation of the building is made, and the seismic isolation slider box is installed and fixed in it. When installing, it is important to measure the level so that the four sides are equal.
As shown in FIG. 2, the installed slide box is moved along the movement direction of the ground due to the shaking of the earthquake.
The figure I shows the position of the building's legs when they were stationary before the earthquake.
II shows the position where the ground has moved maximum from the right to the left due to the earthquake.
III indicates the position where the ground has moved to the maximum from the left to the right due to the earthquake, and specifically indicates that the box moves in the direction in which the ground moves.
The leg of the building is fixed to the building leg insertion part of the slider box, and each leg is independently suspended. It has a structure that does not convey to That is, since each slide box operates independently, energy is absorbed at each place in an independent suspension state against vibration.
This vibration width is assumed to be 50 cm on one side and 1 meter on both sides. That is, a distance greater than the maximum amplitude of past earthquakes of 45 cm is assumed. Moreover, since the absorption of the impact by the vertical vibration of the upper and lower sides differs depending on the place, it is reduced by the cushion of the independently constructed suspension leg insertion portion. Moreover, even in the case of a slider with a side roll of 25 cm and a total recovery of 50 cm, it is possible to reduce the shake of a large earthquake to half or less.
Therefore, in order to solve the problem, the apparatus of the present invention is composed of six types of mechanisms.
The first is the part of the around slide that moves with a slider.
The second is the part of the slider that moves by inserting the legs of the building.
The third part is a special cushion that supports the building in the slider and softens the vibration.
The fourth part is fixed so that it can run stably in the slider gas slide box.
The fifth part is an around slide board and a slide box part for storing the slider.
The sixth is a portion of a rust preventive infusion that prevents metal corrosion in the slide box.

As shown in FIG. 3, the around slide board is a stationary board in which a large number of steel spheres are densely arranged, and its function can freely move in any of the front, rear, left and right oblique directions.
FIG. 4 is a front, back, left, and right side view of the around slide board. 1 is a steel sphere, 2 is an upper slide plate covering the steel sphere from the upper surface (cover plate), 3 is an around slide plate lower surface covering plate (cover plate) wrapping the steel sphere from the lower surface, 4 is upper and lower coating The screws and screw holes for bonding the plates are shown.
FIG. 5 shows a plan view seen from above and a bottom view seen from below. The displayed symbols are the same as in FIG.
FIG. 6 is a side sectional view of the around slide board. Around slide machine, steel spheres are supplemented and held by upper and lower upper and lower cover plates (cover plates), and the spheres protrude above and below the cover plate, and are located between and directly in contact with the bottom plate of the slide box and the slider bottom plate, Transmit building weight to the bottom of the slide box.
FIG. 7 shows a dense arrangement of the steel spheres of the around slide board. 1 is a steel sphere.
FIG. 8 shows a side view of the upper surface covering plate (cover plate) of the around slide board. 5 is a top sphere protrusion of the steel sphere, and 6 is a supplementary space for the steel sphere.
FIG. 9 shows a side view of the lower surface cover plate (cover plate) of the around slide board. 7 is a bottom sphere protrusion of the steel sphere, and 8 is a supplementary space for the steel sphere.
FIG. 10 shows a side view of the upper surface covering plate (cover plate) and the lower surface covering plate (cover plate) of the around slide board. Reference numerals 5 and 7 are upper and lower sphere protrusions of the steel sphere, and 6 and 8 are supplementary spaces serving as holders for the steel sphere.
FIG. 11 is a rear view of an upper and lower surface covering plate (cover plate) serving as a spherical holder of an around slide board. Reference numerals 2 and 3 denote the outer surfaces of the upper and lower surface covering plates (cover plates).
Reference numerals 5 and 7 denote exits of windows through which the steel spheres protrude from the upper and lower surfaces of the sphere holder, and 4 denotes screws and screw holes for bonding and fixing the upper and lower cover plates of the sphere holder.

FIG. 12 shows an internal structure of a side section of a slide box used for a relatively light building such as a general house.
The devices 9 to 13 shown in the figure are slider parts, and 9 is a leg housing space for housing the legs of the upper building. 10 is a connection device with the leg of the upper building, and 12 is an insertion port for the leg of the upper building.
11 is a cushion which supports the leg part of an upper building from the bottom. The cushion is made of soft rubber, and a strong spring made of steel is built inside the rubber structure, so that it can flexibly respond to the impact of huge gravity fluctuations together with strong support force.
Reference numeral 13 denotes a slider plate. Since the sliding part of the slider supports a huge weight, it is necessary to strengthen against bending and distortion impacts, so the bottom part of the bottom is rounded upward to make smooth sliding with a thick steel plate. A rubber cushion 18 for preventing impact is attached around the side surface.
Reference numeral 14 denotes an around slide board. The structure is such that a steel sphere can move freely in any direction in all directions by loading a slider. If the maximum movement range is set to about 17 cm, the slider plate moves 34 cm above it, and even if the ground and the slider box move 51 cm, the slider plate and the slider box do not collide. In other words, even if a large earthquake occurs in which the ground moves as much as 50 cm, the effect of rolling does not occur on the superstructure.
Reference numeral 15 denotes a base portion of the slider box pan. The bottom of the slider box has a pan shape and is called bread. Since the base supports all the weight of the superstructure, it forms a hard and thick steel plate to enable smooth movement of the around slide plate, which has a strong bending force.
Reference numeral 16 denotes a side wall of the slider box pan. The side wall is provided with a damper 17 fitting for pulling the slider and the around slider from four directions, and a cushion 18 for absorbing shocks against collision with these.
Reference numeral 19 denotes an adhesive plate for attaching a slider box pan and an upper canopy portion at the periphery of the pan to which a lid portion at the top of the pan is attached.
The slider plate pan and the upper lid are brought into close contact with the mounting plate 21.
Reference numeral 20 denotes a lid side wall at the top of the pan.
Reference numeral 21 denotes a bolt screw for attaching the slider box pan and the lid on the top of the pan.
Reference numeral 22 denotes a canopy support plate for the slider box.
Reference numeral 23 denotes a fixed wheel on the upper part of the slider plate that presses and fixes the slider against the slider box pan and smoothes the left and right movement without causing rattling.
Reference numeral 24 denotes a fixed wheel rail that holds the fixed wheel from above.
Reference numeral 25 denotes a wheel that carries the fixed wheel rail back and forth, and has a function of pressing the slider plate from above.
Reference numeral 26 denotes a fixed wheel rail that holds the wheel that carries the fixed wheel rail back and forth from above.
That is, the slider can be smoothly moved back and forth and right and left without backlash by the left and right fixed wheels and the left and right rails holding the same, and the front and rear fixed wheels and the front and rear rails holding the same.
Reference numeral 27 denotes an overlapping lid that is overlapped in a ring shape that protects the upper portion against pressure from outside the canopy. The overlapping lids are meshed with each other. As the slider moves, the inner lid drags the outer lid, and the entire lid moves while covering the slider box one after another.
Reference numeral 28 denotes a membrane structure that is joined to the overlapping lid to keep the inside of the slider box airtight. If the slider box is covered only with the membrane structure, the membrane will bend inward by external pressure, so a structure that is joined to the overlapping lid and supported by the overlapping lid is adopted.
30 is an oil solution for preventing metal oxidation that fills the slider box. Since the slider box is stationary in a damp basement for a long period of time, it is easily oxidized, and the exposed metal surface in the box is covered with an oil film to prevent oxidation by oxygen in the air.

FIG. 13 shows the internal structure of the slider box as seen from above under the canopy support plate 22.
A slider 13 is arranged in the center. The slider is made of rubber, and a cushion 11 containing a strong spring made of steel is installed in the bottom of the container.
The slider has a leg housing space 9 for inserting a leg of the upper building and a leg insertion port 12, and an upper building leg connecting device 10 connected to the leg.
Reference numeral 14 denotes an around slide board on which a slider plate is placed and can freely move in all directions in the slider box.
The movement distance of the slider plate 13 in the slider box can be moved by adding the movement distance of the around slide board 14 and the double movement distance of the slider on the around slide board.
For example, when the movable distance on the around slide board is 25 cm, the movable distance of the slider plate is 25 cm on the around slide board, and the slider can move 50 cm on one side. Similarly, when the movable distance on the around slide board is 30 cm, the movable distance of the slider plate is 30 cm on the around slide board, and the slider can move 60 cm on one side.
As described above, in the case of a seismic wave with a seismic intensity of 7, the energy is about 2.370 gal and the reciprocal width of the vibration is about 45 cm. Therefore, even in the case of a large earthquake where the seismometer needle can be swung off, the one-side travel distance is 51 cm. If it is ~ 75cm, it seems that the destruction of the building can be avoided by the seismic isolation action.
On the outside of the upper building leg connecting device 10 on the slider plate 13, a fixed wheel rail 24 that moves left and right to bring the slider plate into close contact with the around slide board is installed, and the structure follows the operation of the slider before and after. It has become. The fixed wheel rail 24 that moves left and right is fixed by a fixed wheel rail 26 that moves back and forth.
The slider plate 13 and the around slide board 14 are each pulled from four sides by a damper 17.
The function of the damper is a role of a shock absorbing brake in the event that the slider swings out and contacts the slider box wall 16.
Around the slider plate 13, the around slide board 14, and the slider box wall 16, a cushion 18 for absorbing shock when contacting is installed.
Around the slider box, a rider box pan and an adhesive plate 19 for the lid at the top of the pan are disposed, and these are adhered by adhesive bolts 21.

FIG. 14 shows a plan view from the top surface of the canopy ring of the slider box.
11 is a cushion containing a strong spring made of steel inside the rubber structure, and 12 is an insertion opening of a leg portion of the superstructure.
Reference numeral 19 denotes an adhesive plate for the peripheral edge of the bread and the lid at the top of the bread.
Reference numeral 21 denotes a bolt screw for attaching the slider box pan and the lid on the top of the pan.
The symbols a, b, c, d, e, f, g, h, i, j, k, l, m, n shown in the figure are from the inside of the overlapping support ring that covers from the outside to the inside of the canopy. It is a symbol of the order to the outside.

FIG. 15 is a diagram showing a state of connection between the overlapping support ring of the upper canopy and the sealing membrane, showing an immediate cross section of the portion of FIG. 14A.
Reference numeral 19 denotes an adhesive plate for the peripheral edge of the bread and the lid at the top of the bread.
Reference numeral 20 denotes a lid side wall at the top of the pan.
Reference numeral 22 denotes a canopy support plate for the slider box.
Reference numeral 27 denotes an overlapping lid that is overlapped in a square ring shape that protects the upper portion against pressure from the outside of the canopy.
Reference numeral 28 denotes a membrane structure that is joined to the overlapping lid to keep the inside of the slider box airtight.
Nitrogen gas is replaced with air inside the membrane to prevent oxidation in the apparatus.
The membrane structure connects the ring-shaped overlapping lid outer edge and the next ring-shaped overlapping lid outer edge so as to cover the upper surface of the ring in a bowl shape, and moves and deforms along with the movement of the ring. And has the function of sealing the outer space. The sealing of the membrane prevents moisture and air from entering from the outside world and prevents corrosion of the device.

FIG. 16 is a plan view seen from above the ring-shaped overlapping lid. The thick black line on the inside is a protrusion to the top. The size of the ring overlaps by half with the adjacent ring, usually forming a double overall, but the stretched side is single supported by the movement of the slider box. The outer end of the overlapping lid protrudes downward and bends, the inner end protrudes upward and bends, and meshes with the protrusions of the inner and outer ends of the next ring. It is a structure that moves continuously.
The symbols a, b, c, d, e, f, g, h, i, j, k, l, m, and n shown in the figure are rings according to the order from the inside to the outside of the overlapping support ring of the canopy. Symbol.

FIG. 17 is an external view of the front, back, and both sides of the slider box.
10 is a connection device with the leg of the upper building, and 12 is an insertion port for the leg of the upper building. Reference numeral 15 denotes a base portion of the slider box pan, and reference numeral 16 denotes a side wall of the slider box pan.
Reference numeral 19 denotes an adhesive plate for attaching a slider box pan and an upper canopy portion at the periphery of the pan to which a lid portion at the top of the pan is attached. Reference numeral 20 denotes a lid side wall at the top of the pan.
Reference numeral 21 denotes a bolt screw for attaching the slider box pan and the lid on the top of the pan.
Reference numeral 28 denotes a membrane structure that is joined to the overlapping lid to keep the inside of the slider box airtight.

FIG. 18 is a plan external view of the slider box as viewed from above.
10 is a connection device with the leg of the upper building, and 12 is an insertion port for the leg of the upper building. Reference numeral 19 denotes an adhesive plate at the peripheral edge of the pan to which the slider box pan and the lid at the top of the pan are attached. Reference numeral 21 denotes a bolt screw for attaching the slider box pan and the lid on the top of the pan.

FIG. 19 is an external view of the bottom surface of the slider box.
Reference numeral 15 denotes a base portion of the slider box pan, and reference numeral 19 denotes an adhesive plate at the peripheral edge of the pan to which the slider box pan and a lid portion at the top of the pan are attached.
Reference numeral 21 denotes a bolt screw for attaching the slider box pan and the lid on the top of the pan.

In FIG. 20, the model of the movement deformation | transformation of the heavy building and seismic isolation slider box by an earthquake was shown with the structural drawing of the side surface cross section.
In the figure, I represents a stationary state, II represents deformation of the slider box accompanying the movement of the ground from right to left, and III represents deformation of the slider box accompanying the movement of the ground from left to right.
Arrows indicate the direction of ground movement. Even if the ground moves, the building is still.

FIG. 21 shows a structural diagram of a side cross section of a seismic isolation slider box of a heavy building.
The devices 9 to 13 shown in the figure are slider parts, and 9 is a leg housing space for housing the legs of the upper building. 10 is a connection device with the leg of the upper building, and 12 is an insertion port for the leg of the upper building.
11 is a cushion which supports the leg part of an upper building from the bottom. The cushion is made of soft rubber, and a strong spring made of steel is built inside the rubber structure, so that it can flexibly respond to the impact of huge gravity fluctuations together with strong support force.
Reference numeral 13 denotes a slider plate. Since the sliding part of the slider supports a huge weight, it is necessary to strengthen against bending and distortion impacts, so the bottom part of the bottom is rounded upward to make smooth sliding with a thick steel plate. A rubber cushion 18 for preventing impact is attached around the side surface.
Reference numeral 14 denotes an around slide board. The structure is such that a steel sphere can move freely in any direction in all directions by loading a slider. If the maximum movement range is set to about 17 cm, the slider plate moves 34 cm above it, and even if the ground and the slider box move 51 cm, the slider plate and the slider box do not collide. In other words, even if a large earthquake occurs in which the ground moves as much as 50 cm, the effect of rolling does not occur on the superstructure.
Reference numeral 15 denotes a base portion of the slider box pan. The bottom of the slider box has a pan shape and is called bread. Since the base supports all the weight of the superstructure, it forms a hard and thick steel plate to enable smooth movement of the around slide plate, which has a strong bending force.
Reference numeral 16 denotes a side wall of the slider box pan. The side wall is provided with a damper 17 fitting for pulling the slider and the around slider from four directions, and a cushion 18 for absorbing shocks against collision with these.
Reference numeral 19 denotes an adhesive plate for attaching a slider box pan and an upper canopy portion at the periphery of the pan to which a lid portion at the top of the pan is attached.
The slider plate pan and the upper lid are brought into close contact with the mounting plate 21.
Reference numeral 20 denotes a lid side wall at the top of the pan.
Reference numeral 21 denotes a bolt screw for attaching the slider box pan and the lid on the top of the pan.
Reference numeral 22 denotes a canopy support plate for the slider box.
The canopy support plate 22 of the slider box has a function of pressing the upper around slide board 14 and pressing and fixing the slider to the slider box pan 15 so that the slider can move smoothly from side to side without causing rattling.
Reference numeral 28 denotes a membrane structure that is joined to the overlapping lid to keep the inside of the slider box airtight. If the slider box is covered only with the membrane structure, the membrane will bend inward by external pressure, so a structure that is joined to the overlapping lid and supported by the overlapping lid is adopted.
29 is a leg room movement space between heavy building seismic isolation slider box canopy plates.
30 is an oil solution for preventing metal oxidation that fills the slider box. Since the slider box is stationary in a damp basement for a long period of time, it is easily oxidized, and the exposed metal surface in the box is covered with an oil film to fill nitrogen and prevent rust due to oxidation of oxygen.

FIG. 22 shows a side cross-sectional view of the seismic isolation slider box canopy of a heavy building.
A damper 17 pulls the around slider from four sides of the side wall.
Reference numeral 19 denotes an adhesive plate for the upper canopy portion at the periphery of the pan, to which the slider box pan and the lid portion at the top of the pan are attached. Reference numeral 21 denotes a bolt screw for attaching the slider box pan and the lid on the top of the pan. Reference numeral 22 denotes a canopy support plate for the slider box.
Reference numeral 27 denotes an overlapping lid that is overlapped in a square ring shape that protects the upper portion against pressure from the outside of the canopy. Reference numeral 28 denotes a membrane structure that is joined to the overlapping lid to keep the inside of the slider box airtight. 29 is a leg room movement space between heavy building seismic isolation slider box canopy plates.

FIG. 23 is a side sectional view of the heavy building slider.
Reference numeral 9 denotes a leg accommodating space for accommodating the leg of the upper building. 10 is a connection device with the leg of the upper building, and 12 is an insertion port for the leg of the upper building.
11 is a cushion which supports the leg part of an upper building from the bottom. The cushion is made of soft rubber, and a strong spring made of steel is built inside the rubber structure, so that it can flexibly respond to the impact of huge gravity fluctuations together with strong support force. Reference numeral 13 denotes a slider plate. Reference numeral 14 denotes a bottom-around slide board that slides with a slider plate placed thereon and an upper-around slide board that slides by pressing the slider plate against the bottom-around slide board.
Reference numeral 18 denotes an impact absorbing cushion against collision / contact between the around slide disk and the side wall.

FIG. 24 is a side sectional view of a heavy building slider box pan.
Reference numeral 15 denotes a base portion of the slider box pan.
Reference numeral 17 denotes a damper that pulls the slider plate and the around slide disk from four sides of the side wall. Reference numeral 18 denotes a shock absorbing cushion against a collision between the slider plate and the around slide disk and the side wall. Reference numeral 19 denotes an adhesive plate between the slider box pan and the upper canopy portion at the periphery of the pan for attaching the lid portion to the upper portion of the pan.

FIG. 25 is a side view of the upper around slide disc.
FIG. 26 is a plan view and a bottom view of the upper around slide disc.
Reference numeral 1 denotes a steel sphere, and 2 denotes an upper surface covering plate of the upper around slide board. Reference numeral 3 denotes a lower surface covering plate of the upper around slide board. Reference numeral 5 denotes an upper-around slide board upper surface covering plate sphere specification 13 exposure hole, and reference numeral 7 denotes an upper around slide disk lower surface coating plate sphere exposure hole. Reference numeral 18 denotes cushions on the outer and inner sides of the slide plate for alleviating the impact of the collision contact with the slider and the box accompanying the movement of the upper around slide plate.
29 is a leg room moving space between slider box canopy plates.

FIG. 27 is a side view of the bottom-around slide board.
FIG. 28 is a plan view and a bottom view of the bottom-around slide board.
Reference numeral 1 is a steel sphere, and 2 is a top cover plate of a bottom-around slide board. 3 is a lower surface covering plate of the bottom-around slide board. Reference numeral 5 denotes a bottom surface surrounding slide board upper surface covering plate sphere exposure hole, and reference numeral 7 denotes a bottom surface surrounding slide plate lower surface covering plate sphere exposure hole. Reference numeral 18 denotes cushions on the outer and inner sides of the slide plate for relaxing the collision contact with the box accompanying the movement of the upper around slide plate. 29 is a leg room moving space between slider box canopy plates.

The present invention provides a seismic isolation slide box as a construction material that has a high seismic isolation function during construction of a building and is extremely easy to install.
When an earthquake is a seismic wave with a seismic intensity of 7, the energy is about 2.370 gal, and according to the touch of the seismometer, the reciprocal width of the vibration is about 45 cm. The destructive power of rolling is particularly great.
Therefore, in the case of a large earthquake where the needle of the seismometer can be swung off, even if the ground movement distance due to shaking is instantaneously close to 50 cm, the sliding function of the seismic isolation slide box is 50 cm to 60 cm only on one side. If it exists, it is thought that the building will remain stationary and will not be destroyed by seismic isolation. In this proposal, it is possible to secure a moving width of 1 m or more for the entire amplitude.
This device is installed as a building base part on the grounding surface of the building. Even if the ground movement is 50 to 60 cm, the building is stationary only by moving the seismic isolation slide box. The structure is extremely effective in seismic isolation.
In general, the installation location of the seismic isolation device is at a low position in the building and is left in a long-term installation state. Therefore, in conventional devices due to moisture, submersion, etc., there is a high risk of the metal fittings being rusted.
Even if this device is installed in such a place, the seismic isolation part is sealed, and the metal part is immersed in the rust-preventive oil solution, replacing it with nitrogen gas. The structure does not rust.

Installation position diagram of the seismic isolation slider box in the building Operation diagram of the seismic isolation slider box Around slide board overhead view Around slide board front view, rear view, both side views Around slide board top view, back view Around slide panel cross section Around slide board sphere arrangement diagram Cross section of the upper slide plate Cross section of lower slide plate Around slide board top and bottom plate joint cross section Around slide board top and bottom plate Side cross section of seismic isolation slider box for general buildings Inside view of seismic isolation slider box for general buildings Ring cover layout of seismic isolation slider box canopy for general buildings Seismic isolation slider box canopy side sectional view Ring cover top view of seismic isolation slider box canopy Front, back and back views of the seismic isolation slider box Top view of the seismic isolation slider box Bottom view of seismic isolation slider box Side sectional view of response to shaking of a seismic isolation slider box for heavy buildings Side sectional view of the seismic isolation slider box for heavy buildings Side cross-sectional exploded view of the ceiling lid of a seismic isolation slider box for heavy buildings Heavy duty building seismic isolation slider box building loading slider side section exploded view Side cross-sectional exploded view of the bottom weight receiving pan of the seismic isolation slider box for heavy buildings Cross-sectional side view of the top slide board of the seismic isolation slider box Top view slide plan of the seismic isolation slider box for heavy buildings Cross section of bottom slide board of seismic isolation slider box for heavy building Bottom slide plan view of the seismic isolation slider box for heavy buildings

A Construction ground B Construction base C Seismic isolation slide box D Construction part grounding leg I Normal position of the seismic isolation slide box II Position of the seismic isolation slide box accompanying the movement of the ground from right to left by the earthquake III From the left by the earthquake Position of the seismic isolation slide box as the ground moves to the right 1 Around slide board roller sphere 2 Around slide board top cover plate 3 Around slide board bottom cover plate 4 Around slide board top and bottom cover plate adhesive screw holes and screws 5 Around slide Panel top cover plate spherical exposure hole 6 Around slide plate top cover plate roller ball holder space 7 Around slide plate bottom cover plate spherical exposure hole 8 Around slide plate bottom cover plate roller ball holder space 9 Inserting the building leg of the seismic isolation slider box Room 10 Construction of seismic isolation slider box Leg room connecting device 11 Seismic isolation slider box building leg cushioning device 12 Seismic isolation slider box building leg insertion port 13 Seismic isolation slider plate 14 Seismic isolation slider box around slide plate 15 Seismic isolation slider box pan bottom plate 16 Seismic Isolation Slider Box Pan Side Wall 17 Seismic Isolation Slider Box Damper Device 18 Contact Cushion 19 for Seismic Isolation Slider Box and Around Slide Board 19 Seismic Isolation Slider Box Pan and Seismic Isolation Slider Box Canopy Combined Device 20 Seismic Isolation Slider Box Canopy Sidewall 21 Seismic isolation slider box pan and seismic isolation slider box canopy coupling screw 22 Seismic isolation slider box canopy support plate 23 Slide wheel 24 that moves to the left and right of the upper side of the seismic isolation slider 24 Slide beam device 25 that restrains the id wheel Slide wheel 26 that moves back and forth of the upper slide beam device of the seismic isolation slider Rail device 27 that restrains the upper slide beam device wheel of the seismic isolation slider Ring lid 28 of the seismic isolation slider box canopy Membrane that covers the ring lid Bellows device 29 Heavy-duty seismic isolation slider box Leg room moving space 30 between canopy plates Metal rust prevention oil inside seismic isolation slider box <Slide lid symbol>
a, b, c, d, e, f, g, h, i, j, k, l, m, n
Cover symbol from the inside to the outside of the covering annular overlapping slide cover on the slide box ceiling

Claims (3)

It consists of two hard metal plates, such as steel, and a metal ball that has a hole that creates a slightly larger spherical space than the sphere that encloses it. The four corners of the two adjacent plates are screwed together. The slide board is shaped so that the top and bottom of the rotatable sphere stick out from the two plates, and the sphere is in contact with other flat plates such as an iron plate. The board is free to move in all directions. Around slide machine characterized by being able to slide in A building leg receptacle for receiving a building installation leg at the top;
A slider movable leg device having a thick iron plate at the bottom for uniformly distributing and transmitting the weight of the building downward through a rubber cushion incorporating a steel strong spring in the building leg receiver,
Around slide board movable device having a large number of metal balls with strong pressure resistance that can slide freely in all directions under the movable leg device;
A slider movable leg device storage container having a thick iron plate on the bottom for freely moving the movable leg device and the around slide board movable device within a certain range;
In order to move the movable leg device and the movable leg device storage container in close contact with each other, a fixed container having a movable leg passage space in the upper part and having a movable leg passage space in the upper part containing a movable beam bonded to the movable leg and moving,
A damper device for pulling the slider movable leg device and the around slide board movable device from the four sides of the movable leg device storage container, and
A cushioning device that softens the collision between the slider movable leg device and the around slide board movable device and the movable leg device storage container side wall;
A sliding ring-shaped overlapping lid device that forms a moving ceiling and can withstand pressure from the outside, and a cover with a durable coating film that prevents the entry of water and dust from the outside to the top of the interlocking ring-shaped overlapping lid device Equipment,
It consists of oil or liquid of metal preservative filled in the movable leg device containment vessel,
Energy is lost by the left and right vertical movement of the movable leg device containment vessel against vibrations such as earthquakes,
A seismic isolation slider box for a general building having a sliding distance of 25 cm or more on one side and 50 cm or more on both sides. A building leg receptacle that inserts the building foundation at the top;
A movable leg device of a slider having a thick iron plate at the bottom for uniformly distributing and transferring the weight of the building downward through a rubber cushion with a built-in steel strong spring in the building leg receiver, and a movable leg device Around slide board movable device having a large number of pressure-resistant metal balls that can slide freely in all directions under,
A movable leg device storage container having a thick iron plate having a larger area than the movable leg device at the bottom in order to freely move the movable leg device and the around slide board movable device within a certain range;
The movable leg apparatus and the movable leg apparatus storage container are moved in close contact with each other. The movable leg apparatus is inserted into the upper part of the iron plate so that the base is wider than the movable leg apparatus. Around the center opening around the movable platen for stable fixation,
An upper fixed container having a ceiling that holds down the movable slider around the center opening from above, a damper device that pulls the slider movable leg device and the around slide disk movable device from each side of the movable leg device storage container, and
A cushioning device that softens the collision between the slider movable leg device and the around slide board movable device and the movable leg device storage container side wall;
A sliding ring-shaped overlapping lid device that forms a moving ceiling and can withstand pressure from the outside, and a cover with a durable coating film that prevents the entry of water and dust from the outside to the top of the interlocking ring-shaped overlapping lid device Equipment,
It consists of oil or liquid of metal preservative filled in the movable leg device containment vessel,
Energy is lost by the left and right vertical movement of the movable leg device containment vessel against vibration such as earthquakes,
A seismic isolation slider box for heavy buildings, having a sliding distance of 50 cm or more on one side and 100 cm or more on both sides.