JP5705183B2 - Base-isolated floor structure - Google Patents

Description

  The present invention relates to a base-isolated floor structure that is used for a floor structure such as a free access floor and performs a base-isolating operation against vibrations and displacement of a building caused by an earthquake or the like.

  As a conventional base-isolated floor structure, as shown in FIG. 17, there is a base-isolated floor structure 2 in which a flat base floor surface 3 is formed on a concrete slab and is arranged on the base floor surface 3. In this seismic isolation floor structure 2, since the ball bearing 10 is provided so as to be horizontally movable with respect to the foundation floor surface 3, horizontal vibration and displacement of the building caused by an earthquake or the like are generated on the ball bearing 10. It is possible to prevent transmission directly to the frame 6 fixed to the frame 6, the support leg 18 disposed above the frame 6, a floor board (not shown), or the like (see Patent Document 1).

  As shown in FIG. 18, the conventional base-isolated floor structure 2 includes a plurality of frames 6 and 8 each formed of a rectangular tube-like pipe, which are combined vertically and horizontally and welded in the vicinity of their contact portions. By joining, a lattice-like frame was formed.

  The frames 6 were arranged in parallel with each other at intervals in the width direction (vertical direction in the figure) so that their length directions (left and right direction in FIG. 18) were substantially parallel to each other. . The frames 8 are provided between the frames 6 so that the length direction of the frames 8 extends in a direction perpendicular to the length direction of the frames 6, and a plurality of the frames 8 are arranged side by side in the length direction of the frames 6. It was.

  A ball bearing 10 (see FIG. 17) was provided at each position where the frame 8 was joined to both sides of the frame 6 (the position where the nut 14 was provided in FIG. 18). The ball bearing 10 is inserted through a through hole 6 c formed in the lower plate portion 6 b of the frame 6, and is disposed below the upper plate portion 6 a of the frame 6.

  The ball bearing 10 has a male screw portion 10a protruding upward from its upper end, and this male screw portion 10a is screwed into the female screw portion of a set screw 16 having a female screw portion formed on the axial line portion of its lower end portion. It was done. A male screw portion is formed on the outer periphery of the set screw 16, and a lower end portion of the set screw 16 is screwed into a nut 12 fixed to the lower surface of the upper plate portion 6 a of the frame 6 by welding.

  The set screw 16 is fixed so that the ball bearing 10 is accommodated in the substantial inside of the frame 6 by fastening a nut 14 to a male screw portion above the upper surface of the upper plate portion 6 a of the frame 6.

  A slit 16 a is formed at the upper end of the set screw 16. In the conventional base-isolated floor structure 2 described above, the height of the ball bearing 10 can be changed by loosening the nut 14 and rotating the set screw 16 using a screwdriver placed in the slot 16a.

  Further, the conventional seismic isolation floor structure 2 is configured such that the ball body 10b of the ball bearing 10 contacts the foundation floor surface 3 and rolls, so that the frame 6 holding the ball bearing 10 is the foundation floor surface 3. I was able to move freely in any horizontal direction.

  In addition, a damper or a coil spring (not shown) is attached to the square part of the frame body composed of the frames 6 and 8, so that the frame body is horizontally formed by the vibration or displacement of the building due to an earthquake or the like. Even if it moved relatively, the damper and the coil spring exerted restoring force, and the frame body could be returned to the original position with respect to the building.

JP 10-317658 A

  However, since the conventional seismic isolation floor structure 2 has a structure in which a large through hole 6c for attaching the ball bearing 10 to the lower plate portion 6b is formed below the upper plate portion 6a of the frame 6, the through hole There is a problem in that the strength of the frame 6 is reduced by the amount 6c is formed, and the support strength of the base isolation floor structure 2 is reduced.

  Further, if the ball bearing 10 is provided below the lower plate portion 6b without forming the through hole 6c in the lower plate portion 6b of the frame 6, the height dimension of the seismic isolation floor structure 2 is increased. There was a problem. And if the height dimension of the seismic isolation floor structure 2 becomes large, the height dimension from the basic floor surface 3 of the floor surface of the free access floor arrange | positioned on the base isolation floor structure 2 will become large correspondingly. There was also a problem.

  Therefore, in view of the above problems, the present invention provides a base-isolated floor structure capable of preventing the support strength of the base-isolated floor structure from being lowered and preventing the height dimension from increasing. The issue is to provide.

In order to solve the above problems, the seismic isolation floor structure according to the present invention is:
In the seismic isolation floor structure having a base isolation frame having a plurality of frames and a plurality of base isolation support parts for supporting the base isolation frame,
The seismic isolation support portion includes a connecting member that connects the ends of the pair of frames arranged opposite to each other, and a base isolation leg portion placed on the foundation floor surface,
The connecting member has a flat plate portion between the flat plate portion whose lower surface of the end portion of the frame is fixed in contact with the upper surface and the end portions of the pair of frames arranged opposite to each other . It has a raised plate part formed so as to rise above the upper surface ,
The upper surface of the raised plate portion is formed below the upper surface of the frame,
The seismic isolation leg portion is arranged below the raised plate portion.

Moreover, the seismic isolation floor structure according to the present invention is:
The seismic isolation leg includes a ball bearing placed on a foundation floor, and a support mechanism arranged above the ball bearing and connected to the connecting member,
The ball bearing is in contact with the support mechanism in a tiltable manner.

Moreover, the seismic isolation floor structure according to the present invention is:
The support mechanism includes a plate-like member disposed below the raised plate portion, and a support bar member fixed to the plate-like member and having a lower end protruding downward from the plate-like member. It is characterized by.

According to such a base-isolated floor structure of the present invention,
In the seismic isolation floor structure having a base isolation frame having a plurality of frames and a plurality of base isolation support parts for supporting the base isolation frame,
The seismic isolation support portion includes a connecting member that connects the ends of the pair of frames arranged opposite to each other, and a base isolation leg portion placed on the foundation floor surface,
The connecting member has a raised plate portion formed so as to rise upward between the ends of the pair of frames arranged opposite to each other.
The seismic isolation leg is disposed below the raised plate part,
It is possible to prevent the support strength of the base isolation floor structure from being lowered and to prevent the height dimension of the base isolation floor structure from increasing.

It is a partially broken side view which shows the seismic isolation floor structure 40 which concerns on the 1st Embodiment of this invention. FIG. 13 is a top view of a wide range of the base isolation floor structures 40, 80 showing a plurality of base isolation supports 44, 82 by reducing the base isolation floor structures 40, 80 shown in FIGS. It is a partial top view of the periphery of the connecting member 52 of the seismic isolation floor structures 40 and 80 shown in FIGS. FIG. 4 is a top view of only the connecting member 52 shown in FIG. 3. It is a side view of the connection member 52 shown in FIG. It is a side view which shows the seismic isolation leg part remove | excluding the connection member 52 from the seismic isolation support part. It is a side view which shows the state which fixed the plate-shaped member 54 and the support bar member 56 mutually. FIG. 8 is a partially sectional bottom view of the plate-like member 54 and the support bar member 56 shown in FIG. 7. It is a figure which shows the ball bearing 60, Comprising: It is BB arrow sectional drawing of the ball bearing 60 shown in FIG. FIG. 10 is a top view of the ball bearing 60 shown in FIG. 9. It is a figure which shows the base isolation leg part which remove | excluding the connection member 52 from the base isolation support part 44 similarly to FIG. 6, Comprising: It is a side view which shows the state which mounted the ball bearing 60 on the inclined foundation floor surface 41. . It is a partially broken side view which shows the base isolation floor structure 80 which concerns on the 2nd Embodiment of this invention. It is a side view which shows the seismic isolation leg part which removed the connection member 52 from the seismic isolation support part. FIG. 7 is a view showing a state in which a support bar member 86 and a first round bar member 88 are fixed to a first plate member 84 and a second round bar member 92 is fixed under a second plate member 90; FIG. 14 is a side view showing a part of the diagram shown in FIG. 13 rotated 90 degrees in a horizontal plane. FIG. 15 is a partial cross-sectional top view of the first plate member 84, the support bar member 86, the first round bar member 88, the second plate member 90, and the second round bar member 92 shown in FIG. It is a figure which shows the base isolation leg part which removed the connection member 52 from the base isolation support part 82 similarly to FIG. 13, Comprising: It is a side view which shows the state which mounted the ball bearing 60 on the inclined foundation floor surface 41. . It is a figure which shows the conventional base isolation floor structure 2, Comprising: It is AA arrow sectional drawing of the base isolation floor structure 2 shown in FIG. It is a top view of the seismic isolation floor structure 2 shown in FIG.

  EMBODIMENT OF THE INVENTION Hereinafter, the form for implementing the seismic isolation floor structure which concerns on this invention is demonstrated concretely based on drawing.

  FIGS. 1 to 11 are views referred to for explaining the seismic isolation floor structure 40 according to the first embodiment of the present invention.

  The base isolation frame 42 of the base isolation floor structure 40 according to the present embodiment includes a frame 46, a cover 48, and a connecting frame 50 as shown in FIG. 2, and as shown in FIG. It arrange | positions at intervals from the base floor surface 41 upwards.

  As shown in FIG. 1, the seismic isolation floor structure 40 includes a seismic isolation support portion 44. The seismic isolation support portion 44 mainly constitutes a connecting member 52, a ball bearing 60, a bolt 58, and a support mechanism. A plurality of plate-like members 54 and support bar members 56 are arranged on the foundation floor surface 41 to support the seismic isolation frame 42 from below.

  Here, the other components excluding the connecting member 52 from the seismic isolation support portion 44, that is, the plate member 54, the support bar member 56, the bolt 58, and the ball bearing 60 are collectively referred to as a seismic isolation leg portion.

  As shown in FIG. 2, the seismic isolation frame 42 has a plurality of frames 46 arranged in series in the length direction (left and right direction in the figure) and arranged in parallel in the substantially parallel direction. It arrange | positions at intervals in the length direction and the width direction (up-down direction in a figure).

  The frame 46 shown in FIG. 3 is formed in the shape of a square cylinder having a hollow portion 46a therein, and the two frames 46 adjacent to each other in the length direction of the frame 46 have a cover 48 and a connecting member 52 at their respective open ends. Are sandwiched between the flat plate portions 52a from above and below, and the opening end portions of each other are arranged to face each other and connected to each other.

  The cover 48 has a cross-sectional shape (not shown) formed in a U shape with an opening below the base floor surface 41, and as shown in FIGS. It arrange | positions so that the three outer surfaces of the upper and both sides of each opening end part which the two frames 46 which oppose may mutually overlap may be covered.

  The connecting frame 50 extends between the side portions of the plurality of covers 48 that extend in the left-right direction in FIG. 2 and are arranged in parallel to each other, with the length direction extending in a direction substantially perpendicular to the length direction of the frame 46. Has been.

  And the connection frame 50 is formed in the square cylinder shape which has the hollow part 50a, and as shown in FIG. 3, each edge part of the two connection frames 50 mutually adjacent in the length direction is a connection member. 52 is fixed on the flat plate portion 52a, and the opening end portions thereof are arranged to face each other across the cover 48 in the length direction.

  As shown in FIG. 4, the connecting member 52 has four sides that are formed between the notches 52 d adjacent to each other, with cutouts 52 d formed at the four corners of the flat plate 52 a having a substantially square outer shape. The plate-like portion extending further outward in the vertical and horizontal directions is formed in a bent plate portion 52e (see FIG. 5) that is bent substantially perpendicularly toward the back side of the drawing.

  A total of twelve screw holes 52c (see FIG. 4) are formed in the flat plate portion 52a of the connecting member 52 along each of the four sides.

  In the central portion of the flat plate portion 52a of the connecting member 52, two long holes 52f that are separated from each other in the vertical direction and have a length in the horizontal direction in the drawing are formed in parallel with each other. Yes. Then, the portion sandwiched between the two long holes 52f of the flat plate portion 52a rises above the flat plate portion 52a (to the front side in FIG. 4) by a press or the like, and has two slopes as shown in FIG. A raised plate portion 52h having an upper surface 52i substantially parallel to the portion 52g and the upper surface 52b of the flat plate portion 52a is formed.

  As shown in FIG. 4, the rising plate portion 52h at the center of the connecting member 52 is formed with a through hole 52j penetrating in the thickness direction, and four positions surrounding the through hole 52j. A through hole 52k is formed in the.

  As shown in FIG. 1, a through hole 46 b is formed in the frame 46 so as to penetrate each of the upper plate portion and the lower plate portion in the vicinity of the opening end. Further, at both ends of the cover 48, when the three outer surfaces of the open end portions of the pair of frames 46 are covered, the through holes 48a are positioned so as to overlap the upper through holes 46b of the frame 46 in the drawing. Is formed.

  In the frame 46 and the cover 48, the male screw portion of the bolt 47 is inserted through the through holes 46 b and 48 a (see FIG. 3), and the tip of the male screw portion is inserted into the screw hole 52 c (see FIG. 4) of the connecting member 52. By being fastened with screws, it is fixed to the flat plate portion 52 a of the connecting member 52. The connecting frame 50 is also fixed to the flat plate portion 52a of the connecting member 52 in substantially the same manner.

  As shown in FIGS. 1 and 3, a male screw portion 56a at the upper end portion of a support rod member 56, which will be described later, is inserted from a lower side in FIG. 1 into a through hole 52j of a rising plate portion 52h (see FIG. 4). After that, the nut 62 is screwed to the male screw portion 56a. Since the support rod member 56 is integrally fixed to the plate-like member 54 as will be described later, the rising plate portion 52h (see FIG. 5) The support bar member 56 is fixed to the rising plate portion 52h by bringing the upper surface 54a of the plate-like member 54 into contact with the lower surface 52m and fastening with the screws.

  As shown in FIG. 8, the outer shape of the plate-like member 54 is formed in a substantially square shape, and through holes 54c are formed near the four corners. The through hole 54c is formed at a position that is coaxial with the through hole 52k (see FIG. 4) of the connecting member 52 when the plate-like member 54 is superimposed on the raised plate portion 52h from below. The diameter is smaller than that of the through hole 52k.

  As shown in FIG. 7, the plate-like member 54 has a corner between the upper surface 54 a and the outer peripheral surface of the support bar member 56 by inserting the support bar member 56 through a through hole 54 d formed at the center thereof. Are integrally formed with the support bar member 56.

  The support rod member 56 has a male screw portion 56a formed on the outer periphery of a portion protruding upward from the upper surface 54a of the plate-like member 54 in FIG. In addition, a convex spherical surface portion 56 c is formed at the tip end portion of the columnar protruding portion 56 b that protrudes downward from the lower surface 54 b of the plate-like member 54 of the support bar member 56.

  In FIG. 6, the convex spherical portion 56 c at the tip of the protruding portion 56 b at the lower end of the support bar member 56 is in contact with the upper surface 74 a of the ball guide 74 of the ball bearing 60.

  The male screw portion 58 a of the bolt 58 is inserted into the through hole 54 c from the upper surface 54 a side of the plate-like member 54, and the tip portion protruding downward of the plate-like member 54 is the upper surface of the ball guide 74 of the ball bearing 60. Screwed to four internal thread portions 74c formed in 74a as shown in FIG. 10 and fixed to the ball bearing 60.

  The plate-like member 54 is configured such that the lower surface of the head of the bolt 58 is engaged with or detached from the upper surface 54a of the plate-like member 54 in accordance with a change in the distance from the foundation floor 41. Are loosely connected to the ball bearing 60 with play.

  That is, as shown in FIG. 6, when the distance between the base floor 41 and the lower surface 54b of the plate-like member 54 is shortened and the head lower surface of the bolt 58 and the upper surface 54a of the plate-like member 54 are separated, The bearing 60 is not engaged (separated) with the plate member 54 via the bolt 58.

  On the other hand, when the space between the foundation floor 41 or the ball bearing 60 and the lower surface 54b of the plate-like member 54 is widened so that the lower surface of the head of the bolt 58 and the upper surface 54a of the plate-like member 54 come into contact, the ball bearing 60 It will be in the state engaged with the plate-shaped member 54 via the volt | bolt 58. FIG.

  Therefore, the bolt 58 is normally spaced from the upper surface 54 a of the plate-like member 54 when the tip of the male screw portion 58 a is screwed to the female screw portion 74 c of the ball guide 74. Although the length is such that it faces each other, the height of a part of the foundation floor 41 is lower than the other part of the foundation floor 41, so that the height of the ball guide 74 of the ball bearing 60 is increased. Is lowered from the other ball bearing 60, the lower surface of the head of the bolt 58 comes into contact with the upper surface 54a of the plate member 54, and the ball guide 74 and the plate member 54 are in the most separated state.

  By the way, the head portion of the bolt 58 is in a state in which the male screw portion 58a is inserted into the through hole 54c of the plate-like member 54, as shown in FIG. 1, the rising plate portion 52h of the connecting member 52 (see FIGS. 4 and 5). ) Is inserted into the through hole 52k from below and assembled.

  When the ball bearing 60 and the bolt 58 are rotated by a predetermined angle with respect to the support rod member 56 depending on the state of the foundation floor surface 41, the head of the bolt 58 is prevented from contacting the inner peripheral surface of the through hole 52k. The through hole 52k (see FIGS. 4 and 5) of the ascending plate portion 52h is formed to have a diameter larger than the diameter of the head of the bolt 58.

  Similarly to the through hole 52k of the raised plate portion 52h, when the ball bearing 60 and the bolt 58 are rotated by a predetermined angle with respect to the support bar member 56 depending on the state of the foundation floor surface 41, the male screw portion 58a of the bolt 58. The through hole 54c of the plate-like member 54 is formed to have a larger diameter than the diameter of the male threaded portion 58a of the bolt 58 so that the inner diameter of the through hole 54c does not contact the inner peripheral surface of the through hole 54c.

  The plate-like member 54 and the ball bearing 60 are engaged or disengaged from each other via the bolts 58 as described above. Therefore, the upper surface 74a of the ball bearing 60 is allowed to rotate to a predetermined angle with respect to the substantially stationary support rod member 56.

  Further, since the lower surface of the head of the bolt 58 is engaged with or detached from the upper surface 54 a of the plate-like member 54, the lower surface of the head of the bolt 58 is engaged with the upper surface 54 a of the plate-like member 54. Except at times, the bolt 58 can freely move up and down in the axial direction with respect to the plate-like member 54.

  Therefore, an inclined surface is formed on the foundation floor surface 41 on which an arbitrary seismic isolation support portion 44 is placed among the plurality of seismic isolation support portions 44 that support the seismic isolation frame 42 in FIG. When the height position is lower than the foundation floor surface 41 on which the seismic isolation support portion 44 is placed, the bolt 58 moves downward with respect to the plate-like member 54, and the support bar member 56 is moved. The ball bearing 60 is rotated, or the height of the ball bearing 60 is lowered so that the upper surface 74a of the ball bearing 60 is spaced from the lower surface 54b of the plate-like member 54. Uniform contact is possible.

  As shown in FIG. 9, the ball bearing 60 includes a large number of ball bodies 70, a ball seat 72, and a ball guide 74. The ball bearing 60 can guide the ball body 70 to circulate and roll through the gap S formed between the ball seat 72 and the ball guide 74.

  The ball seat 72 is formed in a disc shape having a convex spherical surface portion 72b on its outer peripheral portion, and a cylindrical portion 72a protruding upward in the figure is integrally formed at the upper center portion thereof. The cylindrical portion 72a has a smaller outer diameter than the convex spherical portion 72b, and four female screw portions 72e are formed on the upper surface 72c.

  The ball guide 74 is formed in a substantially cylindrical shape, and a concave spherical surface portion 74e corresponding to the convex spherical surface portion 72b of the ball sheet 72 is formed inside thereof. An opening of a concave spherical surface portion 74e is formed on the bottom surface 74b of the ball guide 74, and a step recess 74g that is recessed upward in FIG. 9 is formed above the opening.

  Then, four counterbore holes 74d penetrating from the upper surface 74a to the ceiling surface of the stepped recess 74g are formed at the center of the upper surface 74a of the ball guide 74.

  The cylindrical portion 72a of the ball seat 72 is fitted to the inner side in the horizontal direction of the step concave portion 74g of the ball guide 74, and the male screw portion 76a of the countersunk screw 76 is inserted into the center portion of the counterbore hole 74d of the ball guide 74, The ball guide 74 is fixed to the ball sheet 72 by fastening the portion to the female screw portion 72 e of the ball sheet 72.

  At this time, between the concave spherical surface portion 74e of the ball guide 74 and the convex spherical surface portion 72b of the ball seat 72, a curved gap S as shown in FIG. Is formed. The central portion of the gap S in the ball guide 74 is formed in an annular shape in a horizontal cross section (not shown).

  Further, a dimensional difference shorter than the outer diameter dimension of the ball body 70 between the height of the bottom surface 74 b of the ball guide 74 from the basic floor surface 41 and the height of the bottom surface 72 d of the ball seat 72 from the basic floor surface 41. Is provided.

  For this reason, when the ball body 70 is spread on the base floor surface 41 below the bottom surface 72 d of the ball sheet 72, a part of the ball body 70 sandwiched between the bottom surface 72 d of the ball sheet 72 and the base floor surface 41. Is arranged to be exposed below the bottom surface 74 b of the ball guide 74.

  The ball body 70 is not only below the bottom surface 72d of the ball sheet 72 but also in a gap S formed between the concave spherical surface portion 74e of the ball guide 74 and the convex spherical surface portion 72b of the ball sheet 72, and is substantially adjacent to each other. Filled.

  Then, when the ball bearing 60 shown in FIG. 9 moves horizontally with respect to the base floor surface 41, the ball body 70 located on the opposite side to the side where the horizontal movement proceeds is below the bottom surface 72d of the ball seat 72. The ball body 70 that has entered the gap S and circulated and rolled and located on the traveling side of the horizontal movement moves toward the side opposite to the traveling side.

  For this reason, when the ball bearings 60 are moved horizontally by bringing the ball bearings 60 into contact with the foundation floor 41, the ball bearings 60 are circulated and rolled following the horizontal movements. By operating the body 70 in this way, the seismic isolation frame 42 can freely move on the foundation floor 41 in any horizontal direction.

  As shown in FIG. 11, when the foundation floor 41 is inclined with respect to the horizontal plane, the ball guide 74 of the ball bearing 60 disposed thereon is lowered with respect to the plate-like member 54. By rotating a predetermined angle with respect to the support bar member 56, all of the large number of ball bodies 70 can be brought into uniform contact with the foundation floor surface 41 in the same manner as when the foundation floor surface 41 is not inclined.

  Since the seismic isolation floor structure 40 according to the present embodiment includes the connecting member 52 that connects the pair of frames 46 arranged so that the ends thereof face each other, the conventional seismic isolation structure is provided. Like the frame 6 in the seismic floor structure 2, it is not necessary to provide a large through hole that causes a decrease in strength in the frame 46 or the connecting frame 50, so that the support strength of the seismic isolation floor structure 40 is reduced. Can be prevented.

  In addition, a plate-shaped member 54, a support bar member 56, a bolt 58, and By arranging the ball bearing 60, it is possible to prevent the height dimension of the seismic isolation floor structure 40 from increasing.

  Further, according to the inclined surface of the foundation floor surface 41, the ball bearing 60 is lowered with respect to the plate-like member 54, and the relative angle of the ball guide 74 of the ball bearing 60 is changed with respect to the support bar member 56. Therefore, even if there is a portion where the inclined surface is formed on the foundation floor surface 41, all the ball bodies 70 of the ball bearing 60 can be brought into uniform contact with the foundation floor surface 41.

  Moreover, since the vertical space | interval of the plate-shaped member 54 and the ball bearing 60 can be changed according to the change of the height of the foundation floor surface 41, the height differs from most other portions of the foundation floor surface 41. Even if there is a portion, all the ball bodies 70 of the ball bearing 60 can be uniformly brought into contact with the foundation floor surface 41.

  Further, even if there is a portion where the inclined surface is formed on the foundation floor surface 41 or a portion whose height varies depending on the location, all the ball bodies 70 of the ball bearing 60 can be brought into contact with the foundation floor surface 41 uniformly. Therefore, an effective seismic isolation operation can be sufficiently performed against horizontal vibrations and displacements of buildings caused by earthquakes and the like.

  In addition, the frame 46, the cover 48, and the connecting frame 50 that constitute the seismic isolation frame 42 are fixed to the connecting member 52, and the seismic isolation support portion 44 mainly includes the connecting member 52, the plate-like member. 54, the support rod member 56, the bolt 58, and the ball bearing 60, the base isolation structure 40 is simple in structure and easy to assemble, so that the material cost and manufacturing cost can be reduced. can do.

  Therefore, as described above, according to the base isolation floor structure 40 according to the present embodiment, it is possible to prevent the support strength of the base isolation floor structure 40 from being lowered and An increase in the height dimension can be prevented.

  FIGS. 12 to 16 are views referred to for explaining the seismic isolation floor structure 80 according to the second embodiment of the present invention.

  As shown in FIG. 12, the seismic isolation support portion 82 of the base isolation floor structure 80 according to the present embodiment mainly includes a connecting member 52, a ball bearing 60, a bolt 58, and a first plate member 84 that constitutes a support mechanism. , A support bar member 86, a first round bar member 88, a second plate member 90, and a second round bar member 92, a plurality of seismic isolation support portions 82 are arranged on the foundation floor 41, The seismic isolation frame 42 is supported from below.

  Here, the other component members excluding the connecting member 52 from the seismic isolation support portion 82, that is, the support bar member 86, the first plate member 84, the first round bar member 88, the second plate member 90, the second member. The round bar member 92, the bolt 58, and the ball bearing 60 are collectively referred to as a seismic isolation leg.

  As shown in FIG. 12, a male thread portion 86a of a support rod member 86 to be described later is inserted from the lower side in the drawing into a through hole 52j (see FIG. 4) of the raised plate portion 52h, and then a nut 62 is inserted into the male thread portion 86a. As will be described later, since the support rod member 86 is integrally fixed to the first plate-like member 84, the second lower plate 52h (see FIGS. 5 and 12) The support bar member 86 is fixed to the rising plate portion 52h by bringing the upper surface 84a of the one plate-like member 84 into contact and fastening with the screw.

  As shown in FIG. 15, the first plate-like member 84 is formed in a substantially square outer shape, and through holes 84 c are formed near each of the four corners. The through hole 84c is located at a position that is coaxial with the through hole 52k (see FIG. 4) of the raised plate portion 52h when the first plate member 84 is superimposed on the raised plate portion 52h from below. The diameter is smaller than the through hole 52k.

  As shown in FIG. 14, the first plate-like member 84 is such that the lower end surface of the support rod member 86 is brought into contact with the center portion of the upper surface 84a, and the upper surface 84a and the outer peripheral surface of the lower end portion of the support rod member 86 are It is comprised integrally with the support bar member 86 by welding the corner part between.

  Thus, the support rod member 86 is provided so as to protrude upward from the upper surface 84a of the first plate-like member 84, and a male screw portion 86a is formed on the outer periphery thereof.

  In the 1st plate-shaped member 84 shown in FIG. 13, the 1st round bar member 88 which contacts the lower surface 84b is arrange | positioned, and the space between the lower surface 84b and the outer peripheral surface of the 1st round bar member 88 is welded. Thus, the first plate member 84 is configured integrally with the first round bar member 88.

  As shown in FIG. 14, below the first plate member 84 and the first round bar member 88, the second plate member 90 and the second round bar member 92 having the same configuration are overlapped with each other. Is arranged.

  The first round bar member 88 is placed on the upper surface 90a of the second plate member 90, and the outer peripheral surface of the first round bar member 88 is limited to the upper surface 90a of the second plate member 90. It is in contact so that it can roll within an angle.

  As shown in FIG. 15, the second plate-like member 90 also has the same outer shape as the first plate-like member 84, and the outer shape is aligned with the first plate-like member 84 and in the vertical direction. Are arranged so as to overlap in the vertical direction.

  That is, as shown in FIG. 15, the outer shape of the second plate-like member 90 is formed in a substantially square shape, and through holes 90c are formed in the vicinity of the four corners. The through hole 90 c is formed at a position on the same axis as the through hole 84 c of the first plate member 84 when the second plate member 90 is arranged so as to be aligned with the first plate member 84. The diameter is substantially the same as the through hole 84c.

  A second round bar member 92 is disposed in contact with the lower surface 90b of the second plate-shaped member 90 shown in FIG. 14, and the lower surface 90b and the outer peripheral surface of the second round bar member 92 are welded. Thus, the second plate-like member 90 is configured integrally with the second round bar member 92.

  As shown in FIG. 15, the first round bar member 88 is arranged such that its axis extends in the left-right direction in the figure at the center of the first plate-like member 84 in the up-down direction and the first plate-like member 84. It is fixed to the lower surface 84b (see FIG. 14) of the member 84.

  On the other hand, the second round bar member 92 is arranged such that its axis extends in the up-down direction in FIG. 15 at the central portion in the left-right direction in FIG. The member 90 is fixed to the lower surface 90b (see FIG. 14).

  For this reason, as shown in FIG. 15, the first round bar member 88 and the second round bar member 92 are arranged so that their axes are orthogonal to each other when viewed from above.

  12 and 13, the outer peripheral surface of the second round bar member 92 is in contact with the upper surface 74 a of the ball guide 74 of the ball bearing 60 so as to be able to roll within a limited angle.

  The male screw portion 58a of the bolt 58 is inserted into the through-hole 84c and the through-hole 90c of the second plate-like member 90 from the upper surface 84a side of the first plate-like member 84, and has a tip portion protruding downward. The ball bearing 60 is fixed to the ball bearing 60 by being screwed to four female screw portions 74c formed on the upper surface 74a of the ball guide 74 of the ball bearing 60 as shown in FIG.

  The first plate-like member 84 is configured such that the lower surface of the head of the bolt 58 is engaged with or detached from the upper surface 84a of the first plate-like member 84 in accordance with the change in the distance from the foundation floor 41. The first plate member 84 is loosely connected to the ball bearing 60 with play.

  That is, as shown in FIG. 13, the space between the base floor 41 and the lower surface 84b of the first plate member 84 is shortened, and the lower surface of the head of the bolt 58 and the upper surface 84a of the first plate member 84 are separated. At this time, the ball bearing 60 is not engaged (separated) with the first plate member 84 via the bolt 58.

  On the other hand, when the space between the foundation floor 41 or the ball bearing 60 and the lower surface 84b of the first plate member 84 is widened, the bottom surface of the bolt 58 and the upper surface 84a of the first plate member 84 come into contact The bearing 60 is engaged with the first plate member 84 through the bolt 58.

  Therefore, the bolt 58 is normally spaced from the upper surface 84a of the first plate member 84 by the lower surface of the head when the tip of the male screw portion 58a is screwed to the female screw portion 74c of the ball guide 74. However, since the height of a part of the foundation floor surface 41 is lower than the other parts of the foundation floor surface 41, the ball guide 74 of the ball bearing 60 is formed. When the height of the bolt 58 is lowered from the other ball bearing 60, the lower surface of the head of the bolt 58 comes into contact with the upper surface 84a of the first plate member 84, and the ball guide 74 and the first plate member 84 are most separated. It becomes a state.

  By the way, the head portion of the bolt 58 is in a state in which the male screw portion 58a is inserted into the through hole 84c of the first plate member 84, as shown in FIG. 5) and inserted into the through hole 52k.

  Depending on the state of the foundation floor 41, the upper surface 74 a and the bolt 58 of the ball bearing 60 are moved relative to the first plate member 84 and the second plate member 90 through the rolling operation of one or both of the round bar members 88 and 92. In order to prevent the head of the bolt 58 from coming into contact with the inner peripheral surface of the through hole 52k when the head is rotated by a predetermined angle, the diameter of the through hole 52k of the raised plate portion 52h is the diameter of the head of the bolt 58. It is formed larger than the dimension.

  The through hole 84c (see FIG. 13) of the first plate-like member 84 and the through-hole 90c of the second plate-like member 90 also include the upper surface 74a and the bolt 58 of the ball bearing 60, and one or both of the round bar members 88 and 92. The male screw portion 58a of the bolt 58 contacts the inner peripheral surface of the through-hole 84c or the through-hole 90c when rotating by a predetermined angle with respect to the first plate-like member 84 or the second plate-like member 90 through the rolling operation. In order to avoid this, the diameter of the bolt 58 is larger than the diameter of the male threaded portion 58a.

  As described above, the first plate member 84 and the ball bearing 60 are engaged with or disengaged from each other via the bolts 58. When the first plate member 84 and the ball bearing 60 are separated, the first plate member 84 and the ball bearing 60 are engaged with each other. Since the two plate-like members 90 are loosely connected to the ball bearing 60 with play, the first round bar member 88 and the second plate are compared with the first plate-like member 84 in a substantially stationary state. The ball bearing 60 is allowed to rotate to a predetermined angle through the shaped member 90 and the second round bar member 92.

  When the foundation floor 41 is inclined with respect to the horizontal plane in the left-right direction in FIG. 16, the ball guide 74 of the ball bearing 60 is in relation to the first plate member 84 via the first round bar member 88. It rotates by the tilt angle.

  Further, when the foundation floor surface 41 is inclined with respect to the horizontal plane in the front-rear direction of the paper surface in the drawing, the ball guide 74 of the ball bearing 60 is moved with respect to the second plate member 90 via the second round bar member 92. Rotate by the tilt angle. In this way, a large number of ball bodies 70 can be brought into uniform contact with the foundation floor surface 41 in the same manner as when the foundation floor surface 41 is not inclined.

  Further, when the foundation floor 41 is inclined with respect to the horizontal plane in a direction other than the left-right direction or the front-rear direction in FIG. 16, the ball guide 74 of the ball bearing 60 rolls both the round bar members 88 and 92. And the first plate-like member 84 and the second plate-like member 90 are both rotated by the inclination angle so that a large number of ball bodies 70 are the same as when the foundation floor 41 is not inclined. Furthermore, the base floor surface 41 can be uniformly contacted.

  In such a base-isolated floor structure 80 according to the present embodiment, as in the first embodiment, the ends of a pair of frames 46 arranged so that the ends thereof face each other are connected. Since the connecting member 52 is provided, the frame 46 and the connecting frame 50 do not need to be provided with a large through hole that causes a decrease in strength, unlike the frame 6 in the conventional base-isolated floor structure 2. Further, it is possible to prevent the support strength of the base isolation floor structure 80 from being lowered.

  Further, below the raised plate portion 52h where the end portions of the pair of frames 46 of the connecting member 52 are raised upward, the support rod member 86, the first plate-like member 84, the first plate-like member constituting the seismic isolation leg portion. By arranging the 1 round bar member 88, the second plate member 90, the second round bar member 92, the bolt 58 and the ball bearing 60, the height dimension of the base isolation floor structure 80 is prevented from becoming large. Can do.

  In addition, even if there is a portion where the inclined surface is formed on the foundation floor surface 41 or a portion where the height is different depending on the location, there is no portion where the inclined surface is formed on the foundation floor surface 41 or a portion where the height is different. Similarly, since all the ball bodies 70 of the ball bearing 60 can be brought into uniform contact with the foundation floor surface 41, an effective seismic isolation operation against horizontal vibration and displacement of the building caused by an earthquake or the like. Can be performed sufficiently.

  Further, the frame 46, the cover 48, and the connecting frame 50 constituting the seismic isolation frame 42 are fixed to the connecting member 52, and the seismic isolation support portion 82 mainly includes the connecting member 52, the first plate. The seismic isolation floor structure 80 is composed of the cylindrical member 84, the support bar member 86, the first round bar member 88, the second plate member 90, the second round bar member 92, the bolt 58 and the ball bearing 60. Since the structure is simple and the assembly is simple, the material cost and manufacturing cost can be reduced.

  Therefore, as described above, according to the base isolation floor structure 80 according to the present embodiment, it is possible to prevent the support strength of the base isolation floor structure 80 from being lowered and An increase in the height dimension can be prevented.

  In the base-isolated floor structure 40 according to the first embodiment, the convex spherical portion 56c is formed at the tip of the protruding portion 56b of the support bar member 56, but instead of the convex spherical portion 56c. The chamfered portion obtained by scraping the corner portion of the tip portion to approximately 45 degrees, or the R surface portion may be formed at the angle of the tip portion.

  Further, the support rod member 56 in the base isolation floor structure 40 is configured by a substantially single part whose central portion is inserted through the through hole 54d of the plate member 54. The portion that protrudes upward from the upper surface 54a of the member 54 and the portion that protrudes downward from the lower surface 54b thereof may be configured by a plurality of separate members.

  The seismic isolation legs in the base isolation floor structure 40 are composed of a plate member 54, a support bar member 56, a bolt 58 and a ball bearing 60, and the base isolation legs in the base isolation floor structure 80 are support bars. The base 86 is composed of the member 86, the first plate member 84, the first round bar member 88, the second plate member 90, the second round bar member 92, the bolt 58 and the ball bearing 60. The structure is not limited to the structure of the seismic isolation floor structures 40 and 80 as long as it is placed on the floor surface 41 and connected to the connecting member 52 to perform the seismic isolation operation.

  In the seismic isolation floor structure 80 according to the second embodiment, two sets of the first plate member 84 and the first round bar member 88, and the second plate member 90 and the second round bar member 92 are provided. For example, only one set of the first plate member 84 and the first round bar member 88 may be arranged.

  The connecting member 52 in the seismic isolation floor structures 40, 80 is not limited to the outer shape described in the base isolation floor structures 40, 80, but is formed to rise upward between the frames 46. As long as it has the up board part 52h and the seismic isolation leg part can be arrange | positioned under the rising board part 52h, it may be what kind of other external shape.

2 Base-isolated floor structure 3 Foundation floor 6 Frame 6a Upper plate 6b Lower plate 6c Through hole 8 Frame 10 Ball bearing 10a Male thread 10b Ball body 12, 14 Nut 16 Set screw 16a Slot 18 Support leg 40 Base isolation Structure 41 Foundation floor surface 42 Seismic isolation frame 44 Seismic isolation support portion 46 Frame 46a Hollow portion 46b Through hole 47 Bolt 48 Cover 48a Through hole 50 Connection frame 50a Hollow portion 52 Connection member 52a Flat plate portion 52b Upper surface 52c Screw hole 52d Notch 52e Bent plate portion 52f Long hole 52g Inclined portion 52h Swelling plate portion 52i Upper surface 52j, 52k Through hole 52m Lower surface 54 Plate member 54a Upper surface 54b Lower surface 54c, 54d Through hole 56 Support rod member 56a Male thread portion 56b Protruding portion 56c Convex spherical surface Part 58 bolt 58a male screw 60 Ball bearing 62 Nut 70 Ball body 72 Ball seat 72a Cylindrical portion 72b Convex spherical surface portion 72c Upper surface 72d Bottom surface 72e Female thread portion 74 Ball guide 74a Upper surface 74b Bottom surface 74c Female thread portion 74d Counterbore hole 74e Concave spherical surface portion 74g Stepped concave portion 76 Countersunk screw 76a Male screw Part 80 Base-isolated floor structure 82 Base-isolated support part 84 First plate member 84a Upper surface 84b Lower surface 84c Through hole 86 Support rod member 86a Male thread portion 88 First round bar member 90 Second plate member 90a Upper surface 90b Lower surface 90c Through hole 92 Second round bar member S Clearance W Welding

Claims (3)

In the seismic isolation floor structure having a base isolation frame having a plurality of frames and a plurality of base isolation support parts for supporting the base isolation frame,
The seismic isolation support portion includes a connecting member that connects the ends of the pair of frames arranged opposite to each other, and a base isolation leg portion placed on the foundation floor surface,
The connecting member has a flat plate portion between the flat plate portion whose lower surface of the end portion of the frame is fixed in contact with the upper surface and the end portions of the pair of frames arranged opposite to each other . It has a raised plate part formed so as to rise above the upper surface ,
The upper surface of the raised plate portion is formed below the upper surface of the frame,
The base isolation floor structure is characterized in that the base isolation leg portion is disposed below the rising plate portion. The seismic isolation leg includes a ball bearing placed on a foundation floor, and a support mechanism arranged above the ball bearing and connected to the connecting member,
The base-isolated floor structure according to claim 1, wherein the ball bearing is in contact with the support mechanism so as to be tiltable.   The support mechanism includes a plate-like member disposed below the raised plate portion, and a support bar member fixed to the plate-like member and having a lower end protruding downward from the plate-like member. The base-isolated floor structure according to claim 2.

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