JP2018188918A - Jack device, jack jig unit, and support method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a jack device, a jack jig unit, and a support method capable of maintaining a state in which an upper structure is supported by a lower structure against shaking. SOLUTION: A jack device and a jack jig unit include an upper jig disposed between an upper structure and a jack, and a lower jig disposed between the jack and the lower structure. The lower surface portion of the upper jig and the upper surface portion of the lower jig are respectively provided with curved surface portions so that the jack can swing when the lower structure is displaced laterally with respect to the upper structure. Prepare. Further, in the support method, the upper structure is supported by the lower structure by disposing at least one jack device between the upper structure and the lower structure. [Selection] Figure 2

Description

  The present invention relates to a jack device disposed between an upper structure and a lower structure that are separated in the vertical direction. The present invention also relates to a jack jig unit including an upper jig disposed between an upper structure and a jack, and a lower jig disposed between the jack and the lower structure. The present invention also relates to a support method for supporting an upper structure on a lower structure.

  Conventionally, as a jack device, for example, when exchanging a seismic isolation device arranged between an upper structure and a lower structure separated in the vertical direction, a jack arranged between the upper structure and the lower structure An apparatus is known (for example, Patent Document 1). Such a jack apparatus includes a jack, an upper jig disposed between the upper structure and the jack, and a lower jig disposed between the jack and the lower structure.

  In the jack device according to Patent Document 1, when the earthquake is detected, the jack is lowered to release the state in which the upper structure is supported by the lower structure. By the way, for example, there is a demand for maintaining a state in which the upper structure is supported by the lower structure with a jack against a certain degree of shaking (small earthquake). However, in the jack device according to Patent Document 1, the jack slides with respect to each jig or the lower jig slides with respect to the lower structure in response to the swing, thereby lowering the upper structure. The state of supporting the structure may not be maintained.

JP 2017-8548 A

  Then, a subject is providing the jack apparatus, the jig unit for jack, and the support method which can maintain the state which supports the upper structure with a lower structure with respect to a shake.

  The jack device includes: a jack disposed between an upper structure and a lower structure separated in a vertical direction; an upper jig disposed between the upper structure and the jack; the jack and the lower structure A lower jig disposed between the lower jig and the upper jig. The lower jig and the upper jig are arranged in a lateral direction with respect to the upper structure. Each of the jacks is provided with a curved surface portion so that the jack can swing when displaced.

  In the jack device, the upper surface portion and the lower surface portion of the jack may be formed in a flat shape, and the curved surface portion may be formed in a convex curved surface.

  Further, in the jack apparatus, the lower surface portion of the upper jig includes a flat surface portion that is smaller than the upper surface portion of the jack at the center portion, and the upper surface portion of the lower jig is disposed at the center portion of the jack. The structure of having a plane part smaller than a lower surface part may be sufficient.

  In the jack device, the ratio of the width of the flat portion of the upper jig to the height of the jack is more than the coefficient of static friction between the upper surface portion of the jack and the flat portion of the upper jig. The ratio of the width of the flat portion of the lower jig to the height of the jack is smaller than the static friction coefficient between the lower surface portion of the jack and the flat portion of the lower jig. It may be configured.

  In the jack device, the upper surface portion of the upper jig may be larger than the upper surface portion of the jack, and the lower surface portion of the lower jig may be larger than the lower surface portion of the jack.

  In addition, the jack jig unit includes an upper jig disposed between the upper structure and the jack with respect to the jack disposed between the upper structure and the lower structure separated in the vertical direction. A lower jig disposed between the jack and the lower structure, and a lower surface portion of the upper jig and an upper surface portion of the lower jig Each jack is provided with a curved surface portion so that the jack can swing when displaced laterally with respect to the structure.

  In the supporting method, the upper structure is supported by the lower structure by disposing the at least one jack device between the upper structure and the lower structure separated in the vertical direction.

  As described above, the jack device, the jack jig unit, and the support method have an excellent effect that the state in which the upper structure is supported by the lower structure can be maintained against shaking.

FIG. 1 is an overall front view of a jack device according to an embodiment. FIG. 2 is an enlarged view of region II in FIG. FIG. 3 is an overall exploded front view of the jack device according to the embodiment. FIG. 4 is an overall front view for explaining the operation of the jack device according to the embodiment, and shows a state in which a small shaking has occurred. FIG. 5 is an overall front view for explaining the operation of the jack device according to the embodiment, and shows a state in which a large shaking has occurred. FIG. 6 is an overall front view of a jack device according to another embodiment. FIG. 7 is an overall front view of a jack device according to still another embodiment. FIG. 8 is an overall front view of a jack device according to still another embodiment and is a view showing a partial cross section. FIG. 9 is an overall front view of a jack device according to still another embodiment and is a view showing a partial cross section. FIG. 10 is an overall front view of a jack device according to still another embodiment. FIG. 11 is an overall front view of a jack device according to still another embodiment.

  Hereinafter, an embodiment of a jack device, a jack jig unit, and a support method will be described with reference to FIGS. In each figure (the same applies to FIGS. 6 to 11), the dimensional ratio of the drawings does not necessarily match the actual dimensional ratio, and the dimensional ratios between the drawings do not necessarily match. Absent.

  Here, before explaining each structure of a jack apparatus, a building is demonstrated. As shown in FIG. 1, the building 10 includes an upper structure 11 and a lower structure 12 that are separated in the vertical direction, and a seismic isolation device 13 that is disposed between the upper structure 11 and the lower structure 12. ing. For example, the seismic isolation device 13 is released from being fixed to the upper structure 11 and the lower structure 12 in order to be replaced.

  The upper structure 11 includes an upper casing 11a that is in contact with the seismic isolation device 13 and a structure main body 11b that supports an upper portion of the upper casing 11a. And the load capacity of the upper housing 11a in the vertical direction is larger than the load capacity of the structural body 11b in the vertical direction. In the present embodiment, the upper casing 11a is a pillar, and the structural body 11b is a beam extending in a long length. The upper structure 11 is not limited to such a configuration.

  The lower structure 12 includes a lower housing 12a that is in contact with the seismic isolation device 13, and a structural body 12b that supports the lower portion of the lower housing 12a. And the load resistance of the up-down direction in the lower housing 12a is larger than the load resistance of the up-down direction in the structure main body 12b. In the present embodiment, the lower housing 12a is a foundation pillar, and the structural body 12b is a foundation that spreads in a planar shape. The lower structure 12 is not limited to such a configuration.

  The jack apparatus 1 is disposed between the upper structure 11 and the lower structure 12, thereby supporting the upper structure 11 on the lower structure 12. Specifically, the jack apparatus 1 is disposed between an upper casing 11a and a lower casing 12a having a large load capacity in the vertical direction. And the jack apparatus 1 is arranged in parallel around the seismic isolation apparatus 13 (for example, two to six, two are shown in FIG. 1).

  The jack apparatus 1 includes a jack 2 disposed between an upper housing 11a and a lower housing 12a, and a jack jig unit 3 disposed between the jack 2 and the housings 11a and 12a. The jack jig unit 3 includes an upper jig 4 disposed between the upper housing 11a and the jack 2, and a lower jig 5 disposed between the jack 2 and the lower housing 12a. ing.

  As shown in FIG.2 and FIG.3, the jack 2 is provided with the jack main body 2a and the movable body 2b which can move to an up-down direction with respect to the jack main body 2a. When the pressure medium flows into the jack body 2a, the movable body 2b rises (jacks up) with respect to the jack body 2a, and conversely, the pressure medium flows out from the jack body 2a. Thus, the movable body 2b is lowered (jacked down) with respect to the jack body 2a.

  In the present embodiment, the jack 2 is a hydraulic jack using a pressure medium as oil. The jack 2 may be a jack in which the pressure medium is another liquid or gas. The jack body 2a and the movable body 2b are made of a metal having high rigidity such as iron or stainless steel, for example.

  The upper surface portion 2c of the jack 2 (that is, the upper surface portion 2c of the movable body 2b) is formed in a flat shape, and the lower surface portion 2d of the jack 2 (that is, the lower surface portion 2d of the jack body 2a) is formed in a flat shape. Has been. Moreover, the upper surface part 2c of the jack 2 is formed in a circular shape, and the lower surface part 2d of the jack 2 is formed in a circular shape.

  The upper jig 4 includes an upper surface portion 4 a that contacts the upper housing 11 a of the upper structure 11 and a lower surface portion 4 b that contacts the upper surface portion 2 c of the jack 2. And the upper jig | tool 4 is formed with the metal which has high rigidity, such as iron, stainless steel, duralumin, for example.

  The upper surface portion 4a of the upper jig 4 is formed in a planar shape. The upper surface portion 4a of the upper jig 4 is formed in a circular shape. The upper surface portion 4 a of the upper jig 4 is larger than the upper surface portion 2 c of the jack 2. Specifically, the area of the upper surface portion 4 a of the upper jig 4 is larger than the area of the upper surface portion 2 c of the jack 2. That is, the width (diameter) W4a of the upper surface portion 4a of the upper jig 4 is larger than the width (diameter) W2c of the upper surface portion 2c of the jack 2.

  The lower surface portion 4b of the upper jig 4 includes a flat surface portion 4c formed in a flat shape and a curved surface portion 4d formed in a curved surface shape. The flat surface portion 4 c is disposed at the center portion of the lower surface portion 4 b of the upper jig 4, and the curved surface portion 4 d is disposed at the outer peripheral portion of the lower surface portion 4 b of the upper jig 4.

  The flat surface portion 4c of the upper jig 4 is formed in a circular shape. The flat portion 4 c of the upper jig 4 is smaller than the upper surface portion 2 c of the jack 2. Specifically, the area of the flat surface portion 4 c of the upper jig 4 is smaller than the area of the upper surface portion 2 c of the jack 2. That is, the width (diameter) W4c of the flat surface portion 4c of the upper jig 4 is smaller than the width (diameter) W2c of the upper surface portion 2c of the jack 2.

  The curved surface portion 4d of the upper jig 4 is formed in a convex curved surface. The curved surface portion 4d of the upper jig 4 is formed to be a part of a spherical body. Further, in the curved surface portion 4d of the upper jig 4, the lateral dimension W4d1 in the lateral direction is larger than the vertical dimension W4d2.

  The ratio R1 of the width W4c of the flat portion 4c of the upper jig 4 to the height W2 of the jack 2 is larger than the static friction coefficient μ1 between the upper surface portion 2c of the jack 2 and the flat portion 4c of the upper jig 4. It is getting smaller. Since the height W2 of the jack 2 changes, in this embodiment, the ratio R1 when the movable body 2b is lowered most (ie, when the jack 2 is jacked down) is the static friction coefficient μ1. Is smaller than.

  For example, since the static friction coefficient μ1 is 0.3 to 0.8, the ratio R1 when the movable body 2b is lowered most is 0.25 or less, preferably 0.2 or less, more preferably 0.15 or less, very preferably 0.1 or less. Further, the ratio R1 when the movable body 2b is lowered most is preferably 0.05 or more, for example.

  Accordingly, the ratio R1 is always smaller than the static friction coefficient μ1 regardless of the height W2 of the jack 2. Therefore, in the state where the jack 2 is jacked up and the jack apparatus 1 supports the upper structure 11 on the lower structure 12, the ratio R1 is always smaller than the static friction coefficient μ1.

  The lower jig 5 includes an upper surface portion 5a that contacts the lower surface portion 2d of the jack 2 and a lower surface portion 5b that contacts the lower housing 12a of the lower structure 12. And the lower jig | tool 5 is formed with the metal which has high rigidity, such as iron, stainless steel, duralumin, for example.

  The upper surface portion 5a of the lower jig 5 includes a flat surface portion 5c formed in a flat shape and a curved surface portion 5d formed in a curved surface shape. The flat surface portion 5 c is disposed at the center of the upper surface portion 5 a of the lower jig 5, and the curved surface portion 5 d is disposed at the outer peripheral portion of the upper surface portion 5 a of the lower jig 5.

  The flat portion 5c of the lower jig 5 is formed in a circular shape. The flat portion 5 c of the lower jig 5 is smaller than the lower surface portion 2 d of the jack 2. Specifically, the area of the flat portion 5 c of the lower jig 5 is smaller than the area of the lower surface portion 2 d of the jack 2. That is, the width (diameter) W5c of the flat surface portion 5c of the lower jig 5 is smaller than the width (diameter) W2d of the lower surface portion 2d of the jack 2.

  The curved surface portion 5d of the lower jig 5 is formed in a convex curved surface. The curved surface portion 5d of the lower jig 5 is formed to be a part of a spherical body. Further, in the curved surface portion 5d of the lower jig 5, the lateral dimension W5d1 when viewed in the lateral direction is larger than the vertical dimension W5d2.

  The lower surface portion 5b of the lower jig 5 is formed in a planar shape. Further, the lower surface portion 5b of the lower jig 5 is formed in a circular shape. The lower surface portion 5 b of the lower jig 5 is larger than the lower surface portion 2 d of the jack 2. Specifically, the area of the lower surface part 5 b of the lower jig 5 is larger than the area of the lower surface part 2 d of the jack 2. That is, the width (diameter) W5b of the lower surface portion 5b of the lower jig 5 is larger than the width (diameter) W2d of the lower surface portion 2d of the jack 2.

  The ratio R2 of the width W5c of the flat portion 5c of the lower jig 5 to the height W2 of the jack 2 is based on the static friction coefficient μ2 between the lower surface portion 2d of the jack 2 and the flat portion 5c of the lower jig 5. Even smaller. And since the height W2 of the jack 2 changes, in this embodiment, the ratio R2 when the movable body 2b is lowered most is smaller than the static friction coefficient μ2.

  For example, since the static friction coefficient μ2 is 0.3 to 0.8, the ratio R2 when the movable body 2b is lowered most is 0.25 or less, preferably 0.2 or less, more preferably 0.15 or less, very preferably 0.1 or less. Further, the ratio R2 when the movable body 2b is lowered most is preferably 0.05 or more, for example.

  The configuration of the jack apparatus 1 according to the present embodiment is as described above. Next, a support method by the jack apparatus 1 according to the present embodiment will be described with reference to FIGS. 4 and 5.

  First, when the lower structure 12 supports the upper structure 11 by the jack device 1, it is assumed that a load F1 having a predetermined size in the vertical direction is applied to the jack 2. At this time, when the lateral forces F2 and F3 are applied to the jack 2, the jack 2 can swing between the jigs 4 and 5 (in this specification, the concept does not include "slip"). And the possibility that the jack 2 slides with respect to the jigs 4 and 5.

For example, in order for the jack 2 to swing between the jigs 4 and 5, a force F <b> 2 having a predetermined magnitude is required in the lateral direction with respect to the jack 2. The magnitude of the force (hereinafter also referred to as “swing start force”) F2 is represented by the following equation.
F2 = F1 × R1 (or R2) (1)
R1 is the ratio of the width W4c of the flat portion 4c of the upper jig 4 to the height W2 of the jack 2, and R2 is the width W5c of the flat portion 5c of the lower jig 5 to the height W2 of the jack 2. Ratio.

On the other hand, in order for the jack 2 to slide relative to the jigs 4, 5, a force F 3 having a predetermined magnitude is required in the lateral direction with respect to the jack 2. The magnitude of the force (hereinafter also referred to as “slip start force”) F3 is represented by the following equation.
F3 = F1 × μ1 (or μ2) Equation (2)
Μ1 is a coefficient of static friction between the upper surface portion 2c of the jack 2 and the flat surface portion 4c of the upper jig 4; The coefficient of static friction between.

  Therefore, as shown in FIG. 4, when there is no shaking (earthquake), or when a lateral force F4 smaller than the swing start force F2 or the slip start force F3 is applied to the jack 2 due to the swing, the jack 2 Does not swing between the jigs 4 and 5, and the jack 2 does not slide relative to the jigs 4 and 5. As a result, the upper surface portion 2c and the lower surface portion 2d of the jack 2 are in contact with the flat surface portions 4c and 5c of the jigs 4 and 5, respectively, thereby maintaining the state in which the upper structure 11 is supported by the lower structure 12. Can do.

  Incidentally, in the present embodiment, since the ratios R1 and R2 are smaller than the static friction coefficients μ1 and μ2, the swing start force F2 is smaller than the slip start force F3. Therefore, as shown in FIG. 5, when a lateral force F5 larger than the swing start force F2 is applied to the jack 2, the upper surface portion 2c and the lower surface portion 2d of the jack 2 are the curved surface portions of the jigs 4 and 5, respectively. The jack 2 swings by contacting 4d and 5d, respectively.

  Thereby, it is possible to maintain a state in which the lower structure 12 is supported by the lower structure 12 while the lower structure 12 is displaced laterally with respect to the upper structure 11. At this time, when the jack 2 swings, the jack 2 is controlled such that the height W2 of the jack 2 is constant (including not only completely the same but also substantially the same).

  Since the curvature radii of the curved surface portions 4d and 5d of the jigs 4 and 5 have a predetermined value, the distance W10 between the upper structure 11 and the lower structure 12 is constant (not only when they are completely the same). , Including substantially the same case). For example, when the curvature radii of the curved surface portions 4d and 5d of the jigs 4 and 5 are 50% of the height W2 of the jack 2, the distance W10 between the upper structure 11 and the lower structure 12 is made constant. be able to. Therefore, the curvature radii of the curved surface portions 4d and 5d of the jigs 4 and 5 are, for example, 40 to 60% of the height W2 of the jack 2, and preferably 45 to 55%.

  In this way, since the jack 2 swings to prevent the jack 2 from sliding with respect to the jigs 4 and 5, the jack device is provided in a narrow region between the upper housing 11a and the lower housing 12a. Even if 1 is disposed, the state in which the upper structure 11 is supported by the lower structure 12 can be maintained. Therefore, for example, it is not necessary to perform reinforcement work (for example, see FIGS. 10 and 11 described later) using reinforced concrete or the like, and construction (for example, replacement work for the seismic isolation device 13) can be facilitated.

  In addition, in order to suppress that each jig | tool 4 and 5 slips with respect to each structure 11 and 12, each jig | tool 4 and 5 is each fixed with respect to each structure 11 and 12 by the fixing means. It may be configured that. Further, in order to prevent the jigs 4, 5 from sliding relative to the structures 11, 12 by swinging the jack 2, the jigs 4, 5 and the structures 11, 12 A configuration in which the static friction coefficient between them is set to a predetermined value may be employed.

  Specifically, the static friction coefficient μ3 between the upper surface portion 4a of the upper jig 4 and the upper structure 11 is larger than the ratio R1 of the width W4c of the flat surface portion 4c of the upper jig 4 to the height W2 of the jack 2. ,large. The static friction coefficient μ4 between the lower surface portion 5b of the lower jig 5 and the lower structure 12 is larger than the ratio R2 of the width W5c of the flat surface portion 5c of the lower jig 5 to the height W2 of the jack 2. large. In this embodiment, since each structure 11 and 12 is formed of reinforced concrete, the static friction coefficients μ3 and μ4 are 0.3 to 0.8.

  As described above, the support method according to the present embodiment disposes the upper structure 11 by disposing the at least one jack device 1 between the upper structure 11 and the lower structure 12 that are separated in the vertical direction. The structure 12 is supported.

  Further, the jack jig unit 3 according to the present embodiment has the upper structure 11 and the jack 2 with respect to the jack 2 disposed between the upper structure 11 and the lower structure 12 that are separated in the vertical direction. An upper jig 4 disposed between the lower jig 4 and the lower jig 5 disposed between the jack 2 and the lower structure 12, and the lower surface portion 4b of the upper jig 4 and the lower jig 5 The upper surface portion 5a of the lower jig 5 refers to the curved surface portions 4d, 4d, respectively, so that the jack 2 can swing when the lower structure 12 is displaced laterally with respect to the upper structure 11. 5d.

  Moreover, the jack apparatus 1 according to the present embodiment includes a jack 2 disposed between the upper structure 11 and the lower structure 12 that are separated in the vertical direction, and is disposed between the upper structure 11 and the jack 2. An upper jig 4, and a lower jig 5 disposed between the jack 2 and the lower structure 12, and a lower surface portion 4 b of the upper jig 4 and the lower jig 5. The upper surface portion 5 a includes curved surface portions 4 d and 5 d so that the jack 2 can swing when the lower structure 12 is displaced laterally with respect to the upper structure 11.

  According to such a configuration, the lower surface portion 4b of the upper jig 4 and the upper surface portion 5a of the lower jig 5 include the curved surface portions 4d and 5d, respectively. When the lower structure 12 is displaced laterally with respect to the upper structure 11, the upper surface portion 2c of the jack 2 contacts the curved surface portion 4d of the upper jig 4, and the lower surface portion 2d of the jack 2 is The jack 2 swings so as to come into contact with the curved surface portion 5 d of the lower jig 5. Thereby, it is possible to maintain the state in which the upper structure 11 is supported by the lower structure 12 against shaking.

  Further, in the jack device 1 according to the present embodiment, the upper surface portion 2c and the lower surface portion 2d of the jack 2 are each formed in a flat shape, and the curved surface portions 4d and 5d are formed in a convex curved surface, respectively. This is the configuration.

  According to such a configuration, the upper surface portion 2c of the jack 2 formed in a planar shape is in contact with the curved surface portion 4d of the upper jig 4 formed in a convex curved surface, and the jack formed in a planar shape. The jack 2 swings so that the lower surface portion 2d of the lower surface 2 comes into contact with the curved surface portion 5d of the lower jig 5 formed in a convex shape. Thereby, it can suppress that the distance between the upper structure 11 and the lower structure 12 changes, maintaining the state which supports the upper structure 11 to the lower structure 12 with respect to a shake. .

  Moreover, in the jack apparatus 1 according to the present embodiment, the lower surface portion 4b of the upper jig 4 includes a flat surface portion 4c smaller than the upper surface portion 2c of the jack 2 at the center, and the lower jig 5 The upper surface portion 5a has a configuration in which a flat surface portion 4c smaller than the lower surface portion 2d of the jack 2 is provided at the center portion.

  According to such a configuration, at the normal time, the center portion of the upper surface portion 2 c of the jack 2 is in contact with the flat surface portion 4 c disposed at the center portion of the lower surface portion 4 b of the upper jig 4, and the lower surface portion of the jack 2. The central portion of 2d is in contact with the flat portion 5c disposed at the central portion of the upper surface portion 5a of the lower jig 5. Thereby, at the normal time, the upper structure 11 can be stably supported by the lower structure 12.

  And, for example, for small shaking, the center part of the upper surface part 2c and the lower surface part 2d of the jack 2 is in contact with the flat surface parts 4c and 5c of the jigs 4 and 5, respectively, as usual. The upper structure 11 can be supported by the lower structure 12. Thereby, it is possible to maintain the state in which the upper structure 11 is supported by the lower structure 12 without swinging the jack 2 with respect to a swing smaller than a predetermined size.

  Further, for example, for large shaking, the jack 2 swings when the outer surface portions of the upper surface portion 2c and the lower surface portion 2d of the jack 2 come into contact with the curved surface portions 4d and 5d of the jigs 4 and 5, respectively. . Thereby, the state in which the upper structure 11 is supported by the lower structure 12 can be maintained by swinging the jack 2 with respect to the swing larger than a predetermined size.

  Further, in the jack device 1 according to the present embodiment, the ratio R1 of the width W4c of the flat surface portion 4c of the upper jig 4 to the height W2 of the jack 2 is the upper surface portion 2c of the jack 2 and the upper surface treatment. The ratio R2 of the width W5c of the flat portion 5c of the lower jig 5 to the height W2 of the jack 2 is smaller than the static friction coefficient μ1 between the flat portion 4c of the tool 4 and the height 2 of the jack 2. The static friction coefficient μ2 between the lower surface portion 2d and the flat surface portion 5c of the lower jig 5 is smaller.

  According to such a configuration, the ratio R1 of the width W4c of the flat portion 4c of the upper jig 4 to the height W2 of the jack 2 is such that the static friction between the upper surface portion 2c of the jack 2 and the flat portion 4c of the upper jig 4 is. It is smaller than the coefficient μ1. Thereby, before the upper surface part 2c of the jack 2 slides with respect to the plane part 4c of the upper jig | tool 4, the jack 2 rock | fluctuates.

  Further, the ratio R2 of the width W5c of the flat portion 5c of the lower jig 5 to the height W2 of the jack 2 is based on the static friction coefficient μ2 between the lower surface portion 2d of the jack 2 and the flat portion 5c of the lower jig 5. Even small. Thereby, before the lower surface part 2d of the jack 2 slides with respect to the plane part 5c of the lower jig 5, the jack 2 swings. Therefore, the jack 2 swings stably without sliding with respect to the jigs 4 and 5.

  Moreover, in the jack apparatus 1 according to the present embodiment, the upper surface portion 4a of the upper jig 4 is larger than the upper surface portion 2c of the jack 2, and the lower surface portion 5b of the lower jig 5 is the jack 2. The lower surface portion 2d is larger than the lower surface portion 2d.

  According to such a configuration, since the upper surface portion 4a of the upper jig 4 is larger than the upper surface portion 2c of the jack 2, the area in contact with the upper structure 11 is increased. In addition, since the lower surface portion 5b of the lower jig 5 is larger than the lower surface portion 2d of the jack 2, the area in contact with the lower structure 12 is increased. Thereby, when the upper structure 11 is supported by the lower structure 12, the pressure (load per unit area) applied to the upper structure 11 and the lower structure 12 can be reduced. Therefore, for example, damage to the upper structure 11 and the lower structure 12 can be suppressed.

  In addition, the jack apparatus 1, the jack jig unit 3, and the support method are not limited to the configuration of the above-described embodiment, and are not limited to the above-described effects. Of course, the jack device 1, the jack jig unit 3, and the supporting method can be variously modified without departing from the gist of the present invention. For example, it is needless to say that one or a plurality of configurations and methods according to various modifications described below may be arbitrarily selected and employed in the configurations and methods according to the above-described embodiments.

(1) In the jack device 1 and the jack jig unit 3 according to the above embodiment, the lower surface portion 4b of the upper jig 4 includes a flat surface portion 4c, and the upper surface portion 5a of the lower jig 5 is a flat surface portion. 5c is provided. However, the jack apparatus 1 and the jack jig unit 3 are not limited to such a configuration. For example, as shown in FIG. 6, the lower surface portion 4b of the upper jig 4 includes only the curved surface portion 4d without including the flat surface portion 4c, and the upper surface portion 5a of the lower jig 5 includes the flat surface portion 5c. Alternatively, it may be configured only by the curved surface portion 5d.

(2) Moreover, in the jack apparatus 1 and the jack jig unit 3 according to the above embodiment, the upper surface portion 2c and the lower surface portion 2d of the jack 2 are formed in a flat shape, and the curved surfaces of the jigs 4 and 5 are respectively formed. Each of the portions 4d and 5d is configured to have a convex curved surface. However, the jack apparatus 1 and the jack jig unit 3 are not limited to such a configuration.

  For example, as shown in FIGS. 7 to 9, the upper surface portion 2 c and the lower surface portion 2 d of the jack 2 may be formed in curved shapes. Further, for example, as shown in FIGS. 8 and 9, the curved surface portions 4d and 5d of the jigs 4 and 5 may be formed as concave curved surfaces, respectively.

  In the jack apparatus 1 and the jack jig unit 3 according to FIG. 7, the upper surface portion 2c and the lower surface portion 2d of the jack 2 are formed in a convex curved surface shape. And the curved surface parts 4d and 5d of each jig | tool 4 and 5 are formed in the convex curved surface.

  In the jack apparatus 1 and the jack jig unit 3 according to FIG. 8, the upper surface portion 2c and the lower surface portion 2d of the jack 2 are formed in a convex curved surface shape. And the curved surface parts 4d and 5d of each jig | tool 4 and 5 are formed in the concave curved surface.

  In the jack apparatus 1 and the jack jig unit 3 according to FIG. 9, the upper surface portion 2c and the lower surface portion 2d of the jack 2 are formed in a concave curved surface. And the curved surface parts 4d and 5d of each jig | tool 4 and 5 are formed in the convex curved surface.

(3) Moreover, in the jack apparatus 1 and the jack jig unit 3 according to the above embodiment, the upper surface portion 4 a of the upper jig 4 is larger than the upper surface portion 2 c of the jack 2, and the lower surface of the lower jig 5. The part 5 b is configured to be larger than the lower surface part 2 d of the jack 2. However, the jack apparatus 1 and the jack jig unit 3 are not limited to such a configuration.

  For example, the upper surface portion 4 a of the upper jig 4 may be smaller than the upper surface portion 2 c of the jack 2. Further, for example, the lower surface portion 5 b of the lower jig 5 may be smaller than the lower surface portion 2 d of the jack 2.

(4) Moreover, in the supporting method which concerns on the said embodiment, it is the structure that the jack apparatus 1 is arrange | positioned between the upper housing 11a and the lower housing 12a. However, the jack apparatus 1 and the jack jig unit 3 are not limited to such a configuration. For example, as shown in FIG.10 and FIG.11, the structure that at least one part of the jack apparatus 1 is arrange | positioned between the reinforcement bodies 11c and 12c of each structure 11 and 12 may be sufficient.

  Reinforcing bodies 11c and 12c according to FIG. 10 are formed by reinforcing work for expanding the lower surface of upper casing 11a and the upper surface of lower casing 12a. In the support method according to FIG. 10, the jack apparatus 1 is disposed between the upper casing 11 a and the upper reinforcing body 11 c of the upper structure 11 and the lower casing 12 a and the lower reinforcing body 12 c of the lower structure 12. Has been.

  Reinforcing bodies 11c and 12c according to FIG. 11 are formed by reinforcing work for providing an installation place of the jack apparatus 1 separately from the upper casing 11a and the lower casing 12a while reinforcing the structural bodies 11b and 12b. In the support method according to FIG. 11, the jack device 1 is disposed between the upper reinforcing body 11 c of the upper structure 11 and the lower reinforcing body 12 c of the lower structure 12.

(5) Further, in the support method, when an extremely large earthquake occurs, the jack 2 is jacked down, and the state in which the upper structure 11 is supported by the lower structure 12 with the jack device 1 is released. May be. At this time, when the seismic isolation device 13 is disposed between the upper structure 11 and the lower structure 12, the upper structure 11 is supported by the lower structure 12 by the seismic isolation device 13.

  DESCRIPTION OF SYMBOLS 1 ... Jack apparatus, 2 ... Jack, 2a ... Jack main body, 2b ... Movable body, 2c ... Upper surface part, 2d ... Lower surface part, 3 ... Jack jig unit, 4 ... Upper jig, 4a ... Upper surface part, 4b ... Lower surface portion, 4c ... plane portion, 4d ... curved surface portion, 5 ... lower jig, 5a ... upper surface portion, 5b ... lower surface portion, 5c ... flat surface portion, 5d ... curved surface portion, 10 ... building, 11 ... upper structure, 11a ... Upper housing, 11b ... Structural main body, 11c ... Upper reinforcing body, 12 ... Lower structural body, 12a ... Lower housing, 12b ... Structural main body, 12c ... Lower reinforcing body, 13 ... Seismic isolation device

Claims (7)

A jack disposed between the upper structure and the lower structure separated in the vertical direction;
An upper jig disposed between the upper structure and the jack;
A lower jig disposed between the jack and the lower structure,
The lower surface portion of the upper jig and the upper surface portion of the lower jig are respectively arranged so that the jack can swing when the lower structure is displaced laterally with respect to the upper structure. A jack device provided with a curved surface portion. The upper surface portion and the lower surface portion of the jack are each formed in a planar shape,
The jack device according to claim 1, wherein each of the curved portions is formed into a convex curved surface. The lower surface portion of the upper jig includes a flat surface portion at the center portion that is smaller than the upper surface portion of the jack,
The jack apparatus according to claim 2, wherein the upper surface portion of the lower jig includes a flat surface portion at a central portion that is smaller than the lower surface portion of the jack. The ratio of the width of the planar portion of the upper jig to the height of the jack is smaller than the coefficient of static friction between the upper surface portion of the jack and the planar portion of the upper jig,
The ratio of the width of the flat portion of the lower jig to the height of the jack is smaller than a static friction coefficient between the lower surface portion of the jack and the flat portion of the lower jig. The jack apparatus as described in 2. The upper surface portion of the upper jig is larger than the upper surface portion of the jack,
The jack device according to any one of claims 1 to 4, wherein a lower surface portion of the lower jig is larger than a lower surface portion of the jack. An upper jig disposed between the upper structure and the jack with respect to the jack disposed between the upper structure and the lower structure separated in the vertical direction, the jack and the lower structure A lower jig disposed between,
The lower surface portion of the upper jig and the upper surface portion of the lower jig are respectively arranged so that the jack can swing when the lower structure is displaced laterally with respect to the upper structure. A jack jig unit with a curved surface. The upper structure is supported by the lower structure by disposing at least one jack device according to any one of claims 1 to 5 between the upper structure and the lower structure separated in the vertical direction. Support method.

Images