JP4556129B2 - Fall bridge prevention device - Google Patents

Description

  The present invention relates to a falling bridge prevention device for preventing a bridge girder from dropping from a support such as a pier or an abutment when an external force is applied to the bridge, for example.

Conventionally, as this kind of falling bridge prevention device, a cable that connects a support body such as an abutment or an abutment and a bridge girder in the direction of the bridge axis is known, and the fall of the pier from the support body is prevented by the cable. (For example, refer to Patent Document 1).
JP 2001-64914 A

  However, in the above-mentioned bridge prevention device, for example, when a large external force is applied to the bridge due to an earthquake, the movement of the bridge girder with respect to the support can be restricted in the direction in which the tensile force is applied to the cable. When moving, for example, when the support and the bridge girder are moved so as to approach the bridge axis direction, the movement cannot be restricted, and the bridge is damaged due to contact between the support and the bridge girder. was there.

  In addition, the cable only connects the support and the bridge girder in the direction of the bridge axis and cannot support the bridge girder in the vertical direction with respect to the support. For example, the cable supports the girder in the vertical direction with respect to the support. Therefore, when a vertical support mechanism provided separately is damaged by an earthquake, the bridge girder moves downward, and adjacent bridge girders are greatly displaced up and down.

  The present invention has been made in view of the above-mentioned problems, and the object of the present invention is to prevent the bridge girder from falling from the support, and by contact between the support and the bridge girder or between the bridge girder. An object of the present invention is to provide a falling bridge prevention device capable of supporting a bridge girder at a predetermined height with respect to a support body without damaging the bridge.

For the present invention, to attain the aforementioned object, by connecting a support for supporting the bridge beam and the bridge girder, the girder prevention device for preventing the falling of the bridge girder from the support, the reinforcing plate and the high damping rubber together a rubber bearing which is formed from a laminated rubber structure formed by laminating alternately in the vertical direction, and the flange plate attached respectively to the upper and lower ends of the rubber bearing is fixed to the bridge girder, the upper end of the flange An upper support member that locks the upper end side flange plate so as to restrict the downward movement of the flange plate on the upper end side and supports the flange plate on the upper end side so as to be movable within a predetermined range in the horizontal direction, and a support The lower end side flange plate is locked to the lower end side flange plate so as to restrict upward movement of the lower end side flange plate, and the lower end side flange is fixed. And a lower support member only for movably supporting a predetermined range of the plate in the horizontal direction.

As a result, the upper support member supports the flange plate on the upper end portion attached to the upper end portion of the rubber bearing so as to be movable within a predetermined range in the horizontal direction, and the lower support member is attached to the lower end portion of the rubber bearing. Since the flange plate on the lower end side is supported so as to be movable within a specified range in the horizontal direction, the flange plate on the upper end side is supported on the upper side for normal bridge girder movement due to temperature, live load, wind, etc. While moving in the horizontal direction with respect to the member, the flange plate on the lower end side moves in the horizontal direction with respect to the lower support member, thereby preventing the strength of the rubber bearing from being lowered due to material fatigue due to repeated deformation. In addition, for example, the bridge girder greatly moves, for example, in the direction perpendicular to the bridge axis with respect to the support body due to an earthquake, and the movement is within the predetermined range of the movement relative to the upper support member of the flange plate on the upper end side, When the predetermined range of the movement relative to the lower support member is exceeded, the rubber bearing undergoes shear deformation, and the movement of the bridge beam relative to the support is restricted within the range of the shear deformation of the rubber support. At this time, the upper support member is locked to the flange plate on the upper end side so as to restrict the downward movement of the flange plate on the upper end side, and the lower support member is attached to the flange plate on the lower end side. Since the flange plate on the lower end side is locked so as to restrict the upward movement of the flange plate, the rubber bearing will be tensile-deformed in response to the upward deformation of the bridge girder relative to the support, and the movement of the bridge girder relative to the support will be It is regulated within the range of tensile deformation. Here, since the rubber bearing is formed of a laminated rubber structure in which reinforcing plates and high damping rubber are alternately laminated in the vertical direction, the kinetic energy of the bridge girder moving relative to the support is transferred to the rubber bearing. It can be greatly attenuated by shear deformation. Furthermore, since the high damping rubber is restrained by each reinforcing plate and the deformation of the rubber bearing in the compression direction is restricted, the rigidity of the rubber bearing in the compression direction can be increased.

According to the present invention, for example, the bridge girder greatly moves, for example, in the direction perpendicular to the bridge axis with respect to the support body due to an earthquake, and the movement is within a predetermined range of the movement with respect to the upper support member of the flange plate on the upper end side or the lower end portion. when exceeding a prescribed range of the movement relative to the lower support member on the side of the flange plate, since the movement of the bridge girder to the support is regulated in the range of shear and tensile deformation of the rubber bearing, bridge beam from supporting lifting member Can be prevented from falling. In addition, since the kinetic energy of the bridge girder that moves relative to the support can be significantly attenuated by the shear deformation of the rubber bearing, the range of movement of the bridge girder relative to the support can be reduced, for example, during an earthquake. The bridge is not damaged by the contact between the bridge girder and the bridge girder. Furthermore, since the rigidity of the rubber bearing in the compression direction can be increased, for example, even if a vertical support mechanism provided separately to support the bridge girder in the vertical direction with respect to the support is damaged by an earthquake, the rubber bearing The bridge girder can be supported at a predetermined height. That is, it is extremely advantageous in that the adjacent bridge girders are not greatly displaced vertically and smooth evacuation from the bridge is possible.
When the bridge girder is constantly moved due to temperature, live load, wind, etc., the flange plate on the upper end moves horizontally with respect to the upper support member, and the flange plate on the lower end moves downward. Since the strength of the rubber bearing is prevented from lowering due to material fatigue due to repeated deformation, the bridge girder is securely restricted by the rubber bearing during an earthquake, etc. The bridge girder can be prevented from falling, the range of movement of the bridge girder relative to the support can be reliably reduced to prevent damage to the support and the bridge girder, and the vertical dimension of the rubber bearing can be reduced. However, since the durability does not decrease, the rubber bearing can be downsized and the manufacturing cost can be reduced.

  1 to 6 show a first embodiment of the present invention. FIG. 1 is a partial sectional view of a bridge in a direction perpendicular to the bridge axis, and FIG. 3 is a cross-sectional view of the fall-off prevention device in the direction of the bridge axis, FIG. 4 is a perspective view of the fall-off prevention device, and FIG. 5 is a cross-sectional view of the bridge in the direction perpendicular to the bridge axis. FIG. 6 is a partial cross-sectional view in a direction perpendicular to the bridge axis of the falling bridge prevention device showing a state where the bridge girder is displaced in the direction perpendicular to the bridge axis with respect to the pier.

  The fallen bridge prevention device of this embodiment includes a sole plate 10 as an upper support member attached to a bridge girder 1, a base plate 20 as a lower support member attached to a bridge pier 2 as a support, and the sole plate 10. The upper collar 30 as the flange plate on the upper end side supported by the upper flange, the lower collar 40 as the flange plate on the lower end side supported by the base plate 20, and the upper collar 30 and the lower collar 40 A rubber bearing 50 is provided.

  The bridge girder 1 is provided with an automobile road on the upper surface and is supported by the pier 2 by two vertical support mechanisms 3 provided so as to be aligned in the direction Y perpendicular to the bridge axis. The vertical support mechanism 3 is made of a well-known laminated rubber structure. The upper surface side is attached to the lower surface of the bridge girder 1 and the lower surface side is attached to the upper surface of the pier 2.

  The sole plate 10 includes a plate 11 attached to the lower surface of the bridge girder 1, a first extending member 12 provided so as to extend downward at both ends of the lower surface of the plate 11 in the direction perpendicular to the bridge axis Y, and A first locking member 13 provided on the lower surface of the first extending member 12, a second extending member 14 provided so as to extend downward at both ends in the bridge axis direction X on the lower surface of the plate 11, Each of the second extending members 14 includes a second locking member 15 provided on the lower surface.

  The plate 11 is disposed between the vertical support mechanisms 3 and is attached to the bridge girder 1 by a plurality of anchor bolts 11a. In addition, when the bridge girder 1 is formed of a steel material, the plate 11 can be attached to the bridge girder 1 by bolts or welding. The plate 11 is made of stainless steel, and is formed in a rectangular plate shape with the bridge axis direction X being the longitudinal direction.

  Each first extending member 12 is formed along both ends of the plate 11 in the direction perpendicular to the bridge axis Y, and is fixed to the plate 11 by welding.

  Each first locking member 13 is formed so as to extend along the lower surface of each first extending member 12, and is formed so as to extend inside the bridge axis perpendicular direction Y in the plate 11. It is fixed to each by welding.

  The extending member 12 and the locking member 13 can be fixed to the plate 11 with bolts inserted from the lower surface side.

  Each second extending member 14 is formed along both ends of the plate 11 in the bridge axis direction X, and is fixed to the plate 11 by welding.

  Each second locking member 15 is formed so as to extend along the lower surface of each second extending member 14, and is formed so as to extend inward in the bridge axis direction X of the plate 11. Each is fixed by welding.

  The extending member 14 and the locking member 15 can be fixed to the plate 11 with bolts inserted from the lower surface side.

  The base plate 20 is formed in the same shape as the sole plate 10 and is attached to the pier 2 such that the direction Y perpendicular to the bridge axis is the longitudinal direction. That is, the base plate 20 includes a plate 21 attached to the upper surface of the pier 2, a first extending member 22 provided to extend upward at both ends of the upper surface of the plate 21 in the direction perpendicular to the bridge axis Y, A first locking member 23 provided on the upper surface of the first extending member 22; a second extending member 24 provided on both ends of the upper surface of the plate 21 in the bridge axis direction X; The second locking member 25 is provided on the upper surface of each second extending member 24.

  The plate 21 is disposed between the vertical support mechanisms 3 and is attached to the pier 2 by a plurality of anchor bolts 21a. In addition, when the pier 2 is formed of a steel material, the plate 21 can be attached to the pier 2 by bolts or welding. The base plate 20 is made of stainless steel and is formed in a rectangular plate shape in which the bridge axis perpendicular direction Y is the longitudinal direction.

  Each first extending member 22 is formed along both ends of the plate 21 in the direction perpendicular to the bridge axis Y, and is fixed to the plate 21 by welding.

  Each first locking member 23 is formed along the upper surface of each first extending member 22, and is formed so as to extend inward in the bridge axis perpendicular direction Y of the plate 21, and each first extending member 22. It is fixed to each by welding.

  The extending member 22 and the locking member 23 can be fixed to the plate 21 with bolts inserted from the upper surface side.

  Each second extending member 24 is formed along both ends of the plate 21 in the bridge axis direction X, and is fixed to the plate 21 by welding.

  Each of the second locking members 25 is formed along the upper surface of each of the second extending members 24, and is formed to extend inward in the bridge axis direction X of the plate 21. Each is fixed by welding.

  The extending member 24 and the locking member 25 can be fixed to the plate 21 with bolts inserted from the upper surface side.

  The upper collar 30 is made of a steel material and is formed in a rectangular plate shape. The width of the upper collar 30 is slightly smaller than the interval between the first extending members 12 of the sole plate 10. Further, the thickness of the upper collar 30 is slightly smaller than the distance between the plate 11 of the sole plate 10 and the locking members 13 and 15. A coating portion 30a made of a fluororesin, which is a low friction resistance material, is provided on the upper surface of the upper collar 30. That is, the upper rod 30 is restricted from moving in the direction perpendicular to the bridge axis Y by engaging each first extending member 12 of the sole plate 10 in the direction perpendicular to the bridge axis Y. Further, the upper collar 30 is locked to the locking members 13 and 15 so that the downward movement is restricted. Further, the upper rod 30 is movable in the bridge axis direction X between the second extending members 14. Moreover, the concave part 30b is provided in the lower surface of the upper collar 30, and the horizontal part of the concave part 30b is formed circularly.

  The lower rod 40 is made of a steel material and is formed in a rectangular plate shape having the same shape as the upper rod 30. The width of the lower collar 40 is slightly smaller than the interval between the second extending members 24 of the base plate 20. Furthermore, the thickness dimension of the lower collar 40 is formed slightly smaller than the distance between the plate 21 of the base plate 20 and the locking members 23 and 25. Further, a coating portion 40a made of a fluororesin, which is a low friction resistance material, is provided on the lower surface of the lower rod 40. That is, the lower rod 40 is restricted from moving in the bridge axis direction X by being engaged with each second extending member 24 of the base plate 20 in the bridge axis direction X. Further, the lower rod 40 is locked to the locking members 23 and 25 so that the upward movement is restricted. Further, the lower rod 40 is movable between the first extending members 22 in the direction Y perpendicular to the bridge axis. Further, a concave portion 40b is provided on the upper surface of the lower collar 40, and the concave portion 40b has a circular cross section in the horizontal direction.

  The rubber bearings 50 are arranged in the vertical direction between the upper reinforcing plate 51 attached to the upper rod 30, the lower reinforcing plate 52 attached to the lower rod 40, and the upper reinforcing plate 51 and the lower reinforcing plate 52. The reinforcing plate 53 includes a plurality of reinforcing plates 53 provided at intervals, and a rubber member 54 that connects the reinforcing plates 51, 52, and 53 by vulcanization adhesion.

  The upper reinforcing plate 51 is made of a steel material, is formed in a rectangular plate shape, and is attached to the upper collar 30 by a plurality of bolts 51a. Further, a concave portion 51b is provided on the upper surface of the upper reinforcing plate 51, and the concave portion 51b has a circular cross section in the horizontal direction. Further, a cylindrical key member 51c is inserted into the concave portion 51b, and an upper end portion of the key member 51c is inserted into the concave portion 30b of the upper collar 30.

  The lower reinforcing plate 52 is made of a steel material, is formed in a rectangular plate shape, and is attached to the lower rod 40 by a plurality of bolts 52b. A concave portion 52b is provided on the lower surface of the lower reinforcing plate 52, and the concave portion 52b has a circular cross section in the horizontal direction. Further, a cylindrical key member 52c is inserted into the concave portion 52b, and a lower end portion of the key member 52c is inserted into the concave portion 40b of the lower collar 40.

  Each reinforcing plate 53 is made of a steel material and is formed in a rectangular plate shape. Each reinforcing plate 53 is formed thinner than the upper reinforcing plate 51 and the lower reinforcing plate 52.

  The rubber member 54 is made of high-damping rubber, is formed so as to cover the reinforcing plates 51, 52, and 53, and is formed in a rectangular parallelepiped whose horizontal cross-sectional shape is rectangular. On the other hand, the upper rod 30 and the lower rod 40 are formed so as to protrude in the bridge axis perpendicular direction Y and the bridge axis direction X from the side surface of the rubber bearing 50. Here, as the high damping rubber, those shown in JP-A-10-219029, JP-A-10-219033, JP-A-2000-336207, JP-A-2002-020546, etc. are used. It is desirable.

  Since the bridge girder 1 is supported by the vertical support mechanisms 3 in the vertical direction, the falling bridge prevention device configured as described above is attached between the bridge girder 1 and the pier 2 with almost no deformation in the compression direction. It is done. Further, the sole plate 10 and the base plate 20 are attached to the bridge girder 1 and the pier 2 so that the rubber support 50 is located at the longitudinal center of the sole plate 10 and the base plate 20.

  Here, when the bridge girder 1 extends in the bridge axis direction X due to temperature or a live load, the bridge girder 1 moves in the bridge axis direction X with respect to the pier 2 and each vertical support mechanism 3 is sheared and deformed. Since the flange 30 is provided on the sole plate 10 so as to be movable in the bridge axis direction X, the rubber bearing 50 is not shear-deformed. Further, since the coating portion 30 a is provided on the upper surface of the upper collar 30, the upper collar 30 moves smoothly with respect to the sole plate 10.

  Further, when a force in the direction perpendicular to the bridge axis Y is applied to the bridge girder 1 by wind or the like, the bridge girder 1 moves in the direction perpendicular to the bridge axis Y with respect to the pier 2 and each vertical support mechanism 3 is sheared and deformed. Since the flange 40 is provided on the base plate 20 so as to be movable in the direction Y perpendicular to the bridge axis, the rubber bearing 50 does not undergo shear deformation. Further, since the coating portion 40 a is provided on the lower surface of the lower collar 40, the lower collar 40 moves smoothly with respect to the base plate 20. That is, the rubber bearing 50 is not sheared by the movement of the bridge girder 1 constantly due to temperature, live load, wind, etc., and the strength of the rubber bearing 50 is not reduced by material fatigue due to repeated deformation.

  Next, even if each vertical support mechanism 3 is damaged beyond the allowable range of shear deformation due to the bridge girder 1 greatly moving in the direction perpendicular to the bridge axis Y with respect to the pier 2 due to the earthquake, the lower bar 40 is fixed to the base plate. The rubber bearing 50 is sheared and deformed by being engaged with the first extending member 22 of the 20, and the movement of the bridge girder 1 relative to the pier 2 is restricted within the range of the shear deformation of the rubber bearing 50. At this time, the upper rod 30 is restricted from moving downward by the locking members 13 and 15 of the sole plate 10, and the lower rod 40 is restricted from moving upward by the locking members 23 and 25 of the base plate 20. Therefore, the rubber bearing 50 is tensilely deformed even when the bridge girder 1 is moved upward with respect to the pier 2, and the movement of the bridge girder 1 with respect to the pier 2 is restricted within the range of the tensile deformation of the rubber bearing 50. Even if each vertical support mechanism 3 is damaged by the bridge girder 1 largely moving in the bridge axis direction X with respect to the pier 2 due to the earthquake, the upper rod 30 is attached to the second extending member 14 of the sole plate 10. Locks and produces the same actions and effects as described above.

  Here, since the rubber member 54 constituting the rubber bearing 50 is made of high damping rubber, the kinetic energy of the bridge girder 1 moving relative to the pier 2 can be greatly attenuated by the shear deformation of the rubber bearing 50. . Further, since the rubber member 54 is constrained in the horizontal direction by the reinforcing plates 51, 52, 53, the rigidity of the rubber bearing 50 in the compression direction is increased, and even if each vertical support mechanism 3 is damaged, the rubber bearing 50 50 allows the bridge girder 1 to be supported at a predetermined height.

  Thus, according to the present embodiment, the upper surface side is attached to the bridge girder 1 side and the lower surface side is attached to the pier 2 side, thereby providing the rubber bearing 50 for connecting the bridge girder 1 and the pier 2 and However, even if each vertical support mechanism 3 is damaged with respect to the pier 2, the movement of the bridge girder 1 with respect to the pier 2 is restricted within the range of shear deformation and tensile deformation of the rubber bearing 50. The bridge girder 1 can be prevented from dropping from the pier 2.

  Further, since the rubber member 54 constituting the rubber bearing 50 is made of high damping rubber, the kinetic energy of the bridge girder 1 moving with respect to the pier 2 can be greatly attenuated by the shear deformation of the rubber bearing 50, so that the earthquake At this time, the range of movement of the bridge girder 1 relative to the pier 2 can be reduced, and the bridge girder 1 and the pier 2 are not damaged by contact between the pier 2 and the bridge girder 1 or between the bridge girders 1.

  Furthermore, since the rubber member 54 is restrained in the horizontal direction by the reinforcing plates 51, 52, 53, the rigidity in the compression direction of the rubber bearing 50 can be increased, and even when each vertical support mechanism 3 is damaged. The bridge girder 1 can be supported at a predetermined height by the rubber bearing 50. That is, it is extremely advantageous in that the adjacent bridge girders 1 are not greatly displaced vertically and smooth evacuation from the bridge girder 1 is possible.

  The upper rod 30 is supported on the sole plate 10 so as to be movable in the bridge axis direction X, and the lower rod 40 is supported on the base plate 20 so as to be movable in the direction perpendicular to the bridge axis Y. Since the rubber bearing 50 is not sheared by the movement of the bridge girder 1 and the strength of the rubber bearing 50 is not reduced by material fatigue due to repeated deformation, the rubber girder 50 ensures the bridge girder 1 in the event of an earthquake. It is possible to prevent the bridge girder 1 from falling from the pier 2 by restricting the movement, and to reliably reduce the movement range of the bridge girder 1 with respect to the pier 2 to prevent damage to the pier 2 and the bridge girder 1.

  Further, since the rubber bearing 50 is not sheared by the movement of the bridge girder 1 at all times, the durability is not lowered even if the vertical dimension of the rubber bearing 50 is reduced. Manufacturing costs can be reduced.

  In addition, a coating portion 30 a is provided on the upper surface of the upper collar 30, and a coating portion 40 a is provided on the lower surface of the lower collar 40 so that the upper collar 30 and the lower collar 40 move smoothly with respect to the sole plate 10 and the base plate 20. Therefore, the shear deformation of the rubber bearing 50 due to the constant movement of the bridge girder 1 due to temperature, live load, wind, etc. can be reliably prevented.

  In this embodiment, the upper rod 30 is provided so as to be movable in the bridge axis direction X with respect to the sole plate 10, and the lower rod 40 is provided so as to be movable in the bridge axis perpendicular direction Y with respect to the base plate 20. Although shown, the upper rod 30 can be provided so as to be movable in the bridge axis perpendicular direction Y with respect to the sole plate 10, and the lower rod 40 can be provided so as to be movable in the bridge axis direction X with respect to the base plate 20.

  In the present embodiment, the falling bridge prevention device is provided between the bridge girder 1 and the bridge pier 2. However, the falling bridge prevention device can be provided between the bridge girder 1 and an abutment (not shown).

  FIG. 7 is a cross-sectional view in the direction perpendicular to the bridge axis of the fallen bridge prevention device showing the second embodiment of the present invention. In addition, the same code | symbol is attached | subjected and shown to the component equivalent to 1st Embodiment.

  The falling bridge prevention device of this embodiment is a modification of the sole plate 10, the base plate 20, the upper rod 30 and the lower rod 40 in the falling bridge prevention device of the first embodiment, and has the following configuration.

  The sole plate 60 includes a disk-shaped plate 61 attached to the lower surface of the bridge girder 1, an extending member 62 provided to extend downward on the outer peripheral portion of the lower surface of the plate 61, and a lower surface of the extending member 62. The locking member 63 is provided.

  The extending member 62 is formed along the entire periphery of the outer periphery of the plate 61 and is fixed to the plate 61 by welding.

  The locking member 63 is formed along the lower surface of the extending member 62 and is formed to extend radially inward of the plate 61 and is fixed to the extending member 62 by welding.

  The base plate 70 is formed in the same shape as the sole plate 60, and a disk-shaped plate 71 attached to the upper surface of the pier 2, and an extending member 72 provided so as to extend upward on the outer peripheral portion of the upper surface of the plate 71. And a locking member 73 provided on the upper surface of the extending member 72.

  The extending member 72 is formed along the entire periphery of the outer periphery of the plate 71 and is fixed to the plate 71 by welding.

  The locking member 73 is formed along the upper surface of the extending member 72 and is formed to extend radially inward of the plate 71 and is fixed to the extending member 72 by welding.

  The upper collar 80 is formed in a disk shape having an outer diameter smaller than the inner peripheral surface of the extending member 62 of the sole plate 60 and having an outer shape larger than the inner peripheral surface of the locking member 63. The thickness of the upper collar 80 is slightly smaller than the distance between the plate 61 of the sole plate 60 and the locking member 63. Further, a coating portion 80a made of a fluororesin, which is a low friction resistance material, is provided on the upper surface of the upper collar 80. That is, the upper collar 80 is movable in the horizontal direction with respect to the sole plate 60 within a range where the upper collar 80 is not locked to the extending member 62. Further, the upper collar 80 is locked to the locking member 63 so that the downward movement is restricted. Further, a concave portion 80b is provided on the lower surface of the upper collar 80, and the concave portion 80b has a circular cross section in the horizontal direction.

  The lower collar 90 is formed in a disk shape having an outer diameter smaller than the inner peripheral surface of the extending member 72 of the base plate 70 and having an outer shape larger than the inner peripheral surface of the locking member 73. The thickness of the lower collar 90 is slightly smaller than the distance between the plate 71 of the base plate 70 and the locking member 73. Furthermore, a coating part 90a made of a fluororesin that is a low friction resistance material is provided on the lower surface of the lower rod 90. In other words, the lower collar 90 is movable in the horizontal direction with respect to the base plate 70 within a range not being locked to the extending member 72. Further, the lower hook 90 is locked to the locking member 73, so that the upward movement is restricted. Further, a concave portion 90b is provided on the lower surface of the lower collar 90, and the concave portion 90b has a circular cross section in the horizontal direction.

  In the above configuration, the upper collar 80 is supported to be movable in the horizontal direction with respect to the sole plate 60, and the lower collar 90 is supported to be movable in the horizontal direction with respect to the base plate 70. When the bridge girder 1 is constantly moved by a load, wind, or the like, the upper rod 80 moves in the horizontal direction with respect to the sole plate 60 and the lower rod 90 moves in the horizontal direction with respect to the base plate 70. The rubber bearing 50 does not undergo shear deformation. Thereby, the strength of the rubber bearing 50 is not reduced due to material fatigue due to repeated deformation, and the bridge girder 1 is reliably moved by the rubber bearing 50 in the event of an earthquake to prevent the bridge girder 1 from dropping from the pier 2. In addition, the range of movement of the bridge girder 1 relative to the pier 2 can be reliably reduced to prevent damage to the pier 2 and the bridge girder 1.

  Further, since the rubber bearing 50 is not shear-deformed by the movement of the bridge girder 1 at all times, even if the vertical dimension of the rubber bearing 50 is reduced, the durability is not lowered. Manufacturing costs can be reduced.

  FIG. 8 is a cross-sectional view in the direction perpendicular to the bridge axis of the falling bridge prevention device showing the third embodiment of the present invention. In addition, the same code | symbol is attached | subjected and shown to the component equivalent to 2nd Embodiment.

  The falling bridge prevention device of this embodiment is a modification of the base plate 70 and the lower rod 90 in the falling bridge prevention device of the second embodiment, and has the following configuration.

  The base plate 100 is formed in a rectangular plate shape, and is attached to the pier 2 by anchor bolts 100a. The lower collar 110 is formed in a rectangular plate shape smaller than the base plate 100, and is attached to the base plate 100 by a plurality of bolts 110a. That is, the lower end portion of the rubber bearing 50 is attached so as not to move in the horizontal direction with respect to the pier 2, and the upper rod 80 provided at the upper end portion of the rubber bearing 50 is movable in the horizontal direction with respect to the sole plate 60. It has become.

  In the above configuration, when the bridge girder 1 is constantly moved by air temperature, live load, wind, etc., the upper collar 80 moves in the horizontal direction with respect to the sole plate 60, so that the rubber bearing 50 is sheared and deformed. There is nothing. Thereby, since the strength of the rubber bearing 50 does not decrease due to material fatigue due to repeated deformation, the bridge girder 1 is reliably restricted by the rubber bearing 50 in the event of an earthquake to prevent the bridge girder 1 from dropping from the pier 2. In addition, the range of movement of the bridge girder 1 relative to the pier 2 can be reliably reduced to prevent damage to the pier 2 and the bridge girder 1.

  Further, since the rubber bearing 50 is not shear-deformed by the movement of the bridge girder 1 at all times, even if the vertical dimension of the rubber bearing 50 is reduced, the durability is not lowered. Manufacturing costs can be reduced.

  In the present embodiment, the lower end portion of the rubber bearing 50 is attached so as not to move in the horizontal direction with respect to the pier 2, and the upper rod 80 provided at the upper end portion of the rubber bearing 50 is horizontal with respect to the sole plate 60. Although the upper end of the rubber bearing 50 is mounted so as not to move in the horizontal direction with respect to the bridge girder 1, the lower rod 110 provided at the lower end of the rubber bearing 50 is attached to the base plate. It is also possible to provide it so as to be movable in the horizontal direction with respect to 100.

  In addition, since the fall prevention apparatus of the 1st thru | or 3rd embodiment can be installed in a bridge by attaching sole plate 10, 60 to bridge girder 1 and attaching base plate 20, 70, 100 to bridge pier 2, It can be easily attached to existing bridges, which is extremely advantageous in taking bridge safety measures.

Partial sectional view in the direction perpendicular to the bridge axis of the bridge showing the first embodiment of the present invention Cross-sectional view of the falling bridge prevention device in the direction perpendicular to the bridge axis Cross-sectional view in the direction of the bridge axis of the falling bridge prevention device Perspective view of the fallen bridge prevention device Partial cross-sectional view of the bridge in the direction perpendicular to the bridge axis showing the state where the bridge girder is displaced in the direction perpendicular to the bridge axis with respect to the pier Partial cross-sectional view in the direction perpendicular to the bridge axis showing the state where the bridge girder is shifted in the direction perpendicular to the bridge axis with respect to the pier Sectional drawing in the bridge-axis perpendicular direction of the fall-bridge prevention apparatus which shows 2nd Embodiment in this invention Sectional drawing in the bridge-axis perpendicular direction of the falling-bridge prevention apparatus which shows 3rd Embodiment in this invention

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Bridge girder, 2 ... Bridge pier, 3 ... Vertical direction support mechanism, 10 ... Sole plate, 11 ... Plate, 12 ... 1st extending member, 13 ... 1st locking member, 14 ... 2nd extending member, 15 ... 2nd locking member, 20 ... base plate, 21 ... plate, 22 ... first extending member, 23 ... first locking member, 24 ... second extending member, 25 ... second locking member, 30 ... upper arm , 30a ... coating portion, 40 ... lower collar, 40a ... coating portion, 50 ... rubber support, 51 ... upper reinforcement plate, 52 ... lower reinforcement plate, 53 ... reinforcement plate, 54 ... rubber member, 60 ... sole plate, 61 ... Plate, 62 ... Extension member, 63 ... Locking member, 70 ... Base plate, 71 ... Plate, 72 ... Extension member, 73 ... Locking member, 80 ... Upper collar, 80a ... Coating part, 90 ... Lower collar, 90a ... coating part, 100 ... base plate 110 ... lower shoe, X ... bridge axis direction, Y ... bridge axis perpendicular direction.

Claims (3)

By connecting the bridge girder and the support body that supports the bridge girder, in the falling bridge prevention device that prevents the bridge girder from falling from the support body,
A rubber bearing formed from a laminated rubber structure in which reinforcing plates and high damping rubber are alternately laminated in the vertical direction ;
Flange plates respectively attached to the upper end and lower end of the rubber bearing ;
It is fixed to the bridge girder, and is locked to the flange plate on the upper end side so as to restrict the downward movement of the flange plate on the upper end side, and the flange plate on the upper end side is moved by a predetermined range in the horizontal direction. An upper support member that supports it;
The lower end side flange plate is fixed to a support body so as to restrict the upward movement of the lower end side flange plate, and the lower end side flange plate is horizontally moved within a predetermined range. A falling bridge prevention device comprising a lower support member that is movably supported . The upper support member is supported so that the flange plate on the upper end side is movable within a predetermined range in one of the bridge axis direction and the direction perpendicular to the bridge axis, and the bridge axis direction of the flange plate on the upper end side and the bridge It is formed so as to restrict movement in the other direction out of the direction perpendicular to the axis,
The lower support member supports the lower end flange plate movably in the other direction of the bridge axis direction and the bridge axis perpendicular direction, and the bridge axis direction and the bridge axis right angle of the lower end side flange plate. girder prevention device according to claim 1, wherein the formed so as to restrict the movement of the one direction of the direction. The fallen bridge prevention device according to claim 1 or 2 , wherein at least one of the contact surfaces in a vertical direction between the flange plate and the support member is made of a low friction resistance material.

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