JP2019035189A - Transfer bridge - Google Patents

Abstract

To provide a transfer bridge capable of preventing water from infiltrating an inner land side.SOLUTION: A transfer bridge 10 includes a floor plate 12, and side walls 13 provided at both side ends of the floor plate 12 and capable of preventing infiltration of water. The transfer bridge is provided with a bridge body 11 having one end rotatably mounted directly or indirectly on a quay 1 and the other end mounted on a floating pier 6, and a watertight part 25 which seals the outside of the side walls 13 and the floor plate 12 at one end part of the bridge body 11.SELECTED DRAWING: Figure 2

Description

  The present application relates to a floating bridge for a floating pier.

  Conventionally, a floating bridge is known that spans between a floating jetty installed in a river or the sea and a quay. For example, the transition bridge disclosed in Patent Document 1 includes a floor board and handrails provided at both ends of the floor board. A shaft portion is provided at the end portion of the floor plate on the quay side, and the end portion of the floor plate on the floating pier side is placed on the floating pier via a roller. The floating pier moves up and down according to the water level of the river and the sea. The crossover bridge rotates around the shaft as the floating bridge moves up and down.

JP-A-8-144219

  By the way, a dyke is installed on the quay to prevent flooding and storm surge. When the above-mentioned transfer bridge is provided on the quay with such a dike, an opening for a person to come and go may be provided on the dike at a position corresponding to the crossover bridge. However, in this case, when flooding occurs, water enters from the opening.

  The technology disclosed in the present application has been made in view of such circumstances, and an object thereof is to provide a bridge that can prevent water from entering the inland side.

  The transit bridge of the present application includes a bridge body and a watertight portion. The bridge body has a floor plate and side walls that are provided at both ends of the floor plate and can prevent water from entering, and one end portion of the bridge body is installed on the quay so as to be directly or indirectly rotatable, and the other end portion. Is placed on the floating pier. The watertight portion watertightly seals the side wall and the outside of the floor board at one end of the bridge body.

  According to the present application, it is possible to provide a bridge that can prevent water from entering the inland side.

FIG. 1 is a diagram illustrating a schematic configuration of a transit bridge according to an embodiment when viewed from the side. FIG. 2 is a diagram illustrating a schematic configuration of the crossover bridge according to the embodiment at the time of flooding as viewed from the side. FIG. 3 is a front view as seen from the quay side in FIG. FIG. 4 is a view corresponding to FIG. 1 and illustrating a normal time of the transfer bridge according to the modification of the embodiment. FIG. 5 is a cross-sectional view seen from the floating pier side in FIG. FIG. 6 is a view corresponding to FIG. 1 and showing a normal time of a crossover according to another embodiment. FIG. 7 is a diagram showing a schematic configuration of a normal transit bridge according to another embodiment when viewed from the side.

  Hereinafter, embodiments of the present application will be described with reference to the drawings. Note that the following embodiments are essentially preferable examples, and are not intended to limit the scope of the technology disclosed in the present application, applications thereof, or uses thereof.

  As shown in FIGS. 1 to 3, the bridge 10 according to this embodiment is a floating bridge for a floating pier that is bridged between a quay 1 and a floating pier 6. The quay 1 is provided with a dike 3 extending along the quay 1. The levee 3 is provided at a position away from the end of the quay 1 by a predetermined distance. The bank 3 is provided with an opening 4 for people to go back and forth. The floating pier 6 is a floating body provided, for example, at a position separated from the quay 1 in a river by a predetermined distance, and rises and falls (moves up and down) according to the water level W of the river.

  The crossover bridge 10 includes a bridge body 11, a watertight side wall 21, a watertight bottom wall 22, and a watertight portion 25.

  The bridge body 11 includes a floor plate 12 and two side walls 13. The floor plate 12 extends from the quay 1 to the floating pier 6. The two side walls 13 are provided on both side ends (both ends in the width direction) of the floor board 12. The side wall 13 is configured to prevent water from entering the floor plate 12 from the outside. The side wall 13 is provided over the longitudinal direction of the floor board 12.

  In the bridge body 11, the end portion of the floor plate 12 on the quay 1 side is a rotation center portion 14. The bridge body 11 is installed on the quay 1 so as to be rotatable around a rotation center portion 14. The position of the rotation center portion 14 is fixed. A roller 15 is provided at the end of the floor board 12 on the floating pier 6 side. The roller 15 is rotatably in contact with the upper surface of the floating pier 6. The bridge body 11 has an end portion on the floating pier 6 side that is movable in the left-right direction in FIG. 1 as the floating pier 6 moves up and down. That is, the bridge body 11 rotates counterclockwise in FIG. 1 when the floating bridge 6 rises, and rotates clockwise in FIG. 1 when the floating bridge 6 descends.

  Two watertight side walls 21 are provided on the quay 1. The watertight side wall 21 is provided so as to extend in the vertical direction from the road surface 2 of the quay wall 1. One water-tight side wall 21 is provided on each side of the bridge body 11 at both ends in the width direction of the opening 4 (both ends in the left-right direction in FIG. 3). The watertight side wall 21 is integrally provided with one side surface in contact with the bank 3. The watertight side wall 21 protrudes from the edge of the quay 1 to the floating pier 6 side.

  The edge of the quay 1 is a step 23 that is lower than the road surface 2, and the end of the bridge body 11 on the quay 1 side is installed on the step 23. That is, the rotation center part 14 of the bridge body 11 is located at the step part 23. And the corner | angular part which steps down from the road surface 2 to the level | step-difference part 23 comprises the bottom wall 22 for watertightness mentioned above. Thus, in the bridge body 11, the end (one end) on the quay 1 side is rotatably installed on the quay 1, and the end (the other end) on the floating pier 6 side is placed on the floating pier 6. ing.

  The watertight part 25 is provided in the bridge body 11. The watertight portion 25 is composed of two side watertight portions 26 and a bottom watertight portion 27, and is a so-called three-way watertight method. One side watertight portion 26 is provided on each of the two side walls 13 in the bridge body 11. The side watertight portion 26 is provided substantially in the height direction at the end portion of the side wall 13 on the quayside 1 side. The side watertight portion 26 is in contact with the watertight side wall 21 to ensure watertightness between the side wall 13 and the watertight side wall 21. The bottom watertight portion 27 is provided across the floor plate 12 and the watertight bottom wall 22 in the bridge body 11. The bottom watertight portion 27 is provided across the width direction at the end of the floor plate 12 on the quay wall 1 side. Thus, by providing the bottom watertight portion 27 in contact with the watertight bottom wall 22, watertightness between the floor plate 12 and the watertight bottom wall 22 is ensured. The two side watertight portions 26 and the bottom watertight portion 27 are connected to each other and constitute one continuous watertight line. The side watertight portion 26 and the bottom watertight portion 27 are made of, for example, watertight rubber.

  In the transfer bridge 10 described above, when the river water level W rises from the normal water level shown in FIG. 1 to the flood water level shown in FIG. 2, the floating bridge 6 rises, and the bridge body 11 rotates counterclockwise accordingly. . When the bridge body 11 rotates, the side watertight portion 26 slides with respect to the watertight side wall 21, and the bottom watertight portion 27 is bent between the floor plate 12 and the watertight bottom wall 22. That is, the watertight portion 25 is always in contact with the watertight side wall 21 and the watertight bottom wall 22. Thus, the bridge main body 11 and the watertight side wall 21 and the watertight bottom wall 22 are watertight, so that it is possible to prevent river water from entering the inland side.

  In addition, as shown in FIG. 2, in the bridge body 11, a part of the side wall 13 is immersed in water, but the side wall 13 prevents water from entering the floor plate 12. Therefore, it can prevent that water flows into the opening 4 through the inside of the bridge main body 11, and it can also prevent that the person who exists in the bridge main body 11 gets wet with water.

  As described above, the bridge 10 according to the embodiment includes the bridge body 11 and the watertight portion 25. The bridge body 11 includes a floor plate 12 and side walls 13 that are provided at both ends of the floor plate 12 and can prevent water from entering, and one end portion (the end portion on the quay 1 side) is rotatable to the quay. The other end (the end on the floating pier 6 side) is placed on the floating pier 6. The watertight part 25 watertights the side wall 13 and the outside of the floor board 12 at one end of the bridge body 11. According to this structure, the outer periphery of the side wall 13 and the floor board 12 can be watertight in the bridge body 11. Therefore, it is possible to prevent river water from entering the inland side through the opening 4 of the bank 3.

  Therefore, according to the transfer bridge 10 of the above embodiment, it is not necessary to prepare a large-scale facility for closing the opening 4 of the embankment 3, and it is not necessary to load a sandbag or the like to close the opening 4.

  Further, the watertight portion 25 has a side watertight portion 26 provided on the side wall 13 and a bottom watertight portion 27 provided on the floor plate 12. In addition, the bridge 10 includes a watertight side wall 21 that ensures watertightness by contacting the side watertight portion 26 and a watertight bottom wall 22 that secures watertightness by contacting the bottom watertight portion 27. . According to this structure, the outer periphery of the side wall 13 and the floor board 12 can be easily watertight with a simple structure.

(Modification of the embodiment)
This modification is obtained by changing the structure of the watertight side wall and the watertight bottom wall in the bridge 10 of the above embodiment. In this modification, one end of the bridge body 11 is indirectly installed on the quay 1 via the deck 7. Here, a different point from the said embodiment is demonstrated.

  As shown in FIGS. 4 and 5, in this modification, a deck 7 is provided on the quay 1. The deck 7 is provided in a state of protruding from the edge of the quay 1, and the protruding end is supported by the support column 8. The road surface 2 of the quay 1 and the upper surface of the deck 7 are flush with each other. The deck 7 extends along the quay 1 and is provided at a certain distance.

  Two watertight side walls 31 and a watertight bottom wall 32 are provided on the upper surface of the deck 7. The watertight bottom wall 32 is provided on the upper surface of the deck 7 so that the position of the end is shifted to the inland side by a predetermined distance from the edge of the deck 7 (end on the floating jetty 6 side). The end of the bridge body 11 on the quay 1 side is installed on the upper surface of the end of the deck 7.

  The two watertight side walls 31 are provided across the quay 1 and the deck 7, and are provided in a state extending vertically from the road surface 2 of the quay 1 and the upper surface of the deck 7. That is, the watertight side wall 31 is provided so as to cross the deck 7. Also in this modification, the water-tight side walls 31 are provided on both sides of the bridge body 11 and at one end in the width direction of the opening 4 (both ends in the left-right direction in FIG. 5). The watertight side wall 31 is provided integrally with one side surface in contact with the levee 3. The watertight side wall 31 protrudes from the edge of the deck 7 toward the floating pier 6 side. In the bridge body 11, an end (one end) on the quay 1 side is rotatably installed on the deck 7, and an end (other end) on the floating pier 6 side is placed on the floating pier 6.

  The two watertight side walls 31 are provided with openings 34 that can be opened and closed at positions corresponding to the decks 7. The opening 34 is for a person passing through the deck 7 to pass through the watertight side wall 31. The opening 34 is closed so as to ensure water tightness. Therefore, it is possible to prevent water from entering from the opening 34.

  As described above, in the above modification, the quay 1 is provided with the deck 7 that extends toward the floating pier 6 and extends along the quay 1. One end of the bridge body 11 (the end on the deck 7 side) is installed on the deck 7. The watertight side wall 31 is provided so as to cross the deck 7 and has a watertight opening 34 at a position corresponding to the deck 7. Accordingly, a person passing through the deck 7 can pass through the watertight side wall 31 while watertight on the outside of the side wall 13.

  In addition, in the said embodiment and modification, although the side wall 13 was provided over the whole longitudinal direction of the floor board 12, the technique disclosed by this application is not restricted to this, Even if the water level W rises, it is immersed in water. You may make it comprise the part which does not have with another member. For example, as shown in FIG. 6, in the case of the bridge 10 of the above embodiment, the region R that is not immersed in water even if the water level W rises is assembled with a pipe or the like instead of the side wall 13 that can prevent water from entering. You may make it comprise a handrail.

  Moreover, you may make it provide the transfer bridge 10 of this application on the existing transfer bridge 100, as shown, for example in FIG. The existing bridge 100 is a plate-like one that is bridged between the quay 1 and the floating pier 6. The existing bridge 100 has a rotation center 101 at the end on the quay 1 side and a roller 102 at the end on the floating pier 6 side. The edge of the quay 1 is a step 103 that is lower than the road surface 2, and the end of the existing crossover 100 on the quay 1 side is rotatably installed on the step 103. The end of the existing transit bridge 100 on the floating pier 6 side is placed on the floating pier 6.

  The transit bridge 10 of the present application is provided above the existing transit bridge 100 provided as described above. The bridge main body 11 of the transfer bridge 10 is rotatably installed at the end of the wharf 1 on the road surface 2 of the wharf 1, and the end of the floating bridge 6 is placed on the upper surface of the existing transfer bridge 100. The roller 15 of the bridge body 11 is in contact with the upper surface of the existing bridge 100 so as to be freely rotatable. That is, the end of the bridge body 11 on the floating pier 6 side is placed on the floating pier 6 via the existing bridge 100. Also in this case, the two watertight side walls 41 are provided on the road surface 2 of the quay 1 as in the above embodiment, and the watertight bottom walls 42 are provided on the road surface 2 of the quay 1 as in the above modification. The functions of the watertight side wall 41 and the watertight bottom wall 42 are the same as those of the above embodiment and the modified example.

  In this embodiment, as the floating pier 6 moves up and down, the existing transit bridge 100 rotates about the rotation center portion 101. As the existing bridge 100 rotates, the bridge body 11 rotates about the rotation center portion 14. Other configurations, operations, and effects are the same as those in the above embodiment.

  Moreover, in the said embodiment, although the edge part (one end part) by the side of the quay 1 of the bridge main body 11 was installed in the level | step-difference part 23 lower than the road surface 2, the technique disclosed by this application is not restricted to this, Bridge. You may make it install the edge part by the side of the quay 1 of the main body 11 in the road surface 2. FIG. In this case, a watertight bottom wall is provided on the road surface 2 as in the above modification.

  As described above, the technology disclosed in the present application is useful for a floating bridge for a floating pier.

DESCRIPTION OF SYMBOLS 1 Quay 6 Floating pier 7 Deck 10 Transition bridge 11 Bridge main body 12 Floor board 13 Side wall 21,31 Watertight side wall 22,32 Watertight bottom wall 25 Watertight part 26 Side watertight part 27 Bottom watertight part 34 Opening

Claims (3)

It has a floor plate and side walls that are provided at both ends of the floor plate and can prevent the ingress of water. One end of the floor plate is installed directly or indirectly on the quay and the other end is mounted on a floating pier. The bridge body,
A crossover bridge characterized in that at one end portion of the bridge body, a watertight portion for watertightly sealing the outside of the side wall and the floorboard is provided. In the crossover bridge according to claim 1,
The watertight portion has a side watertight portion provided on the side wall, and a bottom watertight portion provided on the floor plate,
A crossover bridge comprising: a watertight side wall in which water tightness is ensured by contact with the side watertight part; and a watertight bottom wall in which watertightness is ensured by being in contact with the bottom watertight part. In the transfer bridge according to claim 2,
The quay is provided with a deck extending to the floating pier side and extending along the quay,
One end of the bridge body is installed on the deck,
The crossover bridge is characterized in that the watertight side wall is provided so as to cross the deck, and has a watertight opening at a position corresponding to the deck.

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