JP2018178400A - Erectable gate - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simplify a structure of an erectable gate.SOLUTION: A torsion coil spring 31 of an erectable gate 1 is positioned at an underside of an upper surface of a door 2 in a flattened attitude. The torsion coil spring 31 is provided with a coil part 32, a first arm 33, and a second arm 34. In the coil part 32, a spring member is spirally wounded around a central axis J2 as a center oriented toward a width direction of the door 2. The first arm 33 is projected from the coil part 32. A tip of the first arm 33 is connected to a floor surface 91. The second arm 34 is projected form the coil part 32. A tip of the second arm 34 is connected to the door 2. When the door 2 is in the flattened attitude in the erectable gate 1, the door 2 is biased with a flattening moment through resilient force of the torsion coil spring 31. Also, when the door 2 is in a maximum erected attitude, the door 2 is biased with a flattening moment through resilient force of the torsion coil spring 31. Thus, a structure of the erectable gate 1 can be simplified.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a relief gate which stands up when water flows from an opening and shields the opening.

  Conventionally, in order to prevent the entry of water into a building or the like at the time of flood damage, a waterproof door which is undulated via a hinge is provided at the entrance of the building or the like. Patent Document 1 proposes a standup assisting device for applying a standup moment to a waterproof door by a torsion coil spring fixed to a floor surface in a relief gate in which a worker manually lifts and lowers. One arm of the torsion coil spring in the natural state extends horizontally along the floor surface and is fixed to the floor surface, and the other arm extends upward. Then, a roller is provided at the tip of the other arm, and the roller is in contact with the lower surface of the waterproof door. When the waterproof door falls down, the torsion coil spring is compressed, and an erecting moment is applied to the waterproof door from the torsion coil spring. In addition, when the attitude of the waterproof door is changed, the contact between the tip of the other arm and the waterproof door moves in the longitudinal direction of the waterproof door, but since the contact is provided with a roller, The movement is smooth.

  Also in Patent Document 2, a rising assist device is proposed in which a twisting coil spring fixed to a floor surface applies a rising moment to a waterproof door in an undulating gate in which a worker manually undulates. In the stand-up assisting device, the torsion coil spring is not used until the waterproof door in the reclining posture stands up to a predetermined angle, and the gas damper applies a stand-up moment to the waterproof door. Then, when the waterproof door stands up more than a predetermined angle, the application of the standing moment by the gas damper is stopped, and the standing moment is applied to the waterproof door by the torsion coil spring.

  Patent Document 3 proposes a technology for applying a rising moment to a waterproof door by a torsion coil spring fixed to a floor surface in a relief gate which is raised and lowered by an electric motor. The tip of one arm of the torsion coil spring is fixed to the floor, and the tip of the other arm is fixed to the door body.

  On the other hand, in a floating relief gate provided at an opening of a seawall or the like, when the water increases due to a tsunami or the like, the pressure of the water flowing in from the opening causes the door to stand up and shield the opening. By the way, since the water pressure acting on the relief gate is relatively small at the early stage of the inflow of water, the rising operation of the relief gate is relatively gentle. In addition, when the water level drops after the increase of the water level, the falling gate does not start to fall until the water level drops to some extent, and then it may fall rapidly.

  Therefore, in the floating flap gate of Patent Document 4, a technique for attaching a counterweight to the door body in order to promote the standing of the door body in the lying posture and to promote the start of the fall of the door body in the standing posture when the water level drops. Has been proposed.

JP 10-238240 A JP, 2006-83595, A JP 2007-170112 A JP, 2015-180806, A

  By the way, there exist some which a vehicle etc. pass on the door body of a fall posture at the time except the time of a water rise in the undulation gate provided in a seawall etc. In such a relief gate, it is necessary to increase the strength of the door, which increases the weight of the door. Therefore, if it is going to apply the structure of patent document 4, the weight of a counterweight will increase. As a result, the span length of the door is limited, or the thickness of the door is increased to secure the cross section of the front end of the door.

  On the other hand, in the standup assisting devices of Patent Documents 1 to 3, a standup moment is always applied to the waterproof door regardless of the attitude of the waterproof door. For this reason, when making the waterproof door of a standing-up posture a fall posture, it is necessary to apply big power to a waterproof door. Therefore, it is difficult to apply the structures of Patent Documents 1 to 3 to the floating flap gate as described above, which preferably promotes the start of the fall of the door in the standing posture when the water level drops.

  The present invention has been made in view of the above problems, and aims to simplify the structure of the undulating gate.

  The invention according to claim 1 is an undulating gate provided in an opening and standing up when water flows in from the opening to shield the opening, wherein the movable end is in a falling posture from the support end. Also, the door is located on the front side where water flows in, and is pivoted about the support end to change the posture between the laid posture and the maximum standing posture, and the laid posture And a relief assisting portion including a torsion coil spring disposed below the upper surface of the door body, wherein the torsion coil spring spirally winds a spring material around a central axis facing the width direction of the door body. The coil portion, the first arm projecting from the coil portion, the distal end portion being connected to the floor surface, and the second arm projecting from the coil portion and the distal end portion being connected to the door body, In the state where the door is in the fallen posture, By the restoring force of Jiri coil spring the door body upright moment is applied to, in a state wherein the door body is in the maximum upright position, laid down moment is applied to the door body by the restoring force of the torsion coil spring.

  The invention according to claim 2 is the relief gate according to claim 1, wherein the torsion coil spring is disposed on the front side with respect to the support end, and the door is in the reclining posture. The first arm and the second arm extend from the coil portion to the front side, and an angle formed by the first arm and the second arm is smaller than a free angle, and the door body is in the maximum standing posture In the state, the first arm extends from the coil portion to the front side, the second arm extends upward from the coil portion, and the angle formed between the first arm and the second arm is Greater than free angle.

  The invention according to claim 3 is the relief gate according to claim 2, wherein the second arm and the extension line to the front side of the second arm is a state in which the door body is in the laid posture. The same position as the first arm above or in the same vertical direction as the first arm over the entire length ranging from the first connection portion which is the connection portion between the first arm and the floor surface to the coil portion Located in

  The invention according to claim 4 is the relief gate according to claim 2, wherein the extension line to the front side of the second arm or the second arm is a state in which the door body is in the reclining posture. And intersect with the first arm in a side view facing the width direction.

  The invention according to claim 5 is the relief gate according to any one of claims 2 to 4, wherein the door body is between the first arm and the second arm in the width direction. It has a buoyancy part located.

  The invention according to claim 6 is the relief gate according to any one of claims 2 to 5, wherein the tip end of the first arm and the tip end of the second arm are connected. It further comprises a strap-like or strip-like standing restriction member, and the standing restriction member extends linearly when the door is in the maximum standing posture.

  The invention according to claim 7 is the relief gate according to claim 1, wherein the torsion coil spring is disposed rearward of the fulcrum and the door is in the reclining posture. One arm extends downward from the coil portion, the second arm extends rearward from the coil portion, and an angle between the first arm and the second arm is larger than a free angle, In the state where the door is in the maximum standing posture, the first arm and the second arm extend downward from the coil portion, and the angle between the first arm and the second arm is a free angle. Less than.

  The invention according to claim 8 is the relief gate according to any one of claims 1 to 7, wherein the coil portion is not fixed to the floor surface and the door, and the door With the posture change of the body, the relative position of the coil portion to the floor surface and the door is changed.

  The invention according to claim 9 is the relief gate according to any one of claims 1 to 8, wherein a counterweight, the counterweight, and the movable end of the door are connected to each other. A connection member for suspending a counterweight is further provided, and in a state in which the door is in the reclining posture, an erecting moment is applied to the door by the counterweight, and in a state in which the door is in the maximum erecting posture A fall moment is applied to the door by the counterweight.

  In the present invention, the structure of the relief gate can be simplified.

It is a side view of a relief gate concerning a 1st embodiment. It is a top view of a relief gate. It is a front view of a relief gate. It is a perspective view of a torsion coil spring. It is a side view of a relief gate. It is a side view of a relief gate. It is a side view of a relief gate. It is a side view of a relief gate. It is a side view of a relief gate. It is a figure which shows the relationship between the attitude | position of a door, and the moment which acts on a door. It is a side view which shows the other example of a relief gate. It is a perspective view of a torsion coil spring. It is a side view which shows the other example of a relief gate. It is a side view which shows the other example of a relief gate. It is a side view which shows the other example of a relief gate. It is a side view which shows the other example of a relief gate. It is a side view which shows the other example of a relief gate. It is a side view which shows the other example of a relief gate. It is a side view which shows the other example of a relief gate. It is a side view of a relief gate concerning a 2nd embodiment. It is a top view of a relief gate. It is a front view of a relief gate. It is a side view of a relief gate. It is a side view of a relief gate. It is a side view of a relief gate. It is a side view of a relief gate. It is a side view of a relief gate. It is a side view of a relief gate concerning a 3rd embodiment.

  FIG. 1 is a side view showing a relief gate 1 according to a first embodiment of the present invention. FIG. 2 is a plan view showing the relief gate 1. FIG. 3 is a front view of the relief gate 1 as viewed from the front. The relief gate 1 is a floating relief gate. The relief gate 1 is provided, for example, on the floor surface 91 (for example, road surface) at the opening 92 of the dike. The undulation gate 1 stands up by the pressure of the inflowing water when the water flows in from the opening 92 due to the increase in water and shields the opening 92 so that the water flows into the living space etc. from the opening 92 Suppress. In the example shown in FIG. 1, the floor surface 91 extends substantially horizontally (that is, substantially perpendicular to the direction of gravity).

  In the following description, the side on which the water flows in at the time of water increase in the undulation gate 1 (that is, the upstream side of the inflow direction of water, for example, the waterside such as the sea or river rather than the undulation gate 1) The downstream side of the inflow direction of water in the relief gate 1 (for example, the land side of the relief gate 1) is referred to as the “rear side”. That is, the left-right direction in FIGS. 1 and 2 is the “front-back direction”, and the left and right sides in FIGS. 1 and 2 are the “front side” and the “rear side”, respectively. Further, the vertical direction in FIG. 2 and the horizontal direction in FIG. 3 are referred to as “width direction”. The width direction is perpendicular to the longitudinal direction, and the longitudinal direction and the width direction are perpendicular to the vertical direction. The vertical direction in FIGS. 1 and 3 is substantially parallel to the gravity direction.

  The relief gate 1 includes a door 2, a pair of door stops 11, and a relief assisting portion 3. The door 2 illustrated in FIGS. 1 to 3 is a substantially rectangular parallelepiped member that extends in the front-rear direction and the width direction. FIGS. 1 to 3 show the door 2 lying on the floor surface 91. In the following description, the posture of the door 2 shown by a solid line in FIG. 1 will be referred to as a "falling posture". The door 2 in the lying position is accommodated in the recess 93 provided in the floor surface 91. The recess 93 is slightly larger than the door 2 in the lying posture in plan view.

  The position in the vertical direction of the upper surface (hereinafter, referred to as "first main surface 21") of the door 2 in the lying posture is substantially the same as the position in the vertical direction of the floor surface 91 around the recess 93. For example, a vehicle or the like can pass on the first main surface 21 of the door 2 in the lying position. The lower surface (hereinafter, referred to as “second main surface 22”) of the door 2 in the lying posture is in contact with or in proximity to the bottom surface of the recess 93 of the floor surface 91. When the plate member (that is, the plate member extending in the front-rear direction and the width direction) is not provided at the lower end of the door 2 in the lying posture, the second main surface 22 of the door 2 extends downward from the first main surface 21. Means the lower end face of the extending girder member etc. In the example shown in FIG. 1, the bottom surface of the recess 93 which is a part of the floor surface 91 also extends substantially horizontally.

  The rear end portion 23 of the door 2 in the lying posture is rotatably attached to the floor surface 91 at the rear end portion of the recess 93 and is supported by the floor surface 91. In the following description, the rear end 23 of the door 2 in the fallen posture is referred to as a "support end 23". Further, the front end portion 24 of the door 2 in the fallen posture is referred to as a "movable end portion 24". That is, in the door 2 in the reclining posture, the movable end 24 is located on the front side of the support end 23. In the following description, the direction perpendicular to the width direction and connecting the supporting end 23 of the door 2 and the movable end 24 is referred to as the “longitudinal direction” of the door 2. In the door 2 in the fallen posture, the longitudinal direction of the door 2 is the same as the front-rear direction.

  The movable end 24 is separated upward from the floor surface 91 by pivoting the door 2 clockwise in FIG. 1 about the rotation axis J1 extending substantially in parallel in the width direction at the support end 23. Stand up. The rotation axis J1 is located in the vicinity of the rear end edge of the first main surface 21 of the door 2. In the example shown in FIG. 1, as shown by the two-dot chain line, the door 2 can stand up to an angle of about 75 degrees with the floor surface 91. In the following description, the posture of the door 2 shown by the two-dot chain line in FIG. 1 is referred to as the “maximum standing posture”. In the rising and lowering gate 1, the door 2 changes its posture between the laid posture and the maximum standing posture by rotating around the support end portion 23 as a fulcrum. In addition, the angle which the door 2 of the largest standing posture and the floor surface 91 comprise may be suitably set in the range larger than 0 degree and 90 degrees or less.

  The pair of door stops 11 is disposed on both sides in the width direction of the door 2. In FIG. 1, illustration of the door stop 11 on the front side of the door 2 is omitted. As shown in FIG. 3, the space between the pair of door stops 11 is the opening 92 described above. The door stop unit 11 is, for example, a substantially plate-like structure. For example, a sea wall is provided on the widthwise outside of the pair of door stops 11. The pair of door stops 11 is fixed to the seawall.

  The side surface of the door 2 is in contact with the door contact surface 111 which is the side surface on the inner side in the width direction of the door stopper 11. Specifically, on the side surfaces on both sides in the width direction of the door 2, seal members (for example, water-tight rubber, not shown) are provided over substantially the entire length of the door 2 in the longitudinal direction. The door 2 contacts the door contact surface 111 of the door stopper 11 via the seal member. The space between the door 2 and the door stopper 11 is sealed in a watertight manner by the sealing member. In the undulating gate 1, regardless of the attitude of the door 2, the side surface of the door 2 is in contact with the door contact surface 111, and the water tightness between the door 2 and the door stopper 11 is maintained.

  The door 2 includes a plurality of stringers 27 extending substantially in parallel in the longitudinal direction between the first major surface 21 and the second major surface 22. Each longitudinal girder 27 extends over substantially the entire length between the support end 23 and the movable end 24 of the door 2. The plurality of stringers 27 are arranged in the width direction while being separated from one another. In the example shown in FIGS. 2 and 3, six stringers 27 are provided on the door 2. The space under the first main surface 21 in the door 2 in the fallen posture is divided into seven spaces 201 arranged in the width direction by the six longitudinal beams 27. In the following description, the space 201 is referred to as a “division space 201”. Each divided space 201 is a substantially rectangular space.

  The relief assisting portion 3 includes a torsion coil spring 31. In the example shown in FIGS. 2 and 3, the relief assisting portion 3 includes six torsion coil springs 31. Each torsion coil spring 31 is disposed on the front side of the support end 23 of the door 2 and below the first main surface 21 of the door 2 in the lying posture. In FIG. 2 and FIG. 3, in order to facilitate understanding of the shape of the torsion coil spring 31, the torsion coil spring 31 located below the first main surface 21 is drawn by a thin solid line (the same applies to FIG. 21 and FIG. ). The six torsion coil springs 31 are arranged in the width direction while being separated from each other at substantially the same position in the front-rear direction. The six torsion coil springs 31 have substantially the same structure. The number of torsion coil springs 31 included in the relief portion 3 may be changed as appropriate. The number of torsion coil springs 31 may be, for example, one or two or more.

  The torsion coil spring 31 is disposed between the longitudinal beams 27 of the door 2 in the reclining posture. In the example illustrated in FIG. 3, the torsion coil spring 31 is disposed in the first, third, fifth, and seventh divided spaces 201 from the left side in the drawing. That is, the torsion coil spring 31 is disposed inside the door 2 in the lying posture. Two torsion coil springs 31 are disposed in the third and fifth divided spaces 201 from the left in FIG. A plate member is not provided on the second principal surface 22 side of the divided space 201 in which the torsion coil spring 31 is disposed, and the plate member opens downward in FIG. 3.

  The divided space 201 in which the torsion coil spring 31 is not disposed (that is, the second, fourth, and sixth divided spaces 201 from the left side in FIG. 3) is used as, for example, a buoyant portion. The buoyant portion includes, for example, a buoyant body such as a foamed resin disposed in the space between the first major surface 21 and the second major surface 22. In addition, the buoyant portion may include a watertight space provided between the first major surface 21 and the second major surface 22.

  FIG. 4 is a perspective view showing one torsion coil spring 31 in an enlarged manner. In FIG. 4, the rightmost torsion coil spring 31 in FIG. 3 is depicted. Moreover, in FIG. 4, the structure around the torsion coil spring 31 is also drawn. The torsion coil spring 31 includes a coil portion 32, a first arm 33, and a second arm 34. The coil portion 32 is a substantially cylindrical portion centered on a central axis J2 facing in the width direction of the door 2. In the coil portion 32, a spring material is spirally wound around a central axis J2 substantially parallel to the width direction.

  The first arm 33 and the second arm 34 respectively project from the coil portion 32. Each of the first arm 33 and the second arm 34 extends from the coil portion 32 to the front side when the door 2 is in the reclining position. In the example shown in FIG. 4, the first arm 33 extends forward from the lower portion of the coil portion 32, and the second arm 34 extends forward from the upper portion of the coil portion 32. In a side view facing in the width direction, the first arm 33 and the second arm 34 extend substantially tangentially from the coil portion 32. The length of the first arm 33 and the length of the second arm 34 are substantially the same.

  The tip of the first arm 33 is bent at a substantially right angle, and extends away from the coil portion 32 in the width direction. The tip of the first arm 33 is inserted into the hole of the connecting portion 94 fixed to the floor surface 91 (that is, the bottom of the recess 93). Thus, the distal end of the first arm 33 is connected to the floor surface 91 via the connection portion 94. The connection portion 94 is made of, for example, metal, and is fixed to the floor surface 91 by a bolt or the like. In the following description, a connection portion between the first arm 33 and the floor surface 91 is referred to as a "first connection portion 331". The first connection portion 331 is, for example, a hole of the connection portion 94 into which the tip end portion of the first arm 33 is inserted.

  The distal end of the second arm 34 is bent at a substantially right angle opposite to the distal end of the first arm 33, and extends away from the coil portion 32 in the width direction. The tip of the second arm 34 is inserted into a hole provided in the longitudinal girder 27 of the door 2. Thereby, the tip of the second arm 34 is connected to the door 2. In the following description, a connection portion between the second arm 34 and the door 2 is referred to as a "second connection portion 341". The second connection portion 341 is, for example, a hole of the longitudinal girder 27 into which the tip end portion of the second arm 34 is inserted.

  The coil portion 32 is not fixed to the floor surface 91 and the door 2, and is indirectly connected to the floor surface 91 and the door 2 via the first arm 33 and the second arm 34. As shown in FIG. 1, in a state where the door 2 is in the laid posture, the coil portion 32 is separated upward from the floor surface 91 (that is, the bottom surface of the recess 93). It is spaced downward from the main surface 21.

  In the state in which the door 2 is in the laid posture, the angle formed by the first arm 33 and the second arm 34 is smaller than the free angle. In other words, the torsion coil spring 31 is compressed more than in the free state. Therefore, when the door 2 is in the fallen posture, a moment (hereinafter referred to as a “rising moment”) acting in a direction to raise the door 2 is applied to the door 2 by the restoring force of the torsion coil spring 31. . The angle formed between the first arm 33 and the second arm 34 is an angle when the first arm 33 and the second arm 34 are viewed from the side along the direction in which the central axis J2 of the coil portion 32 faces. is there. The angle formed between the first arm 33 and the second arm 34 is zero when the first arm 33 and the second arm 34 are parallel in a side view, and the first arm 33 and the second arm 34 It becomes smaller as it gets closer in side view.

  In the state where the door 2 is in the laid posture, the vertical position of the first connection portion 331 and the vertical position of the second connection portion 341 are substantially the same. The distance in the front-rear direction between the first connection portion 331 and the central axis J2 and the distance in the front-rear direction between the second connection portion 341 and the central axis J2 are substantially the same.

  In the state where the door 2 is in the reclining posture, the second arm 34 is higher than the first arm 33 or the first arm 33 over the entire length in the longitudinal direction from the first connection portion 331 to the coil portion 32. The arm 33 is located at substantially the same position in the vertical direction. In other words, in the side view, the first arm 33 and the second arm 34 do not intersect between the first connection portion 331 and the coil portion 32. Preferably, the second arm 34 overlaps with a straight line connecting the rotation axis J1 and the second connection portion 341 in a side view.

  In the undulating gate 1, the second arm 34 may be shorter than the first arm 33. That is, the second connection portion 341 may be located rearward of the first connection portion 331. In this case, the second arm 34 and the extension line to the front side of the second arm 34 is higher than the first arm 33 over the entire length in the longitudinal direction from the first connection portion 331 to the coil portion 32. Alternatively, they are located at substantially the same position as the first arm 33 in the vertical direction. In other words, in the side view, the first arm 33 and the extension lines of the second arm 34 and the second arm 34 do not intersect between the first connection portion 331 and the coil portion 32. Note that, in the undulating gate 1, the first connection portion 331 may be located rearward of the second connection portion 341.

  Next, the standing state of the door 2 will be described with reference to FIGS. 5 to 9. FIG. 10 is a view showing the relationship between the attitude of the door 2 and the moment acting on the door 2. The horizontal axis in FIG. 10 indicates an angle with the floor surface 91 of the door 2 (hereinafter simply referred to as “the angle of the door 2”). The angle of the door 2 is 0 degrees when the door 2 is in the lying posture, and is 90 degrees when the door 2 stands vertically to the floor surface 91. The vertical axis in FIG. 10 indicates a moment about the rotation axis J1 acting on the door 2 assuming that the counterclockwise moment in FIG. 1 is positive. That is, the positive moment in FIG. 10 is a moment acting in the direction of causing the door 2 to fall (hereinafter referred to as “folding moment”), and a negative moment is acting in the direction of causing the door 2 to stand up It is a moment.

  A broken line 81 in FIG. 10 is a moment due to the weight of the door 2, and a solid line 82 is a moment applied to the door 2 by the relief assisting portion 3. A thick solid line 83 in FIG. 10 is a total moment obtained by adding the line 81 and the line 82. When the angle of the door 2 is 0 degrees (that is, when the door 2 is in the lying posture), the absolute value of the lodging moment by the weight of the door 2 is the absolute value of the standing moment by the relief assisting portion 3 in the compressed state. Greater than the value.

  As shown in FIG. 5, when the water 90 flows into the relief gate 1, a rising moment is given to the door 2 by the buoyancy and the like generated on the door 2 by the water 90, and the rising of the door 2 is started. At this time, in addition to the standing moment by the water 90, a falling moment by the weight of the door 2 and a standing moment by the restoring force of the torsion coil spring 31 work on the door 2.

  The standing moment by the torsion coil spring 31 continuously acts on the door 2 from the fallen posture shown in FIG. 5 to the posture shown in FIG. 7 from the fallen posture to the posture shown in FIG. Thereby, the rising of the door 2 is assisted, and the rising speed of the door 2 is increased. As a result, the water 90 can be prevented from flowing from the opening 92 beyond the door 2. In the state shown in FIG. 7, the torsion coil spring 31 is in a free state in which it is not compressed and expanded. In other words, the angle between the first arm 33 and the second arm 34 of the torsion coil spring 31 is a free angle.

  In the following description, the attitude of the door 2 shown in FIG. 7 will be referred to as "intermediate attitude". In addition, an angle formed by the door 2 in the intermediate posture and the floor surface 91 (that is, the bottom surface of the recess 93) is referred to as "intermediate angle". The middle angle is larger than 0 degree and smaller than an angle formed by the door 2 in the maximum standing posture and the floor surface 91 (about 75 degrees in the above example). In other words, the intermediate posture is a posture between the fallen posture and the maximum standing posture. The intermediate angle is, for example, 5 degrees or more and 70 degrees or less. In the example shown in FIG. 7, the intermediate angle is approximately 45 degrees. The middle angle of the door 2 and the free angle of the torsion coil spring 31 may be changed as appropriate.

  In the state where the door 2 is positioned between the laid posture and the intermediate posture, the angle formed between the first arm 33 and the second arm 34 in the torsion coil spring 31 in the compressed state as the angle of the door 2 becomes larger. The absolute value of the standing moment applied to the door 2 by the torsion coil spring 31 gradually decreases. Moreover, since the coil part 32 is not fixed with respect to the floor surface 91 and the door 2, as the angle of the door 2 becomes large, it moves upward and away from the door 2. In other words, the relative position of the coil portion 32 with respect to the floor surface 91 and the door 2 is changed along with the change in the attitude of the door 2. When the door 2 stands up to the intermediate posture, as described above, the compression of the torsion coil spring 31 is released, and the moment applied to the door 2 by the restoring force of the torsion coil spring 31 becomes substantially zero.

  When the door body 2 stands up more than the intermediate posture, an angle formed by the first arm 33 and the second arm 34 of the torsion coil spring 31 becomes larger than a free angle, and the torsion coil spring 31 is in an extended state. Thereby, the lodging moment by the restoring force of the torsion coil spring 31 acts on the door 2. The lodging moment by the torsion coil spring 31 continuously acts on the door 2 from the intermediate posture shown in FIG. 7 to the maximum standing posture shown in FIG. 9 from the intermediate posture shown in FIG. 8 to the posture shown in FIG. . As shown in FIG. 9, in a state where the door 2 is in the maximum standing posture, the first arm 33 of the torsion coil spring 31 extends from the coil portion 32 to the front side, and the second arm 34 extends upward from the coil portion 32. It extends.

  In a state where the door 2 is positioned between the intermediate posture and the maximum standing posture, the door 2 2 is subjected to a rising moment by the water 90, a falling moment by the weight of the door 2 and a falling moment by the torsion coil spring 31. . In fact, the falling moment of the torsion coil spring 31 by its own weight also acts on the door 2, but since the torsion coil spring 31 is relatively lightweight, the falling moment of its own weight is ignored in the following description. When the door 2 is positioned between the intermediate posture and the maximum standing posture, the angle between the first arm 33 and the second arm 34 of the torsion coil spring 31 gradually increases as the angle of the door 2 increases. The absolute value of the lodging moment applied to the door 2 by the torsion coil spring 31 gradually increases. Further, the coil portion 32 moves upward and away from the door 2 as the angle of the door 2 increases. In other words, the relative position of the coil portion 32 with respect to the floor surface 91 and the door 2 is changed along with the change in the attitude of the door 2.

  In the undulating gate 1, while the door 2 rises from the intermediate posture to the maximum standing posture, the falling moment by the torsion coil spring 31 acts on the door 2, whereby the rising speed of the door 2 is suppressed. As shown in FIG. 9, in the state where the door 2 is in the maximum standing posture, the lodging moment by the torsion coil spring 31 and the water pressure acting on the door 2 are balanced. In other words, the angle of the door 2 in the maximum standing posture is determined by the lodging moment by the torsion coil spring 31 and the water pressure acting on the door 2. As shown in FIG. 7, when the door 2 is in the intermediate posture, the water surface of the water 90 is positioned lower than the movable end 24 (that is, the top end) of the door 2. Even if the rising speed of 2 is suppressed, the water 90 does not flow from the opening 92 beyond the movable end 24 of the door 2. The undulating gate 1 may be provided with a structure such as a tension rod which limits the door 2 to stand up more than a predetermined angle. Thereby, it can be more reliably prevented that the angle of the door 2 becomes larger than the predetermined angle.

  When the water level on the front side of the door 2 starts to fall from the state shown in FIG. 9, the falling moment of the torsion coil spring 31 and the falling moment of the door 2 due to its own weight start the falling of the door 2. While the door 2 falls from the maximum standing posture to the middle posture, in addition to the falling moment due to the weight of the door 2, the falling moment by the torsion coil spring 31 continuously acts on the door 2. Thereby, the fall of the door 2 is assisted, and the fall of the door 2 is started immediately after the water level of the water 90 starts to decrease. As a result, the fall of the door 2 is started after the water level of the water 90 drops significantly, and it can prevent that the door 2 falls rapidly. In addition, when the angle of the door 2 in the maximum standing posture is 90 degrees, the falling moment by the weight of the door 2 does not work at the start of the falling of the door 2, and only the falling moment by the torsion coil spring 31 acts on the door 2. work.

  When the door 2 falls below the intermediate posture shown in FIG. 7, the compression of the torsion coil spring 31 is started. While the door 2 falls from the intermediate posture to the lying posture shown in FIG. 5, the rising moment by the torsion coil spring 31 continuously acts on the door 2 to suppress the falling speed of the door 2. Thus, the force applied to the floor surface 91 or the like when the door 2 is in the fallen posture can be reduced.

  As described above, the relief gate 1 includes the door 2 and the relief assisting portion 3. In the door 2 in the reclining posture, the movable end 24 of the door 2 is located on the front side of the support end 23. The door 2 changes its posture between the laid posture and the maximum standing posture by rotating around the support end 23 as a fulcrum. The relief assisting portion 3 includes a torsion coil spring 31. The torsion coil spring 31 is disposed below the upper surface (i.e., the first main surface 21) of the door 2 in the lying posture. The torsion coil spring 31 includes a coil portion 32, a first arm 33, and a second arm 34. In the coil portion 32, a spring material is spirally wound around a central axis J <b> 2 facing the width direction of the door 2. The first arm 33 protrudes from the coil portion 32. The tip of the first arm 33 is connected to the floor surface 91. The second arm 34 protrudes from the coil portion 32. The tip of the second arm 34 is connected to the door 2.

  In the ups and downs gate 1, in a state where the door 2 is in the laid posture, a rising moment is applied to the door 2 by the restoring force of the torsion coil spring 31. In addition, in a state where the door 2 is in the maximum standing posture, a lodging moment is applied to the door 2 by the restoring force of the torsion coil spring 31. As described above, in the undulating gate 1, both the application of the rising moment at the start of the door 2 and the application of the lodging moment at the start of the door 2 can be realized by the torsion coil spring 31. Thereby, the structure of the undulating gate 1 can be simplified. As a result, it is possible to start rising quickly when water flows in, and reduce the manufacturing cost of the undulating gate 1 that can start falling earlier when the water level drops.

  As described above, the torsion coil spring 31 is disposed below the upper surface of the door 2 in the lying posture. Thereby, compared with the case where the torsion coil spring 31 is arrange | positioned at the side of the door 2 (namely, the outer side of the width direction rather than the door 2), the undulating gate 1 can be miniaturized. As a result, the installation area of the undulating gate 1 can be reduced.

  In the undulating gate 1, the torsion coil spring 31 can be disposed on the center side in the width direction than both side portions of the door 2. Therefore, the force applied from the torsion coil spring 31 to the door 2 is increased compared to the case where a force is applied only to both sides of the movable end of the door when applying a moment to assist the door 2 to rise or fall. can do. On the other hand, when the same force is applied to the door 2, the span length of the door 2 (that is, the width of the door 2) is greater than when the force is applied only to both sides of the movable end of the door. Can be increased. Moreover, the members in the vicinity of the movable end 24 of the door 2 can be miniaturized, and the manufacturing cost of the undulating gate 1 can be reduced.

  As described above, the torsion coil spring 31 is located inside the door 2 in the lying posture. Accordingly, it is not necessary to provide a hole or the like for accommodating the torsion coil spring 31 on the bottom surface (that is, the floor surface 91) of the recess 93. Moreover, it is not necessary to provide drainage facilities, such as the said hole. Therefore, installation and maintenance of the relief gate 1 can be facilitated.

  The relief assisting portion 3 further includes another torsion coil spring 31 disposed at a position different from the one torsion coil spring 31 in the width direction. Thus, by providing the plurality of torsion coil springs 31, each torsion coil spring 31 can be miniaturized. Further, by arranging the plurality of torsion coil springs 31 in the width direction, the span length of the door 2 can be further increased, and the members in the vicinity of the movable end 24 of the door 2 can be further miniaturized. It can also be done. As a result, the manufacturing cost of the relief gate 1 can be further reduced.

  In the undulating gate 1, the coil portion 32 of the torsion coil spring 31 is not fixed to the floor surface 91 and the door 2. Further, in accordance with the posture change of the door 2, the relative position of the coil portion 32 to the floor surface 91 and the door 2 is changed. As described above, even when the central axis J2 of the coil portion 32 is separated from the rotation axis J1 of the door 2 by making the coil portion 32 movable, the second connection portion 341 can be used as the door 2 It is not necessary to make relative movement possible. In addition, it is not necessary to make the first connection portion 331 movable relative to the floor surface 91. Therefore, since it is not necessary to provide moving mechanisms, such as a roller, in the front-end | tip part of the 1st arm 33 and the 2nd arm 34, the structure of the undulation gate 1 can be simplified. As a result, the manufacturing cost of the relief gate 1 can be further reduced.

  In addition, since the coil portion 32 is not fixed to the floor surface 91 and the door 2, the coil portion 32 does not have to be disposed close to the rotation axis J 1 of the door 2. For this reason, the freedom degree of arrangement | positioning of the coil part 32, the 1st connection part 331, and the 2nd connection part 341 can be improved. Therefore, when the door 2 is raised and lowered, the direction of the force applied from the torsion coil spring 31 to the door 2 can be easily made close to the tangential direction of the rotation of the door 2. As a result, the rising moment and the falling moment applied to the door 2 from the torsion coil spring 31 can be increased.

  As described above, the torsion coil spring 31 is disposed on the front side of the support end 23 of the door 2. The first arm 33 and the second arm 34 extend from the coil portion 32 to the front side in a state in which the door 2 is in the laid posture. In the state in which the door 2 is in the laid posture, the angle formed by the first arm 33 and the second arm 34 is smaller than the free angle. In the state where the door 2 is in the maximum standing posture, the first arm 33 extends from the coil portion 32 to the front side, and the second arm 34 extends from the coil portion 32 upward. In the state in which the door 2 is in the maximum standing posture, the angle formed by the first arm 33 and the second arm 34 is larger than the free angle. Thereby, the 1st arm 33 and the 2nd arm 34 can be lengthened. That is, the first connection portion 331 and the second connection portion 341 can be arranged at positions relatively far from the rotation axis J1 of the door 2. As a result, the rising moment and the falling moment applied to the door 2 from the torsion coil spring 31 can be increased.

  As described above, in a state in which the door 2 is in the lying posture, a first connection, which is a connecting portion between the first arm 33 and the floor surface 91, is an extension of the second arm 34 and the second arm 34 to the front side. It is located above the first arm 33 or at the same position as the first arm 33 over the entire length ranging from the portion 331 to the coil portion 32. Thereby, when the door 2 is up and down, the direction of the force applied from the torsion coil spring 31 to the door 2 can be made close to the tangential direction of the rotation of the door 2. As a result, the rising moment and the falling moment applied to the door 2 from the torsion coil spring 31 can be increased. The second arm 34 preferably overlaps the straight line connecting the rotation axis J1 and the second connection portion 341 in a side view. As a result, it is possible to further increase the rising moment and the falling moment applied from the torsion coil spring 31 to the door 2.

  Further, as described above, the extension line to the front side of the second arm 34 and the second arm 34 is located above the first arm 33 or at the same position as the first arm 33 in the vertical direction. When the door 2 stands up from the fallen posture, as the angle of the door 2 increases, the first connection portion 331 and the second connection portion 341 gradually separate in the vertical direction. Therefore, as the angle of the door 2 increases, the coil portion 32 gradually moves upward and away from the first main surface 21 of the door 2 and moves downward (that is, in the direction approaching the floor surface 91) or It does not move in the direction approaching the first major surface 21. As a result, at the time of ups and downs of the door 2, the coil portion 32 is prevented from coming into contact with the bottom surface (that is, the floor surface 91) of the recess 93 or the first main surface 21 of the door 2. Smooth relief.

  Furthermore, in the undulating gate 1, when the door 2 is in the reclining posture, the vertical position of the first connection portion 331 and the second connection portion 341 that is the connection portion between the second arm 34 and the door 2. The position in the vertical direction is the same. Further, the distance in the front-rear direction between the first connection portion 331 and the central axis J2 is the same as the distance in the front-rear direction between the second connection portion 341 and the central axis J2. Thereby, the second connection portion 341 can be disposed at a position relatively far from the rotation axis J1 of the door 2 while realizing smooth undulation of the door 2 as described above. As a result, it is possible to further increase the rising moment and the falling moment applied from the torsion coil spring 31 to the door 2.

  FIG. 11 is a side view showing another example of the relief gate 1. FIG. 12 is an enlarged perspective view of the torsion coil spring 31 shown in FIG. In the example shown in FIG. 11 and FIG. 12, the second connection portion 341 is positioned below the first connection portion 331 in the state where the door 2 is in the fallen posture. Further, the distance in the front-rear direction between the first connection portion 331 and the central axis J2 is the same as the distance in the front-rear direction between the second connection portion 341 and the central axis J2. Therefore, in a state where the door 2 is in the fallen posture, the second arm 34 intersects the first arm 33 in a side view facing in the width direction. Thereby, when the door 2 is up and down, the direction of the force applied from the torsion coil spring 31 to the door 2 can be made closer to the tangential direction of the rotation of the door 2. As a result, the rising moment and the falling moment applied to the door 2 from the torsion coil spring 31 can be further increased.

  In the undulating gate 1 illustrated in FIGS. 11 and 12, the second connection portion 341 may be located rearward of the first connection portion 331. In this case, in a state where the door 2 is in the fallen posture, the second arm 34 or an extension line to the front side of the second arm 34 intersects the first arm 33 in a side view facing in the width direction. Also in this case, the direction of the force applied from the torsion coil spring 31 to the door 2 can be brought closer to the tangential direction of the rotation of the door 2 when the door 2 is raised and lowered, as described above. As a result, the rising moment and the falling moment applied to the door 2 from the torsion coil spring 31 can be further increased.

  In the undulating gate 1 illustrated in FIGS. 11 and 12, when the door 2 is erected from the fallen posture, the coil portion 32 is downward (that is, in a direction approaching the floor surface 91) or the first of the door 2 It may move in the direction approaching the main surface 21. In this case, for example, in the first connection portion 331 and the second connection portion 341, it is preferable that backlash (i.e., play) be provided in the hole into which the tip end portion of the first arm 33 and the second arm 34 is inserted. By moving the tip end portions of the first arm 33 and the second arm 34 in the holes, it is possible to prevent or suppress the movement of the coil portion 32 in the downward direction or in the direction approaching the first major surface 21.

  FIG. 13 is a plan view showing still another example of the relief gate 1. In the undulating gate 1 illustrated in FIG. 13, the door 2 includes the buoyant portion 28 positioned between the first arm 33 and the second arm 34 in the width direction. Thereby, since the buoyancy of the door 2 can be increased, it is possible to start the door 2 more quickly when the water flows in. The buoyant portion 28 includes, for example, a buoyant body such as a foamed resin fixed to the lower surface of the first main surface 21 of the door 2. When the door 2 is in the lying posture, the buoyant portion 28 is located between the first arm 33 and the second arm 34 in the width direction without contacting the first arm 33 and the second arm 34. In the door 2, in the divided space 201 in which the torsion coil spring 31 is disposed, a buoyant portion may be provided around the torsion coil spring 31 (for example, between the torsion coil spring 31 and the movable end 24).

  FIG. 14 is a side view showing still another example of the relief gate 1. The undulating gate 1 illustrated in FIG. 14 further includes a strap-like or strip-like standing restriction member 35 that connects the tip of the first arm 33 and the tip of the second arm 34. The standup restriction member 35 linearly extends in a state where the door 2 is in the maximum standup posture. As described above, since the rising restricting member 35 is in a straight shape without slack, it is possible to prevent the door 2 from pivoting rearward than the maximum standing posture. The standing restriction member 35 is a member that does not substantially expand and contract in the longitudinal direction. The standup restriction member 35 is, for example, a belt-like member made of synthetic fiber. In a state where the door 2 is in the lying posture, for example, the rising restricting member 35 is folded in half at the central portion in the longitudinal direction and disposed between the first arm 33 and the second arm 34.

  The standup restriction member 35 may be attached to each torsion coil spring 31, or may be attached to a part of the plurality of torsion coil springs 31. The standup restriction member 35 may be attached directly to the tip of the first arm 33 and the tip of the second arm 34, for example. Alternatively, as shown in FIG. 15, the rising restricting member 35 is fastened to a hole different from the hole into which the distal end portion of the first arm 33 is inserted in the connection portion 94, and the first arm via the connection portion 94 It may be attached indirectly to the tip of 33. Alternatively, the standup restriction member 35 is fastened to a hole different from the hole into which the tip end portion of the second arm 34 is inserted in the longitudinal girder 27, and the distal end portion of the second arm 34 via the longitudinal girder 27. It may be attached indirectly.

  16 to 19 are side views showing still another example of the undulating gate 1. The relief gate 1 shown in FIG. 16 further includes rising limit members 351, 352, and the door 2 further includes a connecting portion 291 and an abutting portion 292. In the following description, the standing restriction members 351 and 352 are respectively referred to as “first standing restriction member 351” and “second standing restriction member 352”. The first standing restriction member 351 and the second standing restriction member 352 are cord-like or strip-like members that do not extend and contract substantially in the longitudinal direction. The first standing restriction member 351 and the second standing restriction member 352 are, for example, belt-shaped members made of synthetic fiber. The connection portion 291 and the contact portion 292 are disposed between the first main surface 21 and the second main surface 22 of the door 2, and are fixed to the first main surface 21, for example. The connection portion 291 is, for example, a member substantially similar to the connection portion 94 fixed to the floor surface 91. The contact portion 292 is, for example, a substantially plate-like member.

  In the undulating gate 1 shown in FIG. 16, the tip end portion of the first arm 33 of the torsion coil spring 31 is connected to the floor surface 91 via the connection portion 94 in the same manner as described above. On the other hand, the second arm 34 is not fixed to the door 2. One end of a first rising restricting member 351 is fixed to the tip of the second arm 34. The other end of the first rising restricting member 351 is fixed to the connecting portion 291. In other words, the tip of the second arm 34 is indirectly connected to the door 2 via the first rising restricting member 351. One end of the second rising restricting member 352 is fixed to the tip of the first arm 33, and the other end is fixed to the tip of the second arm 34. In other words, the second standing restriction member 352 connects the tip of the first arm 33 and the tip of the second arm 34.

  As shown in FIG. 16, in a state where the door 2 is in a lower position than the intermediate posture, the tip of the second arm 34 of the torsion coil spring 31 in a compressed state is in contact with the contact portion 292 from the lower side. . Thereby, a standing moment is applied to the door 2 from the torsion coil spring 31. The same applies to the case where the door 2 is in the fallen posture. In a state in which the door 2 is more prone to fall than the intermediate posture, the first standing restriction member 351 and the second standing restriction member 352 are slack.

  As shown in FIG. 17, in the state where the door 2 is in the intermediate posture, the torsion coil spring 31 is in the natural state, and therefore the standing moment and the fall moment are not given to the door 2 from the torsion coil spring 31. When the door 2 is in the intermediate posture, the first rising restricting member 351 and the second rising restricting member 352 are slack.

  When the door 2 stands up from the intermediate posture shown in FIG. 17, the second arm 34 is separated from the door 2 in the torsion coil spring 31 in a natural state. Further, since the first standing restriction member 351 and the second standing restriction member 352 are slack, the standing moment and the falling moment are not given to the door 2 from the torsion coil spring 31.

  When the door 2 stands up to a certain extent or more than the intermediate posture, the first rise restricting member 351 linearly extends between the door 2 and the second arm 34 in a natural state separated from the door 2. In the undulating gate 1, the torsion coil spring 31 is in a natural state from the state in which the door 2 is in the intermediate posture until the first rising restricting member 351 extends linearly, and the torsion coil spring 31 stands up to the door 2. No moment or lodging moment is applied.

  After the first rising restricting member 351 linearly extends, as the door 2 is raised, as shown in FIG. 18, the second arm 34 of the torsion coil spring 31 is a door through the first rising restricting member 351. It is pulled by the body 2 to be separated from the first arm 33, and the torsion coil spring 31 is in an extended state. As a result, a folding moment is applied to the door 2 from the torsion coil spring 31. In the state shown in FIG. 18, the second rising restricting member 352 is slack.

  As shown in FIG. 19, when the door 2 is in the maximum standing posture, the first standing restriction member 351 and the second standing restriction member 352 extend linearly. As described above, since the first rising restricting member 351 and the second rising restricting member 352 are straight without slack, it is possible to prevent the door 2 from pivoting to the rear side with respect to the maximum standing posture. Further, in a state where the door 2 is in the maximum standing posture, the torsion coil spring 31 is in the extended state as described above. As a result, a folding moment is applied to the door 2 from the torsion coil spring 31.

  As described above, in the undulating gate 1 shown in FIGS. 16 to 19 as described above, the torsion coil spring 31 applies a rising moment at the start of the rising of the door 2 and at the start of the falling of the door 2. Both the application of the lodging moment can be realized with a simple structure.

  Next, the undulating gate 1a according to the second embodiment of the present invention will be described. FIG. 20 is a side view showing the undulating gate 1a. FIG. 21 is a plan view showing the undulating gate 1a. FIG. 22 is a front view of the relief gate 1a as viewed from the front. The undulating gate 1 a further includes a counterweight mechanism 6 in addition to the components of the undulating gate 1 shown in FIGS. 1 to 3. The structure other than the counterweight mechanism 6 of the undulation gate 1a is substantially the same as that of the undulation gate 1 described above. In the following description, components other than the counterweight mechanism 6 of the relief gate 1a are designated by the same reference numerals as the corresponding configuration of the relief gate 1.

  The counterweight mechanism 6 includes a counterweight 61 and a rope 62 which is a cord-like or strip-like connecting member. In the example shown in FIGS. 20 to 22, two sets of the counterweight 61 and the rope 62 are provided in the counterweight mechanism 6. The two counterweights 61 are disposed behind the support end 23 of the door 2 on both sides in the width direction of the door 2. The counterweight 61 is disposed, for example, inside the doorstop 11. One end of the rope 62 is connected to the counterweight 61.

  The rope 62 extends forward through two fixed pulleys 63 aligned in the front-rear direction. The fixed pulley 63 is fixed to, for example, the door stopper 11. The other end of the rope 62 is connected to the movable end 24 of the door 2 below the front pulley 63. For example, the other end of the rope 62 is connected to a protrusion 241 that protrudes outward in the width direction at the movable end 24. The counterweight 61 is suspended by the rope 62 and is spaced upward from the floor surface 91. When the door 2 is in the lying posture, the absolute value of the falling moment of the door 2 due to its own weight is the sum of the standing moment by the torsion coil spring 31 of the relief assisting portion 3 in the compressed state and the standing moment by the weight of the counterweight 61 Greater than absolute value.

  Next, referring to FIGS. 23 to 27, the standing state of the door 2 in the undulating gate 1a will be described. As shown in FIG. 23, when the water 90 flows into the relief gate 1a, a rising moment is applied to the door 2 by the buoyancy and the like generated in the door 2 by the water 90, and the rising of the door 2 is started. At this time, in addition to the standing moment by the water 90, the door 2 has a falling moment due to its own weight, a standing moment by the restoring force of the torsion coil spring 31, and a standing moment by the counterweight 61 (that is, the counterweight 61). The lifting moment) works by

  With regard to the standing moment by the torsion coil spring 31 and the standing moment by the counterweight 61, the door 2 extends from the fallen posture shown in FIG. 23 through the posture shown in FIG. 24 to the intermediate posture shown in FIG. Work on 2 continuously. Thereby, the rising of the door 2 is assisted, and the rising speed of the door 2 is increased. In the state where the door 2 is positioned between the fallen posture and the intermediate posture, as the angle of the door 2 becomes larger, the absolute value of the rising moment by the torsion coil spring 31 and the absolute value of the rising moment by the counterweight 61 are It will decrease gradually.

  As described above, in the state in which the door 2 is in the intermediate posture, the torsion coil spring 31 is in the free state where it is not compressed and expanded. Further, in the present embodiment, when the door 2 is in the intermediate posture, in the side view, the door 2 and the rope 62 extending from the movable end 24 of the door 2 to the front fixed pulley 63 are in line. Located in In other words, in a side view, the tangent line extended from the rotation axis J1 of the door 2 to the lower part of the constant pulley 63 on the front side overlaps the door 2 and the rope 62. Thereby, the moment given to the door 2 from the counterweight 61 becomes substantially zero. The position of the counterweight 61 shown in FIG. 25 is the lowest point of the counterweight 61. Also at the lowest point, the counterweight 61 is suspended by the rope 62 and is separated upward from the floor surface 91.

  When the door body 2 stands up more than the second posture, the torsion coil spring 31 is in an extended state, and a lodging moment by the torsion coil spring 31 acts on the door body 2. Further, a falling moment by the counterweight 61 (that is, a falling moment by gravity acting on the counterweight 61) also acts on the door 2. The fall moment by the torsion coil spring 31 and the fall moment by the counterweight 61 are from the middle posture shown in FIG. 25 to the maximum standing posture shown in FIG. 27 through the posture shown in FIG. Work on body 2 continuously. Thereby, the standing speed of the door 2 is suppressed. In the state where the door 2 is positioned between the intermediate posture and the maximum standing posture, as the angle of the door 2 becomes larger, the absolute value of the falling moment by the torsion coil spring 31 and the absolute value of the falling moment by the counterweight 61 Gradually increases.

  When the water level on the front side of the door 2 starts to fall, the fall of the door 2 is started by the fall moment by the torsion coil spring 31, the fall moment by the counterweight 61, and the fall moment by the weight of the door 2. While the door 2 falls from the maximum standing posture to the intermediate posture shown in FIG. 25, in addition to the falling moment of the door 2 due to its own weight, the falling moment due to the torsion coil spring 31 and the falling moment due to the counterweight 61 Working continuously. Thereby, the fall of the door 2 is assisted, and the fall of the door 2 is started immediately after the water level of the water 90 starts to decrease.

  While the door 2 falls from the intermediate posture to the lying posture shown in FIG. 23, the standing moment by the torsion coil spring 31 and the standing moment by the counterweight 61 continuously act on the door 2. Thereby, the lodging speed of the door 2 is suppressed.

  As described above, the undulating gate 1 a further includes the counterweight 61 and the rope 62 which is a connecting member. The rope 62 connects the counterweight 61 and the movable end 24 of the door 2 and suspends the counterweight 61. In the ups and downs gate 1a, in a state where the door 2 is in the fallen posture, a standing moment is applied to the door 2 by the restoring force of the torsion coil spring 31 and the counterweight 61. In addition, in the state where the door 2 is in the maximum standing posture, a fall moment is applied to the door 2 by the restoring force of the torsion coil spring 31 and the counterweight 61.

  Thereby, the torsion coil spring 31 can be miniaturized. Further, the counterweight 61 can be reduced in weight as compared with the case where the counterweight mechanism 6 is provided without providing the relief assisting portion 3. Thereby, the span length of the door 2 (that is, the width of the door 2) can be increased. Moreover, the members in the vicinity of the movable end 24 of the door 2 can be miniaturized, and the manufacturing cost of the undulating gate 1a can be reduced.

  Next, a relief gate 1b according to a third embodiment of the present invention will be described. FIG. 28 is a side view of the relief gate 1b. In the undulating gate 1 b, the rotation axis J 1 of the door 2 is located below the second main surface 22 of the door 2 at the support end 23 of the door 2. Further, the floor surface 91 extends downward slightly on the front side of the rotation axis J1. In the following description, a portion of the floor surface 91 extending downward is referred to as a vertical floor surface 95. A connection 94 is provided on the vertical floor 95 (i.e., on the rear side of the vertical floor 95). The support end 23 of the door 2 extends rearward beyond the vertical floor surface 95. In the ups and downs gate 1b, when the door 2 pivots with the rotation axis J1 of the support end 23 as a fulcrum, the posture is set between the laid posture shown by the solid line and the maximum standing posture shown by the two-dot chain line. change. A gap between the raised door 2 and the floor surface 91 is closed by a seal member 96 (for example, a thin plate-like water-tight rubber) connecting the door 2 and the vertical floor surface 95 on the front side of the rotation axis J1.

  The relief assisting portion 3b of the relief gate 1b includes a torsion coil spring 31b. The relief assisting portion 3 b includes, for example, a plurality of torsion coil springs 31 b arranged in the width direction of the door 2. Each torsion coil spring 31 b is disposed on the rear side of the rotation axis J 1 which is a fulcrum of the door 2. Each torsion coil spring 31 b is disposed below the first main surface 21 of the door 2 in the reclining posture. The plurality of torsion coil springs 31 b have the same structure. The number of torsion coil springs 31b included in the relief portion 3b may be changed as appropriate. The number of torsion coil springs 31 b may be, for example, one or two or more.

  Similar to the torsion coil spring 31 shown in FIG. 4, the torsion coil spring 31 b includes a coil portion 32, a first arm 33 and a second arm 34. The coil portion 32 is a substantially cylindrical portion centered on a central axis J2 facing in the width direction of the door 2. In the coil portion 32, a spring material is spirally wound around a central axis J2 substantially parallel to the width direction. The coil portion 32 is not fixed to the floor surface 91 and the door 2. In the state where the door 2 is in the laid posture, the coil portion 32 is separated rearward from the vertical floor surface 95 of the floor surface 91.

  In the torsion coil spring 31 b, the first arm 33 and the second arm 34 respectively project from the coil portion 32. The first arm 33 extends downward from the coil portion 32 in the state where the door 2 is in the lying posture. The tip of the first arm 33 is inserted into the hole of the connecting portion 94 fixed to the vertical floor surface 95 of the floor surface 91. Thus, the distal end of the first arm 33 is connected to the floor surface 91 via the connection portion 94. The second arm 34 extends rearward from the coil portion 32 in a state in which the door 2 is in the lying posture. The tip of the second arm 34 is inserted into a hole provided in the longitudinal beam 27 (see FIG. 4) of the door 2. Thereby, the tip of the second arm 34 is connected to the door 2.

  In the state in which the door 2 is in the lying posture, the angle formed by the first arm 33 and the second arm 34 is larger than the free angle. In other words, the torsion coil spring 31b is stretched more than in the free state. Therefore, in the state where the door 2 is in the fallen posture, a rising moment is applied to the door 2 by the restoring force of the torsion coil spring 31 b. The standing moment by the torsion coil spring 31b continuously acts on the door 2 until the posture of the door 2 reaches from the laid posture to the middle posture.

  The angle formed between the first arm 33 and the second arm 34 is an angle when the first arm 33 and the second arm 34 are viewed from the side along the direction in which the central axis J2 of the coil portion 32 faces. is there. The angle formed between the first arm 33 and the second arm 34 is zero when the first arm 33 and the second arm 34 are parallel in a side view, and the first arm 33 and the second arm 34 It becomes smaller as it gets closer in side view.

  As shown by a two-dot chain line in FIG. 28, the first arm 33 and the second arm 34 extend downward from the coil portion 32 in the state where the door 2 is in the maximum standing posture. In the state where the door 2 is in the maximum standing posture, the angle formed by the first arm 33 and the second arm 34 is smaller than the free angle. In other words, the torsion coil spring 31b is compressed more than in the free state. Therefore, in the state where the door 2 is in the maximum standing posture, a lodging moment is applied to the door 2 by the restoring force of the torsion coil spring 31 b. The folding moment by the torsion coil spring 31b continuously acts on the door 2 until the posture of the door 2 reaches the middle up posture.

  In the undulating gate 1b, as in the case of the undulating gate 1 shown in FIG. 1, in the state where the door 2 is in the laid posture, a rising moment is applied to the door 2 by the restoring force of the torsion coil spring 31b. In addition, in a state where the door 2 is in the maximum standing posture, a lodging moment is applied to the door 2 by the restoring force of the torsion coil spring 31 b. As described above, in the undulating gate 1b, both the application of the rising moment at the start of the door 2 and the application of the lodging moment at the start of the door 2 can be realized by the torsion coil spring 31b. Thereby, the structure of the undulating gate 1b can be simplified. As a result, it is possible to start rising quickly when water flows in, and reduce the manufacturing cost of the undulating gate 1b that can start falling earlier when the water level drops.

  In addition, the torsion coil spring 31b is disposed below the upper surface (that is, the first main surface 21) of the door 2 in the lying posture. Thereby, compared with the case where the torsion coil spring 31b is arrange | positioned at the side of the door 2 (namely, the outer side of the width direction rather than the door 2), the undulating gate 1b can be miniaturized. As a result, the installation area of the undulating gate 1b can be reduced.

  In the undulating gate 1b, the torsion coil spring 31b is disposed on the rear side of the pivot of the door 2 (that is, the rotation axis J1 of the support end 23). When the door 2 is in the lying posture, the first arm 33 extends downward from the coil portion 32, and the second arm 34 extends rearward from the coil portion 32. In the state in which the door 2 is in the lying posture, the angle formed by the first arm 33 and the second arm 34 is larger than the free angle. In the state where the door 2 is in the maximum standing posture, the first arm 33 and the second arm 34 extend downward from the coil portion 32. In the state where the door 2 is in the maximum standing posture, the angle formed by the first arm 33 and the second arm 34 is smaller than the free angle.

  Thereby, even in the floor surface 91 having the vertical floor surface 95 extending downward from the middle of the door 2 in the longitudinal direction, the undulating gate 1 b can be installed. Moreover, since the torsion coil spring 31b is not provided in front of the rotation axis J1, the door 2 can be provided with a large buoyancy portion. As a result, the standing speed of the door 2 can be increased.

  In the undulating gate 1b, as in the case of the undulating gate 1 shown in FIG. 1, the coil portion 32 is not fixed to the floor surface 91 and the door 2 and along with the posture change of the door 2, the floor 91 and the door The relative position of the coil portion 32 to 2 is changed. Thereby, the structure of the undulating gate 1b can be simplified. As a result, the manufacturing cost of the relief gate 1b can be further reduced.

  In the undulating gate 1b, in addition to the undulation assisting portion 3b, a counterweight mechanism 6 may be provided as in the undulating gate 1a shown in FIG. Thereby, the torsion coil spring 31b can be miniaturized. Further, as compared with the case where the counterweight mechanism 6 is provided without providing the relief assisting portion 3b, the weight of the counterweight 61 can be reduced. Thereby, the span length of the door 2 (that is, the width of the door 2) can be increased. Moreover, the members in the vicinity of the movable end 24 of the door 2 can be miniaturized, and the manufacturing cost of the undulating gate 1 b can be reduced.

  Various modifications are possible in the above-described undulating gates 1, 1a, 1b.

  For example, in the undulating gate 1, the connection structure between the first arm 33 and the floor surface 91 in the first connection portion 331 may be variously changed. Moreover, the connection structure of the 2nd arm 34 and the door 2 in the 2nd connection part 341 may also be changed variously. For example, the distal end portion of the second arm 34 and the door 2 may be indirectly connected via a string-like or strip-like member that does not substantially expand and contract. Thus, the torsion coil spring 31 can be miniaturized, and the second connection portion 341 can be disposed at a position largely separated from the rotation axis J1. The same applies to the undulating gates 1a and 1b.

  The coil portion 32 of the torsion coil spring 31 may be fixed to the floor surface 91 in the undulating gate 1 or 1a. In this case, a roller or the like movable on the door 2 at all times in contact with the door 2 is provided at the tip of the second arm 34, and the second arm 34 is connected to the door 2 via the roller or the like. Be done. Further, the coil portion 32 of the torsion coil spring 31 may be fixed to the door 2 in the undulating gate 1, 1 a. In this case, a roller or the like movable on the floor surface 91 at all times in contact with the floor surface 91 is provided at the tip of the first arm 33, and the first arm 33 is connected to the floor surface 91 via the roller or the like. Be done. The same applies to the relief gate 1b.

  In the undulating gate 1 or 1a, a hole or the like may be provided on the bottom surface of the recess 93, and the lower portion of the torsion coil spring 31 may be accommodated in the hole or the like. Moreover, the recessed part 93 is not provided in the floor surface 91, but the door 2 of a lying posture may be installed in the flat floor surface 91 of the height substantially the same as the circumference. Also in the rising and lowering gate 1b, the door 2 in the lying posture may be installed on a flat floor surface 91 having substantially the same height as the surroundings.

  The structure of the undulation gates 1, 1a and 1b may be applied to an undulation gate other than the undulation gate (so-called floating levitation gate) in which the door 2 is automatically erected by water pressure. For example, the above-described structure of the undulation gates 1, 1a and 1b may be applied to an undulation gate for raising the door 2 manually or an undulation gate for raising the door 2 with a hydraulic cylinder, an electric jack or the like.

  The configurations in the above embodiment and each modification may be combined as appropriate as long as no contradiction arises.

1, 1a, 1b undulation gate 2 door body 3, 3b undulation assisting portion 21 (the door body) first principal surface 23 supporting end portion 24 movable end portion 28 buoyant portion 31, 31b torsion coil spring 32 coil portion 33 first arm 34 Second arm 35, 351, 352 Lifting limiting member 61 Counter weight 62 Rope 91 Floor surface 92 Opening 331 1st connecting portion 341 2nd connecting portion J1 Rotational axis J2 Central axis

Claims (9)

A relief gate provided in an opening and standing up when water flows in from the opening to shield the opening,
In the lying posture, the movable end is located on the front side, which is the side from which water flows in, than the supporting end, and is rotated with the supporting end as a fulcrum, so that between the lying posture and the maximum standing posture The door that changes the attitude,
A relief assisting portion including a torsion coil spring disposed below the upper surface of the door in the reclining posture;
Equipped with
The torsion coil spring is
A coil portion in which a spring material is spirally wound around a central axis facing in the width direction of the door;
A first arm which protrudes from the coil portion and whose tip is connected to a floor surface;
A second arm that protrudes from the coil portion and whose tip is connected to the door;
Equipped with
In the state where the door is in the reclining posture, a standing moment is applied to the door by the restoring force of the torsion coil spring.
In the state where the door body is in the maximum standing posture, a folding moment is applied to the door body by a restoring force of the torsion coil spring. The relief gate according to claim 1, wherein
The torsion coil spring is disposed on the front side of the support end;
The first arm and the second arm extend from the coil portion to the front side in a state where the door body is in the reclining posture, and an angle formed by the first arm and the second arm is a free angle. Smaller than
The first arm extends from the coil portion to the front side and the second arm extends upward from the coil portion in a state in which the door body is in the maximum standing posture, and the first arm and the first arm A relief gate characterized in that the angle formed with the second arm is larger than the free angle. The relief gate according to claim 2, wherein
In a state in which the door is in the reclining posture, extension lines to the front side of the second arm and the second arm form a first connection portion that is a connection portion between the first arm and the floor surface. A relief gate characterized by being located above the first arm or at the same position as the first arm in the entire length of the range to the coil portion. The relief gate according to claim 2, wherein
In a state in which the door is in the reclining posture, an extension line to the front side of the second arm or the second arm intersects the first arm in a side view facing the width direction. Unevening gate. A relief gate according to any one of claims 2 to 4, wherein
A relief gate characterized in that the door includes a buoyant portion positioned between the first arm and the second arm in the width direction. The relief gate according to any one of claims 2 to 5, wherein
It further comprises a strap-like or strip-like standing restriction member connecting the tip end of the first arm and the tip end of the second arm,
A rising gate characterized in that the rising restricting member extends linearly in a state in which the door body is in the maximum standing posture. The relief gate according to claim 1, wherein
The torsion coil spring is disposed rearward of the fulcrum;
The first arm extends downward from the coil portion and the second arm extends rearward from the coil portion in a state where the door body is in the reclining posture, and the first arm and the first arm The angle with the second arm is larger than the free angle,
In the state where the door is in the maximum standing posture, the first arm and the second arm extend downward from the coil portion, and the angle between the first arm and the second arm is a free angle. A relief gate characterized by being smaller than. The relief gate according to any one of claims 1 to 7, wherein
The coil portion is not fixed to the floor surface and the door body,
An undulating gate characterized in that the relative position of the coil portion with respect to the floor surface and the door is changed along with the change in the attitude of the door. A relief gate according to any one of the preceding claims, wherein
With counter weight,
A connecting member for connecting the counterweight and the movable end of the door to suspend the counterweight;
And further
In the state where the door is in the fallen posture, a standing moment is applied to the door by the counterweight,
An undulating gate characterized in that a fall moment is applied to the door body by the counterweight in a state where the door body is in the maximum standing posture.

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