KR101444885B1 - Rotary type movable weir - Google Patents

Abstract

The present invention relates to a rotary type movable weir. It is an objective of the present invention to provide a rotary type movable weir which can open or close a waterway while a sluice gate rotates on a rotary shaft by the operation of a cylinder and in which a link for connecting the sluice gate with the cylinder when the sluice gate is raised disperses a load transferred from the sluice gate to a support structure, thereby stably maintaining the raised state of the sluice gate and reducing the load applied to the cylinder. For this, the rotary type movable weir according to the present invention includes: a sluice gate arranged on a waterway to have a structure extending in a direction to cross the waterway; a support structure which is connected with rotary shafts formed at right and left sides of the sluice gate and arranged at the right and left sides of the sluice gate to support rotation of the sluice gate and which has a guide slope of an upwardly inclined structure formed in the upstream direction from the downstream side; a cylinder mounted on the support structure to provide a driving force for rotation of the sluice gate; a first link connected to the rotary shaft to be rotated together with the rotary shaft; a second link for connecting a rod of the cylinder with the first link; and a roller which is mounted at the connected portion between the second link and the rod to rotate on a link shaft which connects the second link and the rod with each other, to move along the guide slope when the sluice gate is raised or inverted by operation of the cylinder, wherein the second link lies at right angles to the guide slope when the sluice gate is raised to perfectly close the waterway.

Description

Rotary type movable weir

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a rotary movable beam that opens and closes a water channel by rotating a water gate around a rotation axis by driving a cylinder, more specifically, And the cylinders are dispersed by supporting structures provided on both sides of the watercourse, the load generated by the watercraft is stably dispersed and the load on the cylinder is reduced, .

In general, weir refers to a kind of clam fence that regulates the water level of a river, which is widely used nowadays because it plays a very important role in securing agricultural, industrial and domestic water. In addition, if several beams are installed in a river in which a dam can not be installed, it can be used as an alternative structure for medium and large dams because the water quantity can be adjusted.

In the meantime, according to the viewing mode, it is divided into high information and movable beam, and the fixed gate is structured in a fixed manner without opening and closing, and the movable gate can be configured to be able to open and close the water gate, .

The movable watch generally functions to close water gates to confine water to rivers, rivers or reservoirs to be used for various purposes, and to open water gates during floods to smoothly flow the water, The function of preventing the backflow of the water flow to the upstream side is performed.

The structure of the movable beam includes a water gate arranged to cross the water channel and opening or closing the water channel while rotating around the rotation axis, and a driving unit rotating the water gate around the rotation axis so that the water gate is raised or turned.

At this time, although the cylinder or the motor is used as the driving unit, the driving unit using the cylinder is mainly used because the driving unit tends to be exposed to moisture due to the nature of the watercraft.

An example of a rotary movable beam constructed using a driving unit using a cylinder is disclosed in Patent Publication No. 1281596. [

The rotary type moving saw disclosed in the above-mentioned invention is constituted by a rotary shaft provided at the gate and a cylinder connected to each other via a rotary arm.

In the case of the rotary movable beam constructed as described above, the rotary shaft rotates as the rotary arm is pushed by the extension of the cylinder, and the water gate rises with the rotation of the rotary shaft, thereby closing the water channel (discharge blocking).

In such a rotary movable beam, when it is necessary to maintain the standing state of the water door for water storage, the water-filled state of the water door is maintained by keeping the extended cylinder intact for the standing of the water door.

However, in the cylinder maintaining the standing state of the watercraft, the load generated due to the weight of the watercraft is operated in the direction of compressing the cylinder. As the hydraulic fluid introduced into the cylinder due to such load and natural leakage is discharged from the cylinder little by little, The standing state of the door can not be stably maintained for a long period of time.

Registered Patent Publication No. 1281596 (issued on March 3, 2013)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a rotary movable beam that opens or closes a water channel while the water gate is rotated around a rotation axis by driving a cylinder, The link connecting the cylinders disperses the load transferred from the gate to the support structure to stably maintain the standing state of the water gate and to reduce the load applied to the cylinder.

According to an aspect of the present invention, there is provided a sewing machine comprising: a water gate disposed in a water channel to have a structure extending in a direction transverse to a water channel; A support structure coupled to a rotation shaft formed on both left and right sides of the watercourse and provided on both left and right sides of the watercress to support rotation of the watercount and having an induction slope having a structure inclined upward from a downstream side in an upstream direction; A cylinder installed in the support structure to provide power for rotating the watercraft; A first link coupled to the rotating shaft to rotate with the rotating shaft; A second link connecting the rod of the cylinder with the first link; And a roller installed at an engagement portion between the second link and the rod so as to rotate about a link shaft coupling the second link and the rod and moving on the guide slope when the water gate stands by the drive and when the water flow is conducted, Wherein the second link has an upright position orthogonal to the guide slope when the gate is erected so as to completely close the channel.

On the other hand, in the rotary movable beam, a groove for restricting the movement of the roller is formed on the guide slope so that part of the roller is inserted at the standing position of the second link.

On the other hand, in the rotary movable beam, a urethane coating layer may be further formed on the outer peripheral surface of the roller.

According to the present invention having the above-described characteristics, the second link is maintained perpendicular to the guiding slope when the watercourse is erected for closing the waterway, and the load transmitted through the first link is dispersed to the guiding slope, The load on the cylinder for maintaining the standing state of the watercraft can be reduced and the standing state of the watercraft can be stably maintained.

1 is a perspective view showing a structure of a rotary movable beam according to a preferred embodiment of the present invention,
FIG. 2 is a side view showing a structure of a rotary movable beam according to a preferred embodiment of the present invention,
FIG. 3 is a side view showing a state in which a water gate rises as a rotary movable beam according to a preferred embodiment of the present invention,
4 is a detailed view of the 'X' portion of FIG. 3,
5 is a side view showing the structure of a support structure according to the present invention,
6 is a view showing a relationship in which a load generated by the weight of a watercraft when the watercourse is standing up acts on the second link;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a perspective view showing a structure of a rotary movable beam according to a preferred embodiment of the present invention, FIG. 2 is a side view showing the structure of a rotary movable beam according to a preferred embodiment of the present invention, FIG. 4 is a detailed view of the 'X' portion of FIG. 3, and FIG. 5 is a side view showing the structure of a supporting structure according to the present invention. .

The rotary operation according to the present invention is composed of a water gate 110, a support structure 120, a cylinder 130, a first link 140, a second link 150, and a roller 160.

The water gates 110 are arranged in a structure that traverses the waterway in order to be able to close the waterway. In arranging the water gate 110 in a direction transverse to the waterway, a single water gate is used when the width of the water channel is narrow. When the water channel is wide, two or more water gates are arranged in a serial structure, (110).

The hydrograph 110 includes a hydrograph body 111 and a rotary part 112 formed integrally on both sides of the hydrograph body 111 and having a rotary shaft 113 protruding from the side.

At this time, the hydrograph body 111 includes a front surface 111a having a convexly protruding structure toward the upstream side when the hydrograph 110 is standing, and a flat surface 111b having a structure parallel to the bottom surface of the hydrograph 110 And a back surface (111b) formed on the back surface (111b).

The support structure 120 supports the rotation of the water gate 110 and supports the cylinder 130 and is formed on both sides of the water gate 110.

The supporting structure 120 is provided with an induction slope 121 having a structure inclined upwards from the downstream side in the upstream direction. In the course of the standing operation or the conducting operation of the sluice 110, The roller 160 coupled to the rod 131 moves along the guide slope 121.

The guide slope 121 may be provided by a base frame 122 formed by assembling a plurality of H-shaped steel bars.

More specifically, the base frame 122 includes a bottom frame member 1221, a vertical frame member 1222 vertically erected on the bottom frame member 1221, And a reinforcing frame member 1223 connecting the bottom frame member 1221 and the side frame member 1222 while tilting upward from the downstream side toward the upstream side by connecting the reinforcing frame member 1222, The side surface of the member 1223 is used as the guiding inclined surface 121.

A first bracket 1224 for rotatably supporting a rotary shaft 113 formed on the water gate 110 and a second bracket 1225 for rotatably supporting the cylinder 130 are formed in the base frame 122 The first bracket 1224 is formed such that the rotary shaft 113 of the water gate 110 is located at the downstream upper end with respect to the guide slope 121 and the second bracket 1225 is formed to be positioned at the cylinder 130, The hinge axis P1 is formed at the lower end of the downstream side with respect to the guide slope 121. [

The cylinder 130 is installed in a second bracket 1225 formed on the support structure 120 and provides power for standing or conducting the water gate 110 and is constructed of a known hydraulic cylinder.

The rod 131 provided in the cylinder 130 is engaged with the second link 150.

The first link 140 transmits the power of the cylinder 130 transmitted through the second link 150 to the rotary shaft 113 so that the water gate 110 can be rotated. Or may be fixed by welding, or may be coupled to the rotary shaft 113 via a key and rotated together with the rotary shaft 113. [

The second link 150 connects the first link 140 to the rod 131 of the cylinder 130 and has one end coupled to the first link 140 and the other end connected to the rod 130 of the cylinder 130 131).

The roller 160 is installed on the rod 130 of the cylinder 130 and is configured to move along the guide slope 121 when the cylinder 130 is operated for standing or conducting the gate 110.

More specifically, the roller 160 is installed at a coupling portion between the rod 131 and the second link 150 by a link shaft P2 coupling the second link 150 and the rod 131. [

The urethane coating layer 161 may be further formed on the outer circumferential surface of the roller 160 to reduce vibrations or noise generated when the roller 160 moves along the guide slope 121.

As described above, the rod 131 and the rotary shaft 113 of the cylinder are connected to each other through the first link 140 and the second link 150, and the rod 131 and the rotary shaft 113 are connected to the coupling portion of the rod 131 and the second link 150 The roller 160 moving along the guide slope 121 is provided to constitute a driving unit for standing or conducting the water gate 110. When the water gate 110 stands up to completely close the water channel, The link 150 is configured to have an upright position orthogonal to the guide slope 121.

The standing position of the second link 150 is determined by the angle θ formed between the guide slope 121 and the horizontal plane in the design of the water gate 110 and the angle θ between the first link 140 and the second link 150 As shown in FIG.

The standing position of the second link 150 is such that a load generated by the weight of the water gate 110 is distributed to the support structure 120 through the second link 150 in a state where the water gate 110 stands And the second link 150 supports the standing state of the water gate 110 and alleviates the load applied to the cylinder 130. The position of the second link 150, It is preferable that a groove 1211 is formed in the guide slope 121 to guide the second link 150 to be stably fixed on the guide slope 121 in the guide slope 121. [

The groove 1211 has a structure in which a part of the guide slope 121 is recessed at a predetermined depth and has a structure in which a part of the roller 160 is inserted to restrict the movement of the roller 160, Or a polygonal shape.

3 is a sealing material that forms a watertight structure between the water gate 110 and the water channel when the water gate 110 stands up.

The roller 160 is moved upward by moving along the guide slope 121 when the cylinder 130 is operated, that is, when the cylinder 130 is extended, and the cylinder 130 The second link 150 and the first link 140 are pushed in accordance with the movement of the roller 160 and the rotating shaft 113 and the water gate 110 are rotated.

3), the roller 160 is inserted into the groove 1211 formed in the guide slope 121 to be restricted from movement, and at the same time, 2 link 150 is positioned at an upright position orthogonal to the guide slope 121 (see FIG. 4).

Fig. 6 is a view showing a relationship in which a load generated by the weight of the watercraft when the watercourse is standing up acts on the second link. Fig.

A rotation moment A acts on the rotary shaft 113 due to the own weight of the water gate 110 and the second link 140 coupled to the rotary shaft 113 acts on the second rotary shaft 113, A load B is applied to the link 150. [

On the other hand, conventionally, the cylinder is burdened by all of the rotational moments acting on the rotating shaft, so that not only the life of the cylinder is short, but also the water gate can not maintain the standing state for a long time owing to the leakage generated in the cylinder, There is a disadvantage that unreported discharge occurs.

However, when the second link 150 receives a load B generated by the rotational moment A of the rotating shaft 113 at the standing position, as in the present invention, the load B is transmitted to the guide slope surface 121 to the base frame 122 and the load transferred to the base frame 122 is dispersed in the support structure 120. This reduces the load on the cylinder 130. [

Further, since the roller 160 is stably fixed to the groove 1211 by the load B, the cylinder 130 can be smoothly moved even if natural leakage is generated in the cylinder 130 as time elapses. It is possible to prevent conduction of the water gate 110 due to shrinkage of the movable beam.

When upstream discharge is required, the cylinder 130 is contracted for the conduction of the water gate 110. At this time, as a force is applied to the roller 160 in the C direction, the roller 160 is moved to the groove 1211 The first link 140 and the second link 150 are moved in a direction corresponding to the movement of the roller 160 and the cylinder 130 Thereby causing the gate 110 to conduct.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

Description of the Related Art
110: Water table 113:
120: support structure 121: guide slope
1211: groove 130: cylinder
131: load 140: first link
150: second link 160: roller
161: Coating layer

Claims (3)

A water gate (110) disposed in the water channel to have a structure extending in a direction transverse to the water channel;
The guiding grooves 110 are provided on both left and right sides of the water gate 110 to support the rotation of the water gates 110 by being coupled with the rotation shaft 113 formed on both left and right sides of the water gates 110, A support structure 120 having an inclined surface 121;
A cylinder 130 installed in the support structure 120 to provide power for rotation of the gate 110;
A first link 140 coupled to the rotating shaft 113 to rotate together with the rotating shaft 113;
A second link 150 connecting the first link 140 and the rod 131 of the cylinder 130; And
The second link 150 and the rod 131 are coupled to each other so as to rotate about a link axis P2 that connects the second link 150 and the rod 131, And a roller (160) moving on the induction slope (121) when the water gate (110)
Wherein the second link (150) has an upright position orthogonal to the guide slope (121) when the water gate (110) is erected so as to completely close the channel. The method according to claim 1,
Wherein a groove (1211) for restricting the movement of the roller (160) is further formed on the guide slope (121) by inserting a part of the roller (160) at the standing position of the second link (150) Bo. The method of claim 2,
And a urethane coating layer (161) is further formed on an outer circumferential surface of the roller (160).

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