KR101133928B1 - Water gate opening closing apparatus - Google Patents

Abstract

The present invention provides a hydrogate opening and closing device. The sluice gate opening and closing device includes a main flow path portion having both sidewalls and forming a main flow path through which the fluid flows; A pair of overflow walls installed on the main flow path so as to extend a predetermined length in a direction facing each other from the two side walls and having a semicircular cross section upwardly convex; A sub flow path part forming a sub flow path inside the pair of overflow walls; And a rotation opening / closing unit connected between the pair of moon walls through a rotation shaft, the rotation opening and closing unit being rotated according to the amount of fluid flowing in the main flow passage to switch the flow direction of the fluid to the main flow passage or the sub flow passage. Equipped. Accordingly, the present invention may allow the fluid to flow along the main flow path or to be discharged along the discharge flow path forming a flow path different from the main flow path, depending on the amount of the flowing fluid.

Description

Water gate opening and shutting device {WATER GATE OPENING CLOSING APPARATUS}

The present invention relates to a sluice opening and closing device, and more particularly, a sluice which can be selectively discharged along a discharge flow path that flows the fluid along the main flow path or forms a flow path different from the main flow path, depending on the amount of fluid flowing. It relates to a switchgear.

Typically, in the case of rivers, reservoirs, or agricultural waterways, when the water is blocked and the water is shut off, a lifting device is installed to raise or lower the water gate by installing a water gate on the embankment, a support on the upper part, and then turning a handle on the support. It is composed of a structure for adjusting the water level of the fresh water in the dike).

However, when such a conventional water gate is used for a long time, both sides of the water gate combined with the screw portion of the handle and the embankment become corroded, making it difficult to open and close the water gate, especially when the heavy rain falls during the rainy season and the water level in the dike rises rapidly. If a person observes the level of the dike and then adjusts the gate opening and closing according to the situation, it is not only cumbersome, but if the floodgate is not opened due to the careless observation of the rapidly increasing level, the disaster is caused by the flooding of fresh water in the dike. There is a problem that occurs.

In addition, when the amount of water is less than a certain amount as described above, because it can not be discharged along a separate discharge flow path, there is a problem that the fresh water amount is gradually increased, and in this state, if the amount of water is increased in a short time.

The present invention was created to solve the above problems, and an object of the present invention is to provide a water gate opening and closing device that can be discharged by switching the direction of the flow of the fluid in accordance with the amount of the flowing fluid.

In one aspect, the present invention provides a hydrogate opening and closing device.

The sluice gate opening and closing device includes a main flow path portion having both sidewalls and forming a main flow path through which the fluid flows; A pair of overflow walls installed on the main flow path so as to extend a predetermined length in a direction facing each other from the two side walls and having a semicircular cross section upwardly convex; A sub flow path part forming a sub flow path inside the pair of overflow walls; And a rotation opening / closing unit connected between the pair of moon walls through a rotation shaft, the rotation opening and closing unit being rotated according to the amount of fluid flowing in the main flow passage to switch the flow direction of the fluid to the main flow passage or the sub flow passage. Include.

Here, the rotation opening and closing unit is formed in the discharge passage along the longitudinal direction therein so as to communicate with the sub flow path as the rotation, forms a semi-circular cross-section with a predetermined radius from the center, the rotating shaft is formed at both ends A discharge pipe, a buoyancy body formed on an upper surface of the discharge pipe and having a radius equal to a radius of the discharge pipe, an inlet formed on an upper surface of the discharge pipe near the buoyant body to expose the discharge flow path to the outside, and the inside of the discharge pipe. It is desirable to have a weight that is fixed to the installation.

In addition, the upper surface of the discharge pipe in which the inlet is formed and the inner surface of the buoyancy body is preferably perpendicular to each other.

In addition, an installation hole having a predetermined depth is formed between the pair of wall walls, and the rotation opening / closing unit is disposed in the installation hole, and converts the flow direction of the fluid into the main flow passage or the sub flow passage and discharges it. Do.

Here, one side end of the installation hole is formed with a slope inclined downward, the other end of the installation hole inclined protrusion is formed upwards, one side end of the discharge pipe over a predetermined angle to the slope or over the inclined projections It is preferable that the inclined first catching band is formed.

In addition, a second catching rod is formed to extend a predetermined length to the other end of the discharge pipe so as to face the first catching block, and a catching groove is formed in the lower end of the other end of the installation hole is fitted with the catching groove, the catching groove It is preferable that an elastic member having a predetermined thickness is formed on the inner side of the.

In addition, it is preferable that urethane is filled in the buoyancy body.

In addition, the inlet is preferably further provided with a screen net.

The present invention has the effect of allowing the fluid to flow along the main flow path or to be discharged along the discharge flow path forming a different flow path from the main flow path according to the amount of the flowing fluid.

In addition, the present invention is not provided with a separate electronic device to change the flow direction of the fluid, and provided with a rotating body that is rotated according to the action of the force generated by the flow amount of the fluid to control the flow direction of the fluid In addition, along with the longitudinal direction of the rotating body has an effect that can form a discharge passage in the interior of the rotating body to stably discharge the fluid to the outside.

Hereinafter, with reference to the accompanying drawings, it will be described the water gate opening and closing device of the present invention.

1 is a perspective view showing a water gate opening and closing device of the present invention. 2 is a perspective view illustrating the rotation opening and closing unit of FIG. 1. 3 is a cross-sectional view illustrating a state before rotation of the rotation opening and closing unit of FIG. 1. 4 is a cross-sectional view illustrating a state before rotation of the rotation opening and closing unit of FIG. 3.

1 and 2, the hydrological opening and closing device of the present invention has a main flow path part 100 having both sidewalls 110 spaced apart from each other by a predetermined distance.

The main flow path part 100 is provided with a main flow path a along the sidewalls 110. Here, the main flow path (a) is a flow path for guiding the flow of fluid, such as rain or sewage.

The main flow path part 110 is provided with a pair of overflow wall 210 forming a space between each other at a predetermined interval.

The pair of overflow walls 210 extend from the inner side walls of the side walls 110 at a predetermined length along a direction facing each other. The cross-sections of the pair of overflow walls 210 are formed in a semicircular shape. The pair of overflow walls 210 are formed to be convex upward on the main flow path a.

In addition, an installation hole 211 having a predetermined width and width is formed in the interspace formed between the pair of wall walls 210. Preferably, the installation hole 211 is a hole formed in the plate 10 installed on the main flow path (a).

Here, the installation hole 211 is a space in which the rotation opening and closing unit 300 described below is installed. Therefore, the width and width of the installation hole 211 may be formed to be variable according to the width of the rotation opening and closing unit 300.

In addition, a sub flow path part 200 forming a sub flow path b is formed at a bottom portion at which the pair of overflow walls 210 are located so as to communicate with the outside of the main flow path part 100.

The sub flow path b is a flow path that can be selectively communicated with the discharge flow path c of the rotation opening / closing unit 300 described below.

Next, in addition to the configuration of the rotation opening and closing unit 300, it will be described that the rotation opening and closing unit 300 is installed in the installation groove 211.

1 to 3, rotary grooves 210a are formed on the inner walls of the pair of overflow walls 210, respectively. The rotary groove 210a is a groove into which the rotary shaft 310a of the rotary opening and closing unit 300 described below is fitted.

The rotation opening / closing unit 300 is rotatably installed in the installation groove 211. That is, the rotation shaft 310a formed at both ends of the rotation opening / closing unit 300 may have a structure in which the rotation shaft 310a is inserted into the rotation grooves 210a formed on the inner walls of the pair of overflow walls 210.

The configuration of the rotation opening and closing unit 300 will be described in detail.

The rotation opening / closing unit 300 includes a discharge pipe 310 in which an discharge flow path c is formed, a buoyancy body 320 formed on an upper surface of the discharge pipe 310, and a weight installed in the discharge flow path c. 330 and an inlet 340 formed on the upper surface of the discharge pipe 310 exposed to the outside to expose the discharge passage (c) to the outside. Here, the inlet 340 serves to flow the fluid flowing from the outside into the discharge passage (c). In addition, the discharge pipe 310 and the buoyancy body 320 mentioned above may be formed integrally with each other.

In addition, the buoyancy body 300 may have a frame 301 forming a predetermined space therein, or may be made of a buoyancy material made of the same material. In the former case, the urethane 320a may be filled in the mold 301.

In addition, when the urethane 320a is filled as described above, a filling hole (not shown) for filling the urethane 320a from the outside may be formed at one or more positions of the mold 301. . When the filling hole is formed, it may be provided with a cover (not shown) which is provided to be rotatably open and closed by forcibly blocking the filling hole.

In addition, the buoyancy body 300 is a hinged opening and closing and a separate hook-type locking device (not shown) to fill the urethane (320a) or to insert and install other buoyancy material therein (not shown) May be provided).

As the discharge pipe 310 is rotated while the rotary shaft 310a is fitted into the rotary groove 210a, the discharge pipe 310 forms a discharge flow path c along the length direction so as to communicate with the sub flow path b.

In addition, the cross section of the discharge pipe 310 forms a semi-circular shape forming a predetermined radius from the center of the discharge pipe 310, the rotary shaft 310a is formed at both ends.

The buoyancy body 300 is formed on the upper surface of the discharge pipe 310 and may achieve the same radius as the radius of the discharge pipe (310).

The inlet 340 may be formed on an upper surface of the discharge pipe 310 near the buoyancy body 300 to expose the discharge passage c to the outside.

The weight 330 is fixedly installed in the discharge passage (c) formed in the discharge pipe (310).

Here, the weight 330 is attached to the inner wall of the discharge passage and has a cross section protruding into the discharge passage (c), it is preferably formed to a predetermined length. In addition, the weight 330 may be installed in a plural number to form a single.

The weight 330 serves to be easily moved by the fluid when the discharge pipe 310 is rotated, the weight 330 is fixed to the interior of the discharge pipe 310 is the discharge pipe ( 310 to return to the original position. Here, preferably, the rotation shaft 310a may be installed at both ends of the discharge pipe 310. In addition, the discharge pipe 310 is disposed in the installation groove 211.

In addition, the upper surface of the discharge pipe 310 in which the inlet 340 is formed and the inner surface of the buoyancy body 320 may be perpendicular to each other.

Particularly, an inclined surface 211a inclined downward is formed at one end of the installation hole 211, and an inclined protrusion 211b protrudes upward at the other end of the installation hole 211. In addition, at one end of the discharge pipe 310, a first catching rod 311 is formed to be inclined at an angle so as to hang on the inclined surface 211a or the inclined protrusion 211b. Here, the first inclined surface 211a is inclined downward at an angle, and the first catching surface 311 is in close contact with the first inclined surface 211a.

In addition, a second catching stand 312 extending to a predetermined length to the other end of the discharge pipe 310 is formed so as to face the first catching stand 311, the lower end of the other end of the installation hole 211 is the second catching stand A locking groove 211c is formed to sandwich the 312, and an elastic member 400 having a predetermined thickness is installed on an inner side surface of the locking groove 211c.

Accordingly, the rotation opening / closing unit 300 is connected between the pair of overflow walls 210 through the rotation shaft 310a, and rotates according to the amount of fluid flowing through the main flow path a to allow the fluid to flow. The flow direction of the gas can be discharged by switching to the main flow path (a) or the sub flow path (b).

In addition, the inlet 340 may be further provided with a screen net 500 formed of a mesh at a predetermined interval.

Next, to explain the operation of the water gate opening and closing device of the present invention configured as described above.

First, referring to FIGS. 1 and 3, a case in which the fluid flowing in the main flow path a flows below a predetermined amount will be described.

When the amount of fluid flowing in the main flow path (a) is less than a predetermined amount, the discharge groove 310 is located in the installation groove 211, the buoyancy body 320 formed on one side of the discharge pipe 310 is the installation groove 211 It is exposed to the outside of. Therefore, the inner surface of the buoyancy body 320 forms a state perpendicular to the upper surface of the discharge pipe 310, the upper surface of the discharge pipe 310 is disposed to follow substantially the same line as the main flow path (a) Can be.

In addition, the discharge pipe 310 may be maintained in the installation groove 211 by the weight 330 installed in the discharge pipe 310, that is, the discharge flow path c. In addition, the first engaging stand 311 formed at one end of the discharge pipe 310 is inclined contact with the inclined surface 211a formed at one side end of the installation groove 211, the other end of the discharge pipe 310 The second locking stand 312 is formed to span the locking groove 211c formed at the bottom of the installation groove 211, thereby preventing the discharge pipe 310 or the buoyancy body 320 to be rotated any more. have.

That is, as mentioned above, the discharge pipe 310 may be maintained in the installation groove 211.

In addition, when the second catching stand 312 is in contact with the elastic member 400 formed on the inner side of the catching groove 211c, the second catching stand 312 spans the catching groove 211c. The impact force generated can be absorbed.

Accordingly, the fluid flowing below the predetermined amount through the main flow path (a) is discharged to the discharge flow path (c) formed inside the discharge pipe (310) through the inlet 340 formed on the upper surface of the discharge pipe (310). Can be introduced. In addition, the fluid flowing into the discharge flow path c may be discharged to the outside through the sub flow path b formed at the bottom of the pair of overflow walls 210.

In this case, when the fluid is introduced through the inlet 340, the foreign matter included in the fluid may be filtered through the screen net 500 installed in the inlet 340. Therefore, it is possible to prevent the phenomenon of clogging caused by the foreign matter entering the discharge passage (c) in advance.

Next, referring to FIGS. 1 and 4, the operation of the rotation opening / closing unit 300 in the case where a predetermined amount or more of the fluid flows through the main flow path a will be described.

When a predetermined amount or more of the fluid flows through the main flow path (a), the flowing fluid may apply a predetermined pressure or more to an inner surface of the buoyancy body 320 which is disposed on the upper surface of the discharge pipe 310. That is, a predetermined force or more may be applied to the inner surface of the buoyancy body 320.

Therefore, the force applied to the inner surface of the buoyancy body 320 allows the buoyancy body 320 and the discharge pipe 310 can be rotated.

Accordingly, the buoyancy body 320 and the discharge tube 310 is rotated, so that the first catching rod 311 protruding from one side end of the discharge tube 310 has an installation groove along the rotated discharge tube 310 ( The inclined contact with the inclined protrusion 211b formed on the upper surface of the other end of 211 may prevent rotation of the discharge pipe 310.

In addition, the second catching stand 312 protruding from the other end of the discharge pipe 310 is separated from the catching groove 211c formed at the lower end of the other end of the installation groove 211 of the installation groove 211 In close contact with a lower end of one side, rotation of the discharge pipe 310 and the buoyancy body 320 may be prevented.

Accordingly, the discharge pipe 310 may be exposed to the outside of the installation groove 211 is separated from the installation groove 211 mentioned above, the buoyancy body 320 is inside the installation groove 211 Can be located. Accordingly, the communication flow path c formed in the discharge pipe 310 is cut off from the communication with the sub flow path b formed under the pair of the overflow walls 210.

In such a state, since the discharge pipe 310 protruding outside the installation groove 211 has a semicircular cross section, the discharge pipe 310 may be disposed to substantially follow the same line as the overflow walls 210.

Subsequently, the predetermined amount or more of the fluid may flow through the outer periphery of the overflow walls 210 and the discharge pipe 310 protruding from the main flow path a in a semicircular shape.

At this time, by the weight 330 and the buoyancy body 320 to be floated in the water discharge path (c) of the discharge pipe 310, the discharge pipe 310 is a return force to be located in the installation groove 211 This can be formed.

Therefore, when the amount of the fluid flowing in the main flow path (a) is formed to a predetermined amount or less, as mentioned above, the discharge pipe 310 and the buoyancy body 320 is returned to its original position to flow the fluid of a predetermined amount or less It may be discharged to the outside through the 340, the discharge passage (c), the sub-channel (b).

Although the preferred embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. Of course.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the claims below, but also by the equivalents of the claims.

1 is a perspective view showing a water gate opening and closing device of the present invention.

2 is a perspective view illustrating the rotation opening and closing unit of FIG. 1.

3 is a cross-sectional view illustrating a state before rotation of the rotation opening and closing unit of FIG. 1.

4 is a cross-sectional view illustrating a state before rotation of the rotation opening and closing unit of FIG. 3.

* Description of Signs of Main Parts of Drawings *

100: main flow path portion 200: sub flow path portion

210: overflow wall 300: rotation opening and closing unit

310: discharge pipe 311: first latch

312: second latch 320: buoyancy body

330: weight 340: inlet

500: screen net

Claims (6)

A main flow passage portion having both side walls and forming a main flow passage through which fluid flows, and provided on the main flow passage so as to extend a predetermined length along a direction facing each other from the two walls, and having a semicircular cross section upwardly A pair of intersecting wall walls, a sub-flow passage section forming a sub-flow path inside the pair of inter-wall flow walls, and a pair of intersecting wall walls through a rotation shaft, and depending on the amount of fluid flowing in the main flow path. Rotating opening and closing unit is rotated to switch the flow direction of the fluid to the main flow path or the sub flow path and discharged, The rotation opening and closing unit is formed in the discharge passage along the longitudinal direction therein so as to communicate with the sub flow path as it is rotated, and forms a semicircular shape having a predetermined radius from the cross-section, the discharge pipe is formed on both ends and the; A buoyancy body formed on the upper surface of the discharge pipe and having the same radius as the discharge pipe, an inlet formed on the upper surface of the discharge pipe near the buoyant body to expose the discharge flow path to the outside, and fixedly installed in the discharge pipe. A hydrological opening and closing device having a weight, wherein an upper surface of the discharge pipe in which the inlet is formed and an inner surface of the buoyancy body are formed at right angles to each other. delete The method of claim 1, An installation hole having a predetermined depth is formed between the pair of wall walls. The rotation opening and closing unit is disposed in the installation hole is discharged by switching the flow direction of the fluid to the main flow path or the sub flow path, One side end of the installation hole is formed inclined downwardly inclined, the other end of the installation hole inclined projections are formed upwards, one side end of the discharge pipe is inclined at a predetermined angle so as to hang over the inclined surface or the inclined projections Sluice opening and closing device, characterized in that the first locking stand is formed. The method of claim 3, A second hook is formed to extend a predetermined length to the other end of the discharge pipe so as to face the first hook, The lower end of the other end of the installation hole is formed with a locking groove that is fitted with the second locking stand, Sluice opening and closing device, characterized in that the inner side of the engaging groove is formed with an elastic member of a predetermined thickness. The method of claim 1, The hydrological opening and closing device, characterized in that the urethane is filled in the buoyancy body. The method of claim 1, The water gate opening and closing device characterized in that the inlet is further provided with a screen net.

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