KR101030112B1 - Discharge type sluice gate - Google Patents

Abstract

PURPOSE: A discharge type water gate, capable of preventing water leakage by using a pressing part, is provided to prevent gaps which can cause water leakage by contacting a gate closely to a drain outlet. CONSTITUTION: A discharge type water gate comprises a body(110), a gate(120), a rod(140), a winch(150), and a pressure unit. The body comprises a drain outlet. The drain outlet is communicated with a discharge pipe installed to the upper stream. The gate ascends and descends according to a guide unit in order to open and close a ring-shaped guide of the drain outlet. The guide unit is formed inside the body. The rod is expanded upward the body from the top of the gate. The winch offers the power to lift the gate by connecting with the rod. The pressure unit is respectively formed on the rear both side of the gate. The pressure unit is elevated to closely contact the gate to the drain outlet.

Description

Discharge type gate {DISCHARGE TYPE SLUICE GATE}

The present invention relates to a discharge type sluice gate, and more particularly, the gate when the gate is opened and closed to open and close the drain port in order to control the water level of the fresh water is not in close contact with the annular guide installed in the drain port occurs when the leak occurs It relates to a discharge type water gate provided with a forward guide for moving the to the annular guide.

Generally, agricultural or industrial waters, and repair facilities or multi-purpose dams for hydroelectric power supply a certain amount of water and discharge fresh water if necessary. In such repair facilities, a hydrogate is essential for controlling the fresh water level. Is installed.

The water gate is a method of opening and closing the discharge pipe by conducting the disk in the same direction as the flow direction and opening and closing the discharge pipe in a direction crossing the flow direction. Separated by.

1 is a schematic view showing a water gate having a conventional lifting gate, and FIG. 2 is a cross-sectional view taken along the line A-A of FIG.

Referring to the drawings, the conventional water gate 1 is provided with a lifting-type gate is a body 20 formed with a discharge pipe 10 extending toward the upstream, and a drain 22 formed in communication with the discharge pipe and formed downstream ), The gate 30 which is lifted from the body 20 to open and close the drain hole, the rod 40 extending upward from the top of the gate 30 and the gate 40 in conjunction with the rod 30. It is composed of a winch 60 for providing power to lift and lower.

In addition, as shown in the enlarged main portion of FIG. 2, guide grooves 24 are provided in the body 10, and guide protrusions 32 guided in the guide grooves 24 are provided at both ends of the gate 30. Is provided in the gate 30 is to be raised and lowered in the interior of the body 20.

The annular guide 50 is installed in the drain 22 communicating with the discharge pipe 10 to move to the gate 30 by the hydraulic pressure of the fresh water. When the gate 30 is closed, the annular guide ( 50 and the gate 30 are in close contact with each other to prevent the leakage of water to the contact surface of the annular guide 50 and the gate 30.

However, the water gate 1 provided with the conventional lifting gate as described above, when the leakage inspection is performed at the production site after the assembly of the finished product, the annular guide 50 does not operate smoothly, causing leakage failure. Accordingly, there is a difficulty in disassembling all assembled sluice gates 1 to find the cause and then reassembling them.

In addition, even if the leak test is confirmed at the production site, the water gate (1) is installed at the construction site and the leak test is performed again. At this time, the annular guide (50 Leakage occurs because the actual movement of) does not match the movement of the annular guide predicted during the hydrological production.

In addition, the fresh water amount and the discharged discharged water exhibits a strong hydraulic pressure, which is concentrated in the gate 30 of the water gate 1 in which construction is completed, so that the gate 30 is in the same direction as the flow direction As a result of the stress, the annular guide 50 and the gate 30 do not come into close contact with each other, and a gap is formed to generate a leak.

In addition, when the construction gate is opened and the freshwater is discharged, relatively heavy deposits such as stones, gravel, and sludge in the freshwater sink to the bottom surface of the drain 22 of the gate 1, thereby completing the discharge of freshwater and closing the gate. When the 30 is closed, the sediment prevents the gate 30 from closing, so that the gate 30 is not completely closed, thereby making it difficult to control the discharge amount of fresh water and the fresh water level.

The present invention is to solve the above problems, the pressurizing portion is respectively installed on both sides of the rear of the gate lifted in the interior of the body for opening and closing the discharge of fresh water, in close contact with the gate to the drain through the running water according to the operation of the pressurizing portion It is an object of the present invention to provide a discharge type sluice that can be contacted so as not to form a gap in which leakage occurs.

In addition, an expansion packing that is variablely adjusted according to the size of the gap formed as the annular guide is moved in the direction of the flowing water from the drainage port of the body is provided between the annular guide and the drainage to provide a discharge-type water gate to prevent leakage There is this.

In addition, an object of the present invention is to provide a discharge-type water gate provided with a gap adjusting portion for adjusting the moving distance of the annular guide moving in the direction of running water in the drain of the body.

It is also an object of the present invention to provide a discharge type sluice that does not accumulate in the bottom of the drain so that relatively heavy deposits, such as stones, gravel and sludge, sink into the bottom of the drain so that the gate does not close when the fresh water is discharged. .

According to the technical idea of the present invention for achieving the above object, the body is formed with a drain hole communicating with the discharge pipe installed upstream, and provided in the drain hole formed in the body in contact with the flowing water discharged through the discharge pipe An annular guide formed by a photographing wing and supported by a fixing ring fixed to the drain hole, a gate that opens and closes the drain hole by lifting along a guide part formed inside the body, and extends upward from the upper end of the gate A rod and a pressurizer configured to provide power to elevate the gate in connection with the rod, and a pressurizing unit provided on both sides of the rear of the gate to move the gate toward the drain hole and to closely contact the gate and the drain hole. The pressing portion is rotated and supported on the top of the body A rotation shaft extending to the rear of the gate, a wedge block having a first inclined surface rising and falling behind the gate according to the rotation of the rotation shaft, and a second inclined surface having a reverse slope facing the first inclined surface formed on the wedge block; A sluice gate is achieved by including an inclined plate formed integrally with the back surface of the gate.

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In addition, it is preferable that the guide groove for guiding the wedge block rising and falling behind the gate is formed in the body, and the guide groove is formed in the anti-rotation cross section.

In addition, it is interposed between the annular guide and the inner diameter of the drain hole is expanded by a fluid supplied from the outside has an expansion packing for sealing between the annular guide and the inner diameter of the drain hole and a flow path for guiding the fluid to the expansion packing and the fluid flows in Preferably, the inlet includes a fluid inlet provided with a check valve.

And, by moving the annular guide further comprises a gap adjusting portion for adjusting the gap between the annular guide and the drain of the body, the gap adjusting portion is formed in the annular guide and has a bottlenecked shape facing the drain hole of the body And a head interposed in the slot and extending from the head to penetrate the body to be exposed to the outside and a fastening member fastened to the end of the bar.

In addition, it is preferable that an inclined bottom surface directed downstream is formed in the drain hole formed in the body.

In the discharge-type water gate according to the present invention, pressurization portions are respectively provided on both sides of the rear of the gate, which are elevated in the body, and the gate is advanced to an annular guide provided at a drain hole or a drain hole according to the operation of the pressurization portion, and thus the front of the gate. In close contact with the drain or annular guide, so that no gap is created.

In addition, a gap formed between the outer diameter of the annular guide and the horizontal moving space is injected by injecting a fluid supplied from the outside of the body into the expansion packing, the gap formed as the annular guide moves in the direction of flowing water at the drain hole of the body. Prevent expansion packings from leaking.

In addition, when the amount of movement of the annular guide predicted and calculated according to the change of fresh water and flow rate does not match the amount of movement of the annular guide of the discharge type floodgate installed in the field, the annular guide is adjusted by adjusting a gap adjusting part installed through the upstream body. Is moved in a horizontal moving space so that the annular guide is in intimate contact with the front of the gate, so that no leakage occurs.

In addition, the bottom surface of the drain formed in the body is formed to be inclined downstream, so that when the fresh water is discharged sediment such as stones, gravel, sludge transported to the drain along with the flowing water accumulates on the bottom of the drain. It slides on the inclined bottom surface formed and moves downstream, so as not to prevent the gate from closing.

1 is a schematic view showing a water gate having a conventional lifting gate.
FIG. 2 is a cross-sectional view taken along the line AA of FIG. 1.
Figure 3 is a partial cross-sectional view showing the front of the discharge gate according to the present invention.
Figure 4 is a partial cross-sectional view showing the side of the discharge-type water gate according to the present invention.
5 is a cross-sectional view taken along line BB of FIG. 3.
6 is an enlarged cross-sectional view of part C of FIG. 4.
FIG. 7 is an enlarged cross-sectional view of part D of FIG. 6.
8 is a cross-sectional view of a portion of the gate and the pressing portion to show the operation of the discharge-type water gate according to the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor may properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a partial cross-sectional view showing the front of the discharge gate according to the invention, Figure 4 is a partial cross-sectional view showing a side of the discharge gate according to the invention, Figure 5 is a cross-sectional view taken along line B-B of 3.

Referring to the drawings, the discharge-type water gate 100 according to the present invention is a body 110, the drain 110 is formed in communication with the discharge pipe 10 installed largely upstream, and the interior of the body 110 A gate 120 having a plate shape to open and close the annular guide 130 provided at the drain hole 112 by lifting up and down along the guide part 180 formed in the drain hole 112, and the body 110 at an upper end of the gate 120. A rod 140 extending upwardly, and a winch 150 for providing power for elevating the gate 120 in association with the rod 140 and provided at both rear sides of the gate 120, respectively, The pressing part 160 is configured to advance the gate 120 toward the drain hole 112 to closely contact the gate 120 and the drain hole 112.

The body 110 is installed on a barrier for storing fresh water such as dams and weirs, and the body 110 has a substantially rectangular shape as shown in the drawing, and the gate 120 may be elevated therein. Space is formed.

The body 110 is formed of a left and right halves having an upper portion formed therein with a space in which the gate 120 can be elevated. The body 110 is located in an upstream side and upstream body 110a having a drain 112 formed in communication with the discharge pipe 10 extending toward the upstream and integrally with the upstream body 110a. It is divided into a downstream body (110b) fixed and located on the downstream side, the gate 120 is located between the upstream body (110a) and the downstream body (110b) to discharge as the gate 120 is elevated Opening and closing of the drain 112 is in communication with the pipe (10).

And, as shown in the enlarged main portion of FIG. 5 on both inner side surfaces of the body 110 facing both side ends of the gate 120 and both side ends of the gate 120 is provided with the guide portion 180 When the gate 120 is moved up and down inside the 110 to open and close the drain 112 formed in the upstream body 110a, the vertical movement of the gate 120 is stably guided.

As such, the guide part 180 stably guiding the lifting and lowering of the gate 120 has a shape corresponding to the guide rail 182 and the guide rail 182 formed on both inner surfaces of the body 110. The guide protrusion 184 is formed to protrude on both side ends of the gate 120.

In addition, the sliding plate 186 made of a material in which the friction resistance is small to the guide rails 182 formed on the body 110 and the guide protrusions 184 formed on both side ends of the gate 120, respectively, face to face. Is attached to minimize the wear of the guide rail 182 and the guide protrusion 184 according to the lifting of the gate 120, the sliding plate 186 when the sliding plate 186 is worn by the lifting of the gate 120 for a long time ) Can be replaced easily.

Here, the gate 120 for elevating inside the body 110 to open and close the drain 112 formed in the upstream body 110a guides the flowing water flowing into the discharge pipe 10 formed upstream and downstream. It has a plate shape so as to block the open area of the drain 112 discharged to the.

In this case, the front, rear and left and right sides of the gate 120 may be stacked by the plate member 122 having a predetermined thickness as shown in FIG. 5 and the inside thereof is poured by concrete, and the plate member ( 122) is preferably coated with an rust preventive paint which prevents the green algae inhabiting and prevents corrosion and rust.

As such, the rod 140 having a predetermined length extends upwardly above the body 110 at an upper end of the gate 120 that is opened and lowered in the body 110 to open and close the drain 112. An idle bearing 142 is installed at a portion where the lower end of the rod 140 and the upper end of the gate 120 come into contact with each other, even though the rod 140 rotates while moving upward. ) And along the guide portion 180 formed on the gate 120 to move vertically inside the body 110.

In addition, the cover 111 is installed on the open upper portion of the body 110, the cover 111 is closed at the open upper portion of the body 110 at the same time the top of the body 110 of the gate 120 The rod 140 extending upward is rotatably supported.

And, the upper portion of the body 110 is provided with a winch 150 associated with the rod 140. The winch 150 is to provide the power to lift the vertically moving gate 120 in the interior of the body 110, the winch 150 is a mechanical or hydraulic cylinder exerts a force in accordance with the rotation of the motor It can be any one of the hydraulic type to exert a force according to the stretching, in some cases, as shown in Figure 3 and 4 handle is provided on the winch 150 is provided by the user rotates the handle to the gate 120 It may also provide power to elevate it.

On the other hand, the pressing unit 160 that is elevated in the rear of the gate 120 to advance the gate 120 toward the drain 112, the intimate contact between the gate 120 and the drain 112 is the gate ( 120 is provided at both rear sides.

The pressing unit 160 may include a rotation shaft 162 extending rearward of the gate 120 in a state of being supported by the cover 111 installed at the upper end of the body 110, and the rotation shaft 162. A wedge block 164 having a first inclined surface 164a rising and falling behind the gate 120 and a second inclined surface facing the first inclined surface 164a formed in the wedge block 164 according to rotation. An inclined surface 166a is formed and is formed of an inclined plate 166 integrally formed with the rear surface of the gate 120.

In other words, as shown in FIGS. 3 and 4, the rotation shaft 162 extends upward from the rear of the gate 120 so that an upper end of the rotation shaft 162 is installed at an upper end of the body 110. The upper end of the rotating shaft 162 is formed to penetrate the cover 111 to be exposed to the outside of the cover 111, and a handle 161 is provided at the upper end of the rotating shaft 162 to rotate the rotating shaft 162 according to a user's manipulation. do.

In addition, a lower end of the rotation shaft 162 positioned behind the gate 120 has a thread formed at an outer diameter thereof, and the thread penetrates an upper surface of the wedge block 164 in close contact with the rear surface of the gate 120. As the screw is fastened, the wedge block 164 is elevated in the rear of the gate 120 in accordance with the rotation of the rotary shaft 162.

In particular, the one surface of the wedge block 164 facing the rear surface of the gate 120 is inclined from the upper portion of the wedge block 164 to the lower side, the inclination of the lower portion than the upper portion of the wedge block 164 gate 120 The first inclined surface 164a is formed to be inclined closer to the rear surface of the back panel).

In addition, the inclined plate 166 is integrally formed on the rear surface of the gate 120, the wedge block 164 on the other surface of the inclined plate 166 facing the first inclined surface 164a of the wedge block 164. A second inclined from the top of the inclined plate 166 to the bottom to form a reverse slope with the formed first inclined surface 164a, the second of which is formed closer to the wedge block 164 than the bottom of the inclined plate 166 The inclined surface 166a is formed.

As such, the first inclined surface 164a and the second inclined surface 166a are respectively formed on the surface where the wedge block 164 and the inclined plate 166 face each other, and the first inclined surface 164a and the second inclined surface 166a are formed. When the wedge block 164 is raised from the rear of the gate 120 in a state of contacting, the drain 120 is formed in the upstream body 110a as shown in FIG. Advance toward and the front of the gate 120 is in close contact with the drain 112, on the contrary, when the wedge block 164 is lowered behind the gate 120, the gate 120 is Retreat from the drain 112.

In particular, as the above ascending and descending from the rear of the gate 120, the pressing unit 160 for advancing or retracting the gate 120 toward the drain 112 is provided on both sides of the rear of the gate 120, respectively As a result, the degree of airtightness of the gate 120 and the drain 112 in close contact with each other may be adjusted on both sides of the gate 120 to prevent leakage.

In addition, the support plate 114 of the downstream body 110b facing the rear surface of the gate 120 guides the wedge block 164 to be vertically moved without being rotated at the rear of the gate 120. Guide groove 113 is formed.

Such, the guide groove 113 is preferably formed of an anti-rotation cross section, such as a square groove as shown in the main portion enlarged in the lower right of Figures 4 and 5. Here, the anti-rotation cross section may be any shape other than a rectangular shape, that is, a triangular shape, a pentagon, a hexagonal shape, or the like.

On the other hand, the annular guide 130 is installed in the drain 112 in communication with the discharge pipe (10). Accordingly, the annular guide 130 moves horizontally from the upstream body 110a toward the downstream body 110b by the hydraulic pressure exerted by the hydraulic pressure discharged through the discharge pipe 10 or the fresh water having the fresh water. The annular guide 130 is in close contact with the front surface of the gate 120 to prevent leakage of water to a surface where the gate 120 and the annular guide 130 contact each other. This will be described based on FIG. 7.

6 is an enlarged cross-sectional view of part C of FIG. 4. Referring to the drawings, the annular guide 130 is installed in the drain 112 is along the circumference of the drain 112 for guiding the flow of water flowing through the discharge pipe 10 to the downstream body 110b. Is installed.

The annular guide 130 has an outer diameter larger than the outer diameter of the drain hole 112 formed by the end of the discharge pipe 10 and the upstream body 110a. A horizontal moving space 115 is formed at the rear end of the drain hole 112 so as to be recessed in the drain hole 112, and a fixing ring 134 is installed at the end of the horizontal moving space 115 to provide the annular guide 130. ) Acts as a stopper that is prevented from being separated from the horizontal moving space 115 by being pushed backward by the water pressure.

In addition, by forming an inclined wing 132 having an inner diameter of the annular guide 130 smaller than the inner diameter of the drain hole 112, the flowing water flows into the drain hole 112 through the discharge pipe (10). When the wing 132 is in contact with the flowing water to move the entire annular guide 130 toward the front of the gate 120 in a horizontal moving space as shown by the arrow shown in the drawing by the hydraulic pressure exerted in the flowing water. .

In particular, in the horizontal movement space 115 formed at the rear end of the drain hole 112 in which the annular guide 130 is moved horizontally, the annular guide 130 is pushed by the water pressure of the flowing water to the gate 120. An expansion packing 136 is provided so that a gap does not occur in a surface where the horizontal movement space 115 and the outer diameter of the annular guide 130 come into contact with each other when moving toward the front side of the horizontal moving space 115.

The expansion packing has a shape such as a rubber tube in which fluid supplied from the outside of the body 110 flows in and expands in volume thereof, and has an outer diameter between the annular guide 130 and the horizontal moving space 115. Is installed on.

To this end, a flow path 116 is formed inside the upstream body 110a to supply fluid supplied from the outside to the expansion packing, and an outer surface of the upstream body 110a at which the flow path 116 starts. The fluid inlet 117 is installed, the fluid inlet 117 is a fluid compressor (not shown) and the tube (not shown) installed outside the body 110, for example, above the body 110. Connected.

Accordingly, the fluid compressed in the fluid compressor is supplied to the fluid inlet 117 through a tube, and the fluid supplied to the fluid inlet 117 is expanded through the flow path 116 formed in the upstream body 110a. It is injected into the packing 136 to increase the volume of the expansion packing 136.

Here, a check valve (not shown) may be installed in the fluid inlet 117 to intermittently prevent the fluid introduced into the expansion packing 136 through the fluid inlet 117 from flowing backward.

In addition, a gap adjusting unit 170 that adjusts a moving distance of the annular guide 130 moving in the direction of flowing water from the drain hole 112 of the body 110 is provided on the outer surface of the upstream body 110a. do. This will be described based on FIG. 8.

FIG. 7 is an enlarged cross-sectional view of part D of FIG. 6. Referring to the drawings, the gap adjusting unit 170 is formed in the annular guide 130 and has a bottleneck shape facing the drain hole 112 of the body 110, and the slot A head 174 is interposed on the 172 and extends from the head 174 to pass through the upstream body 110a to be exposed to the outside, and fastening member fastened to the end of the bar 176. It is composed of 178.

Accordingly, when the fastening member 178 fastened to the end of the bar 176 is fastened to the slot 172 formed in the annular guide 130 while the bar 176 is advanced to the upstream body 110a. The interposed head 174 is pulled to move the annular guide 130 located in the horizontal moving space 115 to the upstream body 110a. On the contrary, when the fastening member 178 is released, the annular guide 130 is moved. The 130 moves toward the gate 120 to bring the annular guide 130 into close contact with the front of the gate 120 so that the leak does not occur in a portion where the gate 120 and the annular guide 130 contact each other. It can be adjusted.

When the fresh water is discharged through the discharge pipe 10, a drain hole formed in the body 110 is disposed in the drain hole 112 formed in the body 110 so that relatively heavy deposits such as stones, gravel and sludge do not accumulate. 112 forms an inclined bottom surface 112a that is directed downstream.

As described above, the inclined bottom surface (112a) is formed downstream in the drain hole 112, when the fresh water is discharged sediment, such as stones, gravel, sludge transported to the drain hole 112 with the flowing water drain ( Even if stacked on the bottom surface 112, the sliding surface of the inclined bottom surface (112a) formed in the drain hole 112 is moved to the downstream does not prevent the gate 120 is lowered and closed.

The operation of the discharge-type water gate 100 according to the present invention having the configuration as described above will be described based on FIG.

8 is a cross-sectional view of a portion of the gate and the pressing portion to show the operation of the discharge-type water gate according to the present invention. Referring to the drawings, after the final product assembly of the discharge-type water gate is leak-tested at the production site, or after the discharge-type water gate 100 is installed in a repair facility to perform the leak test.

At this time, the gate 120 is elevated in the body 110 is not in close contact with the annular guide 130 installed in the drain 112, in particular, the drain 112 to form a gap and through the gap When leakage occurs, the pressurizing unit 160 is operated to move the gate 120 toward the drain hole 112 so that the front surface of the gate 120 is provided in the drain hole 112 or the drain hole 130. ) In close contact with each other to close the gap of leakage.

That is, by operating the handles 161 located on both sides of the upper portion of the cover 111 to rotate each of the rotating shaft 162 extending to the rear of the gate 120, according to the rotation of the rotating shaft 162 As the wedge block 164 located at the rear of the gate 120 is moved up and down, the rear side of the gate 120 is pushed forward so that the front of the gate 120 is brought into close contact with the drain hole 112 or the annular guide 130 and leaks. This prevents any gaps that occur.

At this time, the wedge block 164 is guided by the guide groove 113 of the support plate 114 formed in the downstream body (110b) when the wedge block 164 is elevated in the rear of the gate 120 The wedge block 164 can be moved vertically without rotation.

In addition, when the annular guide 130 of the discharge-type water gate 100 of the present invention does not match the change of fresh water and flow rate at the construction site, the gap adjusting unit 170 is operated when the movement amount of the annular guide 130 is poor. As such, the position of the annular guide 130 located in the horizontal moving space 115 of the drain 112 may be manipulated so that the annular guide 130 may be in airtight contact with the front surface of the gate 120.

At this time, when the annular guide 130 is horizontally moved in the horizontal moving space 115 and a gap is generated between the annular guide 130 and the horizontal moving space 115, the outer surface of the upstream body 110a is disposed. The fluid is injected into the expansion packing 136 through the installed fluid inlet 117 to increase the volume of the expansion packing 136 to prevent a gap generated between the outer diameter of the annular guide 130 and the horizontal moving space 115. Do not leak.

Discharge-type water gate 100 according to the present invention as described above is provided with a pressing unit 160, respectively on both sides of the rear of the gate 120 is elevated in the interior of the body 110, the operation of the pressing unit 160 By advancing the gate 120 to the drain 112 or the annular guide 130 installed in the drain 112, the front of the gate 120 in close contact with the drain 112 or the annular guide 130 Also, make sure that no gap is formed.

In addition, by injecting a fluid supplied from the outside of the body 110 into the expansion packing 136 to increase the volume of the gap formed as the annular guide 130 moves in the direction of flowing water, the annular guide ( The expansion packing 136 blocks a gap generated between the outer diameter of the 130 and the horizontal moving space 115 so that no leakage occurs.

In addition, when the amount of movement of the annular guide 130 predicted and calculated according to the change of fresh water and flow rate does not match the amount of movement of the annular guide 130 of the discharge-type water gate 100 installed in the field, the upstream body 110a. The annular guide 130 is moved in a horizontal moving space by adjusting the clearance adjusting unit 170 installed through the annular guide 130 so that the annular guide 130 is in intimate contact with the front surface of the gate 120, so that no leakage occurs. Do not.

Then, by forming the bottom surface of the drain 112 formed in the body 110 to be inclined toward the downstream, sediment, such as stones, gravel, sludge transported to the drain with drainage when the fresh water is discharged to the drain 112 Even if stacked on the bottom surface (112a) of the inclined bottom surface formed in the drain 112 is moved to the downstream, so that the gate 120 does not prevent the closing.

Meanwhile, the present invention is not limited to the above-described embodiments, but may be modified and modified without departing from the scope of the present invention, and such modifications and variations should be regarded as belonging to the technical spirit of the present invention. .

For example, in the foregoing description, the first inclined surface 164a formed in the wedge block 164 is inclined from the top to the bottom thereof, and the inclination thereof is closer to the rear surface of the gate 120 than the top of the wedge block 164. The second inclined surface 166a of the inclined plate 166 formed to be inclined and integrally formed with the rear surface of the gate 120 facing the first inclined surface 164a of the wedge block 164 forms a reverse slope. As the wedge block 164 rises, the gate 120 is moved forward toward the drain 112. However, in some cases, the first inclined surface 164a of the wedge block 164 is opposite to the above description. When the second inclined surface 166a of the inclined plate 166 facing the first inclined surface 164a forms a reverse slope, the wedge block 164 is lowered so that the gate 120 is drained. Advance toward 112 so that the front of the gate 120 Sewer is tightly in contact with the (112) or the annular guide 130 will also prevent water leakage from occurring.

10: discharge pipe 100: discharge water gate
110: body 111: cover
112: drain 112a: bottom surface
113: guide groove 114: support plate
115: horizontal movement space 116: euro
117: fluid inlet 120: gate
130: annular guide 122: plate
132: wing 134: retaining ring
136: expansion packing 140: rod
150: winch 160: pressurizing unit
162: rotation axis 164: wedge block
164a: first inclined surface 166: inclined plate
166a: second inclined surface 170: gap adjusting portion
172: slot 174: head
176 bar 178 tightening member
180: guide portion 182: guide rail
184: guide protrusion 186: sliding plate

Claims (6)

A body formed with a drain hole communicating with the discharge pipe installed upstream; An annular guide provided in a drain hole formed in the body to be inclined to contact the flowing water discharged through the discharge pipe and supported by a fixing ring fixed to the drain hole; A gate that opens and closes the drain hole by elevating along a guide formed in the body; A rod extending above the body from an upper end of the gate; A winch which is connected with the rod to provide power for lifting the gate; And pressurizing parts provided on both rear sides of the gate, respectively, to move the gate toward the drain hole and to closely contact the gate and the drain hole while lifting up and down.
The pressing unit,
A rotating shaft supported by the upper end of the body and extending rearward of the gate;
A wedge block having a first inclined surface configured to move up and down behind the gate according to the rotation of the rotation shaft; And
And an inclined plate having a second inclined surface having a reverse slope facing the first inclined surface formed on the wedge block, the inclined plate integrally formed with the rear surface of the gate. delete The method according to claim 1,
Discharge-type water gate, characterized in that the guide groove for guiding the wedge block rising and falling from the rear of the gate, the guide groove is formed in the anti-rotation cross section. The method according to claim 1,
An expansion packing interposed between the annular guide and the inner diameter of the drain port and expanded by a fluid supplied from the outside to seal between the annular guide and the drain hole inner diameter; And
And a fluid inlet having a flow path for guiding the fluid to the expansion packing and having a check valve at an inlet through which the fluid is introduced. The method according to claim 1,
It further comprises a gap adjusting unit for moving the annular guide to adjust the gap between the annular guide and the drain hole of the body,
The gap adjusting unit,
A slot formed in the annular guide and having a bottleneck shape facing the drain hole of the body;
A head interposed in the slot and extending from the head to penetrate the body and be exposed to the outside; And
Discharge-type sluice comprising a fastening member fastened to the end of the bar. The method according to claim 1,
Discharge-type water gate, characterized in that the inclined bottom surface is formed downstream to the drain formed in the body.

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