KR100539323B1 - Apparatus for opening closing hydraulic floodgate - Google Patents

Abstract

The present invention relates to a hydraulic gate opening and closing device that can be opened and closed each of the multiple gates quickly and safely with a single hydraulic device, and also can be easily installed at a low cost and less trouble.

According to the present invention, in the water gate 20 assembled to be lifted and lowered to the door frame 10, the water gate fixing frame 30 is installed at both sides of the door frame 10 and includes a multi-stage locking plate 31; An upper cylinder 40 for raising the sluice which is built in the upper part of the sluice 20 and has a lifting chamber 41 and 42; A height adjustment stopper 50 which is coalesced with a tension spring S so as to be protruded on both lower sides of the sluice 20 and caught on the locking plate 31; It is installed in the lower portion of the upper cylinder 40, the lower cylinder 60 for the hydro lock fixing to operate the stopper 50; An oil pressure supply unit 90 connected to the oil tank 70 and the accumulator 80 by a hydraulic line to supply oil pressure to the upper and lower cylinders 40 and 60; An upward rotation valve 100 and a downward rotation valve 200 connected to the accumulator 80 and the upper and lower cylinders 40 and 60 by a hydraulic line to control the hydraulic direction; Is connected to the lower chamber 42 of the upper cylinder 40 by a hydraulic line is composed of a height gauge 300 for measuring the height of the water gate 20.

Description

Apparatus for opening closing hydraulic floodgate}

The present invention relates to a water gate installed in a reservoir or a river dam to adjust the water level, and more particularly, it is possible to open and close the multiple water gates quickly and safely with a single hydraulic device, respectively, and it is easy to trouble-free and at low cost. It is related with the hydraulic gate opening and closing device which can be installed easily.

In general, since the water level is manually operated to control the water level of the low water and the discharge amount, there is a problem that it is difficult to effectively manage water and requires a large number of management personnel.

In order to solve this problem, an automatic sensing gate opening and closing device using a sensor has been developed. However, it has been pointed out that the sensor's ability to detect or the sensor is corroded by water does not function properly. It is not widely used due to economic problems such as need.

Therefore, the conventional manual and electronic water gate opening and closing device as described above is unable to manage the reservoir safely and conveniently, causing flooding, flooding, or water backflow, causing enormous damage such as a year of farming. There was this.

In addition, the conventional water gate opening and closing device has a problem that it takes a long time to structurally increase the water gate, in particular, in order to open and close the water gate there was a problem that each switchgear must be installed respectively. That is, in the related art, since a plurality of gates cannot be opened and closed by a single opening and closing device, there is an inconvenience and an uneconomical problem of opening and closing each of the gates in a state where the opening and closing devices are installed in each of the gates.

On the other hand, in recent years, a structure for opening and closing a water gate by using a motor has been proposed, but since it is to open and close the water gate by the rotational force of the motor, extra energy is required, especially when electricity is not supplied, the water gate may be moved. There was a disadvantage.

An object of the present invention is to invent the above-mentioned conventional drawbacks, it is possible to open and close each of the multiple gates quickly and safely with a single hydraulic device, and also easy to install with little trouble and low cost To provide a hydraulic gate opening and closing device.

In order to achieve the above object, the present invention is to install a sluice fixing frame having a multi-stage locking plate on both sides of the door frame, a built-in upper cylinder for sluice rising in the upper part of the water gate, the height of the locking plate on both sides of the lower door An adjustable stopper is installed to be retractable, and a lower cylinder for sluice fixing to operate the stopper is installed below the upper cylinder, and the hydraulic supply means for supplying hydraulic pressure to the upper and lower cylinders is connected to a hydraulic line, Up and down cylinders for controlling the hydraulic direction to the upper and lower cylinders for connecting the lower rotary valves in the hydraulic line, and the height gauge for measuring the height of the water gate to the lower chamber of the upper cylinder is connected to the hydraulic line.

Hereinafter, the technical configuration of the present invention according to the accompanying drawings in detail.

1 to 14, the hydraulic door opening and closing device of the present invention, in the water gate 20 assembled to be liftable to the door frame 10, is installed on both sides of the door frame 10, the multi-stage locking plate A sluice lock frame (30) having (31); An upper cylinder (40) for raising the sluice which is built in the upper part of the sluice (20) and has a lifting chamber (41) (42); A height adjustment stopper 50 which is coalesced with a tension spring S so as to be protruded on both lower sides of the sluice 20 and caught on the locking plate 31; It is installed in the lower portion of the upper cylinder 40, the lower cylinder 60 for the hydro lock fixing to operate the stopper 50; An oil pressure supply unit 90 connected to the oil tank 70 and the accumulator 80 by a hydraulic line to supply oil pressure to the upper and lower cylinders 40 and 60; An upward rotation valve 100 and a downward rotation valve 200 connected to the accumulator 80 and the upper and lower cylinders 40 and 60 by a hydraulic line to control the hydraulic direction; The lower cylinder 42 of the upper cylinder 40 is connected to the hydraulic line is configured to include a height gauge 300 for measuring the rising height of the sluice 20 is a basic feature of the technical configuration.

Here, vertical holes 11 through which the stopper 50 penetrates are respectively drilled on both sides of the door frame 10 as shown in FIGS. 3 and 4A and 4B.

A plurality of rollers 21 are installed on both upper and lower sides of the sluice gate 20 to easily move up and down as shown in FIGS. 1 and 3.

The sluice fixing frame 30 is attached to the outside of the vertical long hole 11 formed in the door frame 10, as shown in Figure 3 and 4a, 4b, the stopper 50 is caught inside the sluice fixing frame 30 The stopping plate 31 is installed in multiple stages.

The upper cylinder 40 is built in the central upper portion of the sluice 20 to lift the sluice 20, as shown in Figures 4a, 4b, the inner cylinder of the upper cylinder 40 is lifted by a piston 43 A seal 41 and a lower chamber 42 are provided, and an upper end of the piston rod 44 vertically reciprocating into the upper cylinder 40 is fixed to the upper part of the door frame 10, and inside the piston rod 44. First, second and third hydraulic lines (1) (2) (3) are installed through. At this time, the first hydraulic line 1 is in communication with the lifting chamber 41, the second hydraulic line 2 is in communication with the lower cylinder 60, the third hydraulic line 3 is the lower chamber 42 and Communicating.

Therefore, when the hydraulic pressure is supplied into the lifting chamber 41 of the upper cylinder 40 through the first hydraulic line 1, the lifting chamber 41 is expanded by the pressure of the hydraulic pressure supplied, so that the water gate 20 is automatically raised. When the hydraulic supply supplied to the first hydraulic line 1 is stopped, the water gate 20 is closed while descending by its own weight, and the elevator 41 is compressed by the water gate 20 which is lowered, so the elevator chamber ( The hydraulic pressure supplied to 41 is discharged to the first hydraulic line 1 by the pressure to be compressed and returned to the oil tank 70.

The stopper 50 is installed in the tension spring S so that the stopper 50 is protruded on both lower sides of the sluice 20, and is caught by the locking plate 31, and the outer side of the stopper 50 as shown in FIGS. 4A, 4B and 5. The upper end is formed in an arc-shaped round, and the inner end of the stopper 50 is formed as an inclined surface. At this time, the stopper 50 is installed in the casing 51, both ends of the tension spring (S) is connected to the stopper 50 and the casing (51).

The lower cylinder 60 is installed in the lower portion of the upper cylinder 40 to operate the stopper 50, as shown in Figure 4a, 4b and 5 piston 61 for vertical reciprocating motion into the lower cylinder (60) A spring 62 is installed in the lower portion of the lower portion of the piston rod 63, and the push rod 64 formed on both sides of the inclined surface is installed at the lower portion of the piston rod 63.

Therefore, when the hydraulic pressure is supplied into the lower cylinder 60 through the second hydraulic line 2, the push rod 64 is lowered while pushing the both stoppers 50 outwards, and when the hydraulic supply is stopped, the spring 62 is stopped. Is raised by the restoring force of and at the same time the hydraulic pressure supplied to the lower cylinder 60 is returned. At this time, the second hydraulic line (2) which is located inside the upper cylinder 40 is formed in the same shape as the coil spring so that it can be expanded and contracted according to the lifting operation of the water gate 20, as shown in Figure 4a, 4b.

The oil tank 70, the accumulator 80 and the hydraulic supply means 90 is connected to the hydraulic line as shown in FIG.

The accumulator 80 is provided with first and second supply ports 81 and 82, and third, fourth, fifth and sixth return ports 83, 84, 85 and 86. A pressure gauge 87 is provided to return undesired pressure to the oil tank 70 while maintaining a constant pressure.

The hydraulic pressure supply unit 90 is connected to the oil tank 70 and the accumulator 80 by a hydraulic line to supply hydraulic pressure to the upper and lower cylinders 40 and 60, according to an embodiment of the present invention. The supply means 90 consists of a set of hydraulic jacks 91 and 92 and a set of foot plates 93 and 94 for operating the two hydraulic jacks 91 and 92 as shown in FIGS. 1 and 6. It is done. Therefore, when the operator stepped on both sides of the foot (93) (94) alternately by this the hydraulic jack (91) (92) generates a pressure in the hydraulic line while repeating the vertical reciprocating movement can be operated by the hydraulic device manually.

On the other hand, the hydraulic supply end 90 according to another embodiment of the present invention is characterized in that it consists of a motor 95 and the oil pump (96). Therefore, when the motor 95 is driven using electricity, the oil pump 96 operates to generate pressure in the hydraulic line, thereby enabling the hydraulic apparatus to be electrically operated.

The lifting rotary valve 100 is a housing 110 having a plurality of valve chambers 113 having inlet, outlet 111, 112, respectively, as shown in Figures 9 to 11, the valve chamber 113 The ball 121 is installed in the spring 121 to open and close the inlet 111, the operation pin 130 is built in the valve chamber 113 so as to be movable up and down and contacts the spring 121, and the housing. A pin groove 141 is provided to be rotatably assembled on an upper portion of the 110 to selectively insert one operation pin 130 into the bottom surface thereof, and an inclined surface 142 which induces one direction rotation to one side of the pin groove 141. Rotation cap 140 is formed, the handle 150 is provided on the top of the rotary cap 140. At this time, it is preferable to form four valve chambers 113 in the rotary valve 100 for the lift.

In the following description, for convenience of description, the valve device, which consists of the ear ball 120, the spring 121, and the operation pin 130, is installed in each of the four valve chambers 113, first, second, third, and third. Four valves V1, V2, V3, and V4 will be described.

Accordingly, if the pin groove 141 of the rotary cap 140 is selectively positioned among the four valve devices by turning the handle 150, the operation pin 130 of the corresponding valve device is the pin groove ( 141, so that the ear ball 120, which is installed with the spring 121 in the lower portion of the operation pin 130 inserted into the pin groove 141 is opened to open the corresponding inlet 111, but the remaining three valve device The operating pin 130 is closed because it is pressed in contact with the bottom surface of the rotary cap 140. That is, for example, by turning the handle 150 to position the pin groove 141 of the rotary cap 140 in the first valve V1, the first valve V1 opens but the remaining first, second and third valves. (V2) (V3) (V4) are closed.

In addition, since the inclined surface 142 is formed at one side of the pin groove 141, the rotation cap 140 is easily rotated in the direction in which the inclined surface 142 is formed, but the rotation in the opposite direction of the inclined surface 142 is not easy. Therefore, the rotation cap 140 is rotated only in one direction by the inclined surface 142.

The lower rotary valve 200 is a housing 210 having a plurality of valve chambers 213 having inlets and outlets 211 and 212, respectively, as shown in FIGS. 12 and 13, and the valve chamber 213. The ear ball 220 is installed in the spring 221 to open and close the inlet 211, the operation pin 230 is built in the valve chamber 213 to be moved up and down to contact the spring 221, the housing Two pin grooves 241 are rotatably assembled at an upper portion of the upper portion 210 so that two operation pins 230 may be selectively inserted into the bottom surface thereof, and one side of the pin grooves 241 may be inclined to induce one-way rotation. Rotating cap 240 is formed 242, the handle 250 is provided on the upper portion of the rotating cap 240. At this time, it is preferable to form four valve chambers (213) in the rotary valve (200).

Hereinafter, for convenience of description, the valve device which consists of the ear ball 220, the spring 221, the operation pin 230, and is installed in the four valve chambers 213, respectively, is 5th, 6th, 7th, 5th Eight valves V5, V6, V7, and V8 will be described.

Accordingly, when the pin groove 241 of the rotary cap 240 is selectively positioned among the four valve devices by turning the handle 250, the operation pin 230 of the corresponding valve device is the pin groove ( 241, so that the ear ball 220, which is installed with the spring 221 in the lower portion of the operation pin 230 fitted in the pin groove 241 is opened to open the corresponding inlet 211, but the remaining two valve device The operating pin 230 is closed because it is pressed in contact with the bottom surface of the rotary cap 240. That is, for example, when the pin groove 241 of the rotary cap 240 is turned on the fifth valve V5 and the sixth valve V6 by turning the handle 250, the fifth and sixth valves V5 and V6 are located. Is opened but the remaining two seventh and eighth valves V7 and V8 are closed.

Since the inclined surface 242 is formed at one side of the pin groove 241, the rotation cap 240 is easily rotated in the direction in which the inclined surface 242 is formed, but the rotation in the opposite direction of the inclined surface 242 is not easy. Therefore, the rotation cap 240 is rotated only in one direction by the inclined surface 242.

The upper portion of the operation pins 130 and 230 respectively installed on the upward rotation valve 100 and the downward rotation valve 200 is formed in a hemispherical round as shown, and also the operation pins 130 and 230. The pin grooves 141 and 241 are fitted into the shape of a hemispherical round corresponding thereto, and the rubber packing for airtightness is fitted to the outer circumferential surface of the operation pins 130 and 230, respectively.

The height gauge 300 is connected to the lower chamber 42 of the upper cylinder 40 by a third hydraulic line (3) to measure the height of the water gate 20, such height gauge as shown in FIG. Inside the cylinder 310 constituting the 300, the piston 320 is coalesced with a spring 330, the return line 340 is connected to the upper and lower portions of the cylinder 310, the outer peripheral surface of the cylinder 310 The scale is displayed.

Therefore, when the descending chamber 42 is contracted when the water gate 20 is raised, the pressure is supplied to the height gauge 300 through the third hydraulic line 3, so that the piston 320 may move the spring 330. While descending while compressing, the user can measure the elevation of the water gate 20 through a scale marked on the outside of the cylinder 31.

Figure 2 is an exemplary view showing a state in which two sluice 20 is installed according to an embodiment of the present invention, as shown in the present invention, by installing two or more sluices 20 in a single hydraulic device to a number of sluice The device can be opened and closed.

That is, in the embodiment of the present invention, the sluice gate 20 is provided with a plurality of two or more, and the rotary valve 100, 200 for controlling the hydraulic direction supplied to the upper and lower cylinders 40, 60 is It is installed in each of the water gate 20, the height gauge 300 is connected to each of the lower cylinder 60 is also installed, respectively, the rotary valves 100, 200 are respectively installed in each of the water gate 20 is one It is connected to the accumulator 80.

On the other hand, Figure 14 is a hydraulic circuit diagram showing a hydraulic line of the present invention, as shown in the first hydraulic line 1 is the outlet of the first valve (V1), the inlet of the fourth valve (V4), the fifth valve It is connected to the inlet and outlet of (V5), the inlet of the seventh valve (V7), respectively, the second hydraulic line (2) is the outlet of the second valve (V2), the inlet of the third valve (V3), the sixth It is connected to the inlet and outlet of the valve V6, and the inlet of the eighth valve V8, respectively.

In addition, the first supply port 81 of the accumulator 80 is connected to the inlet of the first valve (V1), the second supply port 82 is connected to the inlet of the second valve (V2), the third return The port 83 is connected to the outlet of the third valve V3, the fourth return port 84 is connected to the outlet of the fourth valve V4, and the fifth return port 85 is connected to the seventh valve V7. ), And the sixth return port 86 is connected to the outlet of the eighth valve (V8).

Referring to the overall operating relationship of the present invention configured as described above in detail.

First, FIG. 1 and FIG. 4A illustrate a state in which the sluice 20 is closed. When the hydraulic pressure supply unit 90 is operated in this state, the pressure accumulates in the accumulator 80. When the lower rotary valve 200 is rotated to open the fifth and sixth valves V5 and V6, the upward rotary valve 100 is rotated to open the first valve V1 to accumulate the accumulator 80. The accumulated hydraulic pressure is supplied to the lifting chamber 41 of the lifting cylinder 40 through the first supply port 81 and the first hydraulic line 1, whereby the water gate 20 is raised as shown in FIG. 4B. Is opened.

As shown in FIG. 4B, the lower chamber 42 of the elevating cylinder 40 is compressed during the operation in which the gate 20 is opened, so that the pressure in the lower chamber 42 is increased through the third hydraulic line 3. Since it is supplied to 300, the operator can measure the height by which the gate 20 is opened while checking the height through which the piston 320 of the height gauge 300 descends through the scale.

After confirming that the water gate 20 is opened to a desired height, when the upward rotation valve 100 is rotated to open the second valve V2, the first hydraulic line 1 is blocked and the second supply port 82 is closed. Since the hydraulic pressure is supplied to the lower cylinder 60 through the second and second hydraulic lines 2), as shown in FIG. 4B, as the pusher 64 descends, both stoppers 50 protrude outwards, and as shown in FIG. 4C. As a result, the stopper 50 is fitted into the locking plate 31 of the sluice fixing frame 30.

In the above-described state of FIG. 4D, when the upward rotary valve 100 is rotated to open the third valve V3, the hydraulic pressure of the second hydraulic line 2 is accumulated through the third return port 83. It is returned to, and the push rod 64 is thereby returned to its original state by the restoring force of the spring (62). At this time, since the weight of the stopper 50 protruding outward is greater than the restoring force of the tension spring S, the stopper 50 is maintained in the protruding state without returning to the original state.

Thereafter, when the upward rotation valve 100 is rotated to open the fourth valve V4, the hydraulic pressure of the first hydraulic line 1 is returned to the accumulator 80 through the fourth return port 84, whereby the water gate 20 tries to descend by its own weight, but at this time, the stopper 50 protruding outwardly hangs on the latching plate 31 so that the water gate 20 remains open without descending.

In FIG. 4E, the operation of lowering the raised gate 20 as described above will be described below. First, when the rising rotary valve 100 is rotated to open the first valve V1, the first supply port 81 and Hydraulic pressure is supplied to the lifting chamber 41 of the lifting cylinder 40 through the first hydraulic line 1 so that the water gate 20 is raised, and the stopper 50 protruding outwards is like the water gate 20. When it is pushed inward while being caught by the locking plate 31 while being raised, the restoring force of the tension spring S is generated and the stopper 50 is returned to its original state.

In FIG. 4F, when the lower rotary valve 200 is rotated to open the seventh and eighth valves V7 and V8, the hydraulic pressure of the first hydraulic line 1 is changed to the fifth return port 85. Is rapidly returned to the accumulator 80, whereby the sluice 20 is closed quickly while descending by its own weight.

Therefore, the present invention has the advantage that it is possible to effectively and properly control the water level of the reservoir and discharge amount through the hydraulic device, there is an advantage to manage the reservoir more safely and conveniently, and also the present invention has a structurally low failure and install at a low cost There are advantages to it.

In addition, the present invention can automatically adjust the sluice 20 by operating the rotary valve 100, 200 can reduce the manpower and at the same time open and close multiple sluice 20 with a single hydraulic device, respectively, quickly and safely There is an advantage to this.

And according to the present invention, by using a set of hydraulic jacks (91) (92) and the footrest (93) (94) in the hydraulic supply means 90 can be operated by the hydraulic device manually so even when the electricity is not supplied 20) there is an advantage that can be easily opened and closed.

Meanwhile, in the embodiment of the present invention, the height gauge 300 and the rotary valves 100 and 200 are respectively installed in each of the gates 20 in a state where a plurality of the gates 20 are installed in one accumulator 80. When connected to the same hydraulic line, there is an advantage that can be opened and closed each gate 20 by a single hydraulic device without separately installing the switchgear to each gate as in the prior art.

As described above, the hydraulic hydrogate opening and closing device of the present invention is a very useful invention that can open and close multiple hydrological gates with a single hydraulic device quickly and safely, respectively, and can be easily installed at a low cost and with little trouble.

1 is an overall configuration diagram schematically showing the structure of the present invention.

2 is an exemplary view showing a state in which two water gates are installed according to an embodiment of the present invention.

Figure 3 is an exploded perspective view showing the structure of the water gate and the door frame according to the present invention.

Figure 4a, 4b, 4c, 4d, 4e, 4f is a cross-sectional view showing the operating state of the water gate according to the present invention.

5 is an exploded perspective view of the stopper according to the present invention.

Figure 6 is an exemplary view showing an embodiment of the hydraulic pressure supply means according to the present invention.

7 is an exemplary view showing another embodiment of the hydraulic supply means according to the present invention.

8 is a cross-sectional view showing a structure of a height gauge according to the present invention.

Figure 9 is an exploded perspective view showing the structure of the rotary valve for lift in accordance with the present invention.

10 is a cross-sectional view of FIG.

FIG. 11 is a cross-sectional view taken along the line AA of FIG. 10. FIG.

12 is an exploded perspective view showing the structure of the rotary valve for descending in accordance with the present invention.

13 is a cross-sectional view of the combination of FIG.

14 is a hydraulic circuit diagram showing a hydraulic line of the present invention.

<Code Description of Main Parts of Drawing>

10: door frame 20: sluice

30: sluice fixing frame 31: stopping plate

40: upper cylinder 41: lifting room

42: descent chamber 50: stopper

60: lower cylinder 70: oil tank

80; Accumulator 90: Hydraulic supply means

100,200: Rotating valve 300: Height gauge

Claims (7)

In the water gate 20 is assembled to the door frame 10 to be elevated, the water gate fixing frame 30 is provided on both sides of the door frame 10 having a multi-stage locking plate 31; An upper cylinder (40) for raising the sluice which is built in the upper part of the sluice (20) and has a lifting chamber (41) (42); A height adjustment stopper 50 which is coalesced with a tension spring S so as to be protruded on both lower sides of the sluice 20 and caught on the locking plate 31; It is installed in the lower portion of the upper cylinder 40, the lower cylinder 60 for the hydro lock fixing to operate the stopper (50); A hydraulic pressure supply unit 90 connected to the oil tank 70 and the accumulator 80 by a hydraulic line to supply hydraulic pressure to the upper and lower cylinders 40 and 60; An upward rotation valve 100 and a downward rotation valve 200 connected to the accumulator 80 and the upper and lower cylinders 40 and 60 by a hydraulic line to control the hydraulic direction; A hydraulic gate opening and closing device comprising a height gauge 300 is connected to the lower chamber 42 of the upper cylinder 40 by a hydraulic line to measure the height of the gate 20. According to claim 1, wherein the upper end of the outer end of the stopper 50 is formed in an arc-shaped round, the inner end of the stopper 50 is formed in the inclined surface, the stopper 50 is built in the casing 51, Both ends of the tension spring (S) is connected to the stopper 50 and the casing 51, the spring 62 is installed in the lower portion of the piston 61 vertically reciprocating into the lower cylinder 60, the piston rod ( The lower portion of the 63) hydraulic side door opening and closing device is characterized in that both sides are formed in the inclined surface to push the stopper (50) to the outside when protruding when pushed down. 2. The hydraulic supply means (90) according to claim 1, characterized in that the hydraulic supply means (90) consists of a set of hydraulic jacks (91) (92) and a set of scaffolds (93) (94) for operating the two hydraulic jacks (91) (92). Hydraulic hydro switchgear. 2. The hydraulic waterway opening and closing device according to claim 1, wherein the hydraulic supply end (90) comprises a motor (95) and an oil pump (96). According to claim 1, The rotary valve for lift 100 is a housing 110 having a plurality of valve chamber 113 having inlet, outlet 111, 112, respectively, the spring in the valve chamber 113 The ball 120, which is carbonized by the 121 and opens and closes the inlet 111, the operation pin 130 which is built in the valve chamber 113 so as to be movable up and down and contacts the spring 121, and the housing 110. Is rotatably assembled on the upper part thereof, and a pin groove 141 is provided to selectively insert one operation pin 130 into the bottom surface thereof, and one side of the pin groove 141 has an inclined surface 142 for inducing one-way rotation. Hydraulic sluice door opening and closing device, characterized in that made of a rotating cap 140, the handle 150 provided on the upper portion of the rotating cap 140. According to claim 1, The lower rotary valve 200 is a housing 210 having a plurality of valve chambers 213 having inlet, outlet 211, 212, respectively, the spring in the valve chamber 213 221, the ear ball 220 to open and close the inlet 211, the operation pin 230 is built in the valve chamber 213 to be moved up and down in contact with the spring 221, the housing 210 Two pin grooves 241 are rotatably assembled at an upper part thereof so that two operation pins 230 are selectively inserted into the bottom thereof, and an inclined surface 242 which induces one direction rotation to one side of the pin grooves 241. The hydraulic cap opening and closing device characterized in that consisting of a handle formed on the top of the rotating cap 240, the rotating cap 240 is formed. According to claim 1, wherein the water gate 20 is provided with a plurality of two or more, the rotary valve 100, 200 for controlling the hydraulic direction supplied to the upper and lower cylinders 40, 60 is a water gate ( 20 are respectively installed, the height gauges 300 are connected to the lower cylinder 60, respectively, and each of the rotary valves 100 and 200 installed at each of the floodgates 20 is one accumulator 80. Hydraulic door lock, characterized in that connected to).