KR200171459Y1 - Oil pressure type water gate moving device - Google Patents

Abstract

The present invention relates to a hydraulic hydrograph, a hydraulic pump, a hydraulic cylinder actuated by the hydraulic pump, and a hydraulic hydrograph that is attached to the hydraulic cylinder to move the water gate, generating hydraulic pressure on the upper portion of the hydraulic pump It is provided with a hydraulic pump handle that can be made, and on the other side of the upper side of the hydraulic pump is formed a hydraulic conveying portion which determines the direction of the hydraulic pressure by the change valve, and the upper and lower connectors are respectively formed in the hydraulic conveying portion, the middle of the lower connector A pilot check valve is provided at a predetermined position, and the upper and lower connectors are used to transfer the hydraulic pressure to the hydraulic cylinder. A height measuring port and a height measuring gauge are attached to the outside of the hydraulic cylinder, and the hydraulic cylinder has a movable rod for moving the water gate. It is configured to be connected so that it can be easily operated manually without supplying external energy such as electricity or oil. After that, and so can be the same, and so can be found in the contact place by a movement in height in a simple sluice device moving device is installed, the water gate will rise to a height that can be maintained as it is.

Description

Hydraulic Hydro Shifter

The present invention relates to a hydraulic hydrograph, in particular, a hydraulic pump for raising a rack for raising a hydrogate by a hydraulic pump, and allowing the hydrostatic gate raised by the hydraulic pump to be maintained in an un lowered state. Relates to a device.

In general, those who use water have stored a large amount of water in a predetermined place, and a water gate is formed in a predetermined place such as a dam, a reservoir, a pond, and the like so that the water stored in the reservoir can be moved out.

By the way, the water gate may be operated by a human hand, but when the water pressure of the reservoir or the like is heavy or the weight of the water gate is heavy, it is difficult to move the water gate to the human hand. Therefore, by installing a power generating unit such as a motor in the water gate as described above, even if high water pressure acts on the water gate or the weight of the water gate is high, the height of the water gate can be adjusted to adjust the amount of water discharged or to adjust the water level of the dam. It was.

As a device for moving the water gate, a rack bar 12 is formed on both sides of the water gate 11 for blocking water, as shown in the schematic diagram of FIG. A predetermined portion of the rack bar 12 is configured a gear group 13 for transmitting the rotational force of the gear, the rotating shaft 14 configured to transmit the rotational force to the gear group 13 is the driving force in the power transmission unit 15 Received, the predetermined portion of the power transmission portion 15 has a handle portion 16, a drum portion 17, a gear portion 18 and a stop portion 19, the upper portion of the power cut-off portion 15 The power generation unit 20 for generating a drive unit is formed.

In the conventional hydrological transfer device configured as described above, when a user sends a signal to the power generation unit 20, a rotational force is generated in the power generation unit 20, and the driving force generated in the power generation unit 20 is power. The drum 17 is rotated through the transmission unit 15, and the driving force for rotating the drum 17 is transmitted to the gear group 13 by rotating the rotation shaft 14, and to the gear group 13. The transmitted rotational force was converted into a linear motion by the rack bar 12 and transmitted to the sluice 11, and the sluice 11 to which the linear motion was transferred was lifted to open the waterway.

When the locking device of the stop 19 is released to close the open channel as described above, the water gate 11 is lowered by its own weight. Thus, the lowered sluice 11 blocks the waterway and prevents water from entering.

In order to transfer power to the above-mentioned general hydrograph moving device, the rack bar 12 installed perpendicular to the water gate and the pinion installed on the rotating shaft are engaged with each other, and the reduction gear installed on one axis of the rotating shaft and the reduction gear in the center are installed. The pinion installed at both ends of the rotary shaft 14 is engaged, and the reduction gear installed at the center of the rotary shaft 14 is engaged with the pinion installed at the power transmission intermediate shaft, and the reduction gear is fitted with the pinion installed at the center of the power transmission shaft. The driving device, which is the power generating part, is connected to the geared power transmission shaft.

In the related art, when the power transmission shaft is rotated, the rotation shaft is rotated by each reduction gear and pinion. The pinion installed at both ends rotates the reduction gear installed at the rotation shaft. To raise the installed rack bar (12).

FIG. 2 is a perspective view showing a conventional winch machine, which comprises a spindle 82 at the lower side of the horizontal winch machine 80 having a handle 81 on the upper side thereof, and a water gate 83 is fixed at the lower side of the spindle 82. It was. That is, when the handle 81 formed on the upper side of the lateral winch 80 is turned in one direction, the spiral spindle 82 moves upward, and when the spindle 82 moves upward, the spindle 82 moves upward. The water gate 83 provided on the lower side is moved to the upper side. In addition, when the knob 81 is turned in the opposite direction, the spindle 82 moves downward, and when the spindle 82 moves downward, the water gate 83 also moves downward.

However, since the conventional hydro gate power transmission device rotates the motor by electricity and transfers the gate by the rotational force, extra energy is required, and when the electricity is not supplied, the hydro gate cannot be moved. There was a downside.

And, as shown in FIG. 2, there was a manual movement of the water gate, but a lot of power was consumed because it was to force the person to raise the water gate by turning the handle by force. There was a problem.

In addition, in the prior art, the device for transferring the water gate was not provided with a gauge capable of measuring the height of the water gate, so it was necessary to check the gauge separately provided in the water gate to check the height of the water gate. Therefore, in order to check the height of the water gate, there is a problem in that it is possible to check the height of the water gate by moving from the place where the water gate transfer device is provided to the water gate. Of course, in addition to the above case there is a device that can check the height of the water gate through the digital gauge in the hydrological transfer device, but the device was expensive and was not a device that can be easily mounted.

And, in the past, there was a device for hydraulically moving the floodgate, but the hydraulic floodgate is leaked in the unsealed state of the hydraulic pump when the work of moving the water out by fixing it after raising the floodgate. There was a disadvantage that the gate to be stopped gradually descended.

Therefore, the present invention has been conceived in view of such a situation, and its purpose is to enable easy manual movement of the water gate without supplying external energy such as electricity or oil.

In addition, the present invention has another object to be able to check the moving height of the water gate in the place where the water gate device is installed by a simple device.

In addition, the present invention has yet another object of maintaining its height even after raising the floodgate.

The present invention is to produce a hydraulic pressure in the upper portion of the hydraulic pump in the hydraulic pump, a hydraulic cylinder operated by the hydraulic pump, and a hydraulic hydrograph moving device attached to the hydraulic cylinder to move the water gate to achieve the above object. It is provided with a hydraulic pump handle that can be made, and on the other side of the upper side of the hydraulic pump is formed a hydraulic conveying portion which determines the direction of the hydraulic pressure by the change valve, and the upper and lower connectors are respectively formed in the hydraulic conveying portion, the middle of the lower connector A pilot check valve is provided at a predetermined position, and the upper and lower connectors are used to transfer the hydraulic pressure to the hydraulic cylinder, and a height measuring port and a height measuring gauge are attached to the outside of the hydraulic cylinder, and the hydraulic cylinder has a movable rod for moving the water gate. By configuring the connection, it is possible to move the floodgate in simple operation, And so as to be maintained, it can be moved by the contact height so that you can see in the hydrological mobile devices.

1 is a front view showing a general hydrological device.

2 is a perspective view showing a conventional hoisting machine.

3 is a perspective view showing the present invention.

Figure 4 is a side view showing the present invention.

5 is a cross-sectional view showing a valve used in the present invention,

Figure 5 (a) is a cross-sectional view showing the free flow of hydraulic pressure.

Figure 5 (b) is a cross-sectional view showing a state in which the hydraulic pressure is closed.

Figure 5 (c) is a cross-sectional view showing a state in which the hydraulic pressure is opened at the pilot pressure.

6 is a perspective view showing another embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

30: hydraulic pump 31: hydraulic pump handle

33: change switch 34: hydraulic feeder

37: pilot check valve 40: hydraulic gauge

43: height measuring gauge 44: height measuring sphere

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

Figure 3 is a perspective view showing a hydraulic hydrograph of the present invention, Figure 4 is a side view showing a hydraulic hydrograph of the present invention. As shown above, the hydraulic pump 30, the hydraulic cylinder 40 operated by the hydraulic pump 30, and the hydraulic cylinder 40 are attached to the movable rod 50 and attached to the movable rod 50. In the hydraulic hydrograph moving device for moving the water gate 60, the hydraulic pump handle 31 which can generate the hydraulic pressure on the upper portion of the hydraulic pump 30, and the other side of the hydraulic pump 30 A hydraulic conveying part 34 capable of being conveyed to the hydraulic cylinder 40 is constituted, and the hydraulic conveying part 34 is provided with a change valve 32 which can switch the conveying direction of the hydraulic pressure, and the change valve 32 ), The change switch 33 is formed on the change valve 32 so that an operator can operate the change valve 32.

In addition, the upper portion of the hydraulic transfer portion 34 protrudes the lower connector 35 and the upper connector 36, respectively, and the lower connector 35 constitutes a pilot check valve 37 in the middle predetermined portion, and the hydraulic pump ( The hydraulic cylinder (40) provided separately from 30) constitutes an oil pressure inlet (41) and a oil pressure cylinder (42), and the oil pressure inlet (41) is connected to a pipe from the upper connector (36) of the hydraulic pump (39). To connect the, the lower pressure inlet 42 is to connect the connecting pipe from the lower connector 35 of the hydraulic pump 30, the height measuring gauge 43 is attached to the outer surface of the hydraulic cylinder (40). .

The movable rod 50 is connected to the lower side of the hydraulic cylinder 40, and the movable rod 50 is connected to the water gate 60, and the height measuring port 44 protrudes outward at a predetermined height of the movable rod 50. The height measuring sphere 44 is configured to be able to indicate a predetermined height of the height measuring gauge 43. Therefore, the position indicated by the height measuring tool 44 is formed so as to indicate a predetermined portion of the height measuring gauge 43 made of metal or the like to represent the height of the water gate.

Referring to the operation of the subject innovation configured as described above in detail as follows.

First, when the hydraulic pump handle 31 is moved up and down in a state of being held by an operator to raise the water gate 60 to generate hydraulic pressure in the hydraulic pump 30, the hydraulic pressure is transferred to the hydraulic transfer part 34. At this time, when the operator operates the change switch 33 to transfer the hydraulic pressure to the lower connector 35, the hydraulic pressure is moved to the lower pressure inlet 42 of the hydraulic cylinder 40 through the lower connector 35. When the hydraulic pressure is moved to the oil pressure outlet 42 as described above, the hydraulic pressure is pushed upward to the piston provided in the hydraulic cylinder (40).

When the piston is pushed upward, the movable rod 50 connected to the lower side of the hydraulic cylinder 40 moves upward, and when the movable rod 50 moves upward, the water gate 60 connected to the lower side of the movable rod 50 is Will move upwards. As a result, the water gate opens the channel, and when the channel is opened, water moves through the channel.

At this time, when the water gate 60 is raised to a predetermined height to maintain the state, the water moves to the water channel. That is, the piston of the hydraulic cylinder 40 which moved the water gate 60 to the predetermined height is not moved. For this purpose, the piston of the hydraulic cylinder 40 is not moved to the lower side by the action of the pilot check valve 37 of the lower connector 35 connected to the lower hydraulic cylinder 42.

The above operation will be described in detail as follows. 5 is a cross-sectional view showing a state of use of the pilot check valve, Figure 5 (a) is a cross-sectional view showing the free flow of the hydraulic pressure. That is, the pressure oil which enters from the connection port b 37b wins the force of the spring 37f, lifts the poppet 37e, and flows into the outlet port 37d, but FIG. 5 (b) shows the state in which the hydraulic pressure is closed. As a cross sectional view, the reverse flow is completely blocked. The hydraulic pressure flowing into the pilot check valve 37 from the outlet 37d is blocked by the poppet 37e and is prevented from flowing into the pilot check valve 37.

5 (c) is a cross-sectional view showing a state in which the hydraulic pressure is opened at the pilot pressure. When the pilot pressure is hydraulically applied to the connection port a 37a, the pilot piston 37c is pushed, and the pilot piston 37c is transferred upward. The poppet 37e is transferred upwards to open the outlet 37d, and when the outlet 37d is opened, the hydraulic pressure introduced into the connection port b 37b can be freely moved to the outlet 37d, and conversely, the outlet 37d. The hydraulic pressure introduced into) can be moved to the connection port 37b.

As described above, the pilot check valve 37 is maintained in the state of FIG. 5 (b) to prevent the water gate 60 from descending. Thus, the sluice gate 60 can maintain its height even after a considerable time passes so as not to block the water passing through the waterway.

In order to lower the raised water gate is to operate as follows.

When the hydraulic pump handle 31 is moved up and down in a state in which the worker is held to lower the water gate 60 to generate hydraulic pressure in the hydraulic pump 30, the hydraulic pressure is transferred to the hydraulic transfer part 34. At this time, when the operator operates the change switch 33 to transfer the hydraulic pressure to the upper connector 36, the hydraulic pressure is moved to the oil pressure injection inlet 41 of the hydraulic cylinder 40 through the upper connector 36. When the hydraulic pressure is moved to the oil pressure outlet 41 as described above, the hydraulic pressure is pushed downward to the piston provided in the hydraulic cylinder (40). At this time, the pilot check valve 37 is in the state of the fifth (c) is able to flow the hydraulic pressure.

When the piston is pushed downward, the movable rod 50 connected to the lower side of the hydraulic cylinder 40 moves downward, and when the movable rod 50 moves downward, the water gate 60 connected to the lower side of the movable rod 50 is Will move downward. As a result, the water gate 60 closes the waterway. When the waterway is closed by the water gate 60, the water is blocked by the water gate 60 and cannot be moved.

6 is an embodiment showing a height measuring gauge different from the embodiment of the present invention, the hydraulic cylinder 40 that operates by the action of the hydraulic pump, and the movable rod 50 for moving the water gate under the hydraulic cylinder 40 ) Is the same as in one embodiment, but in another embodiment a fixture (72) constituting the graduation 72 in the hydraulic cylinder 40, and can be fixed to the height indicator 70 in a predetermined portion of the moving rod (50) And the height indicator 70 is fixed by the fixture 71 is configured so that the front end points to a predetermined portion of the scale 72 in accordance with the movement of the movable rod 50, and the height indicator ( 70 is formed to pass through the display drive hole 73 provided in the lower side of the hydraulic cylinder (40).

In another embodiment as described above, when the movable rod 50 is moved by the hydraulic pressure applied to the hydraulic cylinder 40, the fixture 71 fixed to the movable rod 50 moves together. As a result, the height indicator 70 integrally connected to the fixture 71 also moves together, and the height indicator 70 moves inside the display movement hole 73 so that the height indicator 70 does not move in the other direction. . Therefore, the height indicator 70 can be pointed at the tip portion 72 of the scale 72, the height indicator 70 by the display guiding hole 73 is prevented from being moved in the other direction is continuously of the water gate The height will be displayed.

This design makes it easy to move the water gate manually without the supply of external energy such as electricity or oil, it is convenient to use the operator who operates the water gate, and the device for moving the water gate by a simple device. It is possible to check even in the installed place, and even after raising the water gate, its height can be maintained as it is.

Claims (1)

In the hydraulic hydrograph moving device for allowing the hydraulic pressure generated from the hydraulic pump to move the moving rod attached to the hydraulic cylinder, the hydraulic pump handle for generating the hydraulic pressure on the upper portion of the hydraulic pump, and the upper other side of the hydraulic pump The hydraulic valve is formed by the change valve to determine the direction of hydraulic pressure. The upper and lower connectors are respectively formed in the hydraulic transfer part, and a pilot check valve is provided at a predetermined portion in the middle of the lower connector. The hydraulic cylinder is transferred to the hydraulic cylinder, and the height measuring gauge is attached to the outside of the hydraulic cylinder, and the hydraulic cylinder is configured such that a moving rod for moving the water gate is connected, and the height measuring hole installed on the moving rod Characterized in that it can be formed to indicate the height of the sluice so as to indicate a predetermined portion Hydraulic hydro shifter.