KR200442618Y1 - Automatic sluice gate using buoyancy - Google Patents

Abstract

The present invention relates to an automatic sluice using buoyancy, which adjusts the height and buoyancy of the buoys coupled to the sluice by a gearbox wire rope method, and improves the opening / closing hinge structure of the sluice by a double hinge method.

The present invention is a water frame for opening and closing the channel of the concrete structure; A buoyancy generating buckle mounted on the rear surface of the sluice frame so as to be lowered and lowered along guide rails formed at both ends thereof; A float height adjusting device for elevating the float to a predetermined level using a gearbox wire rope or chain; Consists of a double hinge device for connecting between the concrete structure and the upper end of the sluice frame, there is an effect that the opening and closing rotation operation of the sluice smoothly.

Automatic gate, buoyancy, float, hinge device, substructure device

Description

Automatic sluice gate using buoyancy}

The present invention relates to an automatic sluice using buoyancy, and more specifically, the height and buoyancy of the buoys coupled to the automatic sluice can be easily adjusted by adopting a gearbox wire rope method, and the double hinge of the structure of the opening / closing hinge part of the sluice. It relates to an automatic sluice using buoyancy to improve the way to facilitate the opening and closing rotation of the sluice smoothly.

As is generally known, the boundary area between the sea and the river, the freshwater area of the amusement park including the lake, and the freshwater area requiring the agricultural water are closed or discharged to maintain the water level as necessary. There is a sluice which opens as much as possible.

These floodgates are installed at appropriate locations in the freshwater area for flood control of rivers and flooded areas or for the supply of agricultural and industrial water needed in agricultural and industrial areas.

In order to install the water gate, first, the concrete structure having the water channel is constructed at a position that becomes the discharge path of the freshwater reservoir, and then the water gate that can open and close the water channel is mounted on the concrete structure. .

6 is a front view of a conventional water gate structure, showing a passive water gate.

Conventional manual floodgates include a rectangular frame-shaped fixed frame (3) mounted on the inner surface of the concrete structure (2), a water gate (1) which can be opened and closed in an up and down direction on the inner surface of the fixed frame (3), and this floodgate ( It comprises a screw rod (4) connected to the upper end of 1), and a rotary operating lever (5) coupled to the upper end of the screw rod (4) penetrating the upper end of the fixing frame (3).

Therefore, when the fresh water is discharged in a state where water is filled up to a certain level, the screw rod 4 is transferred upward by the manager or the user by rotating the rotary operation lever 5 of the manual water gate in the opening direction. At the same time, the sluice gate 1 is opened to move upwards to discharge the water.

However, the conventional manual water gate has a disadvantage in that it is difficult to control the water level that requires the discharge of water, and also has to be operated every time to open and close the water gate during discharge.

In order to solve the shortcomings of the manual hydrology, an automatic hydrology using buoyancy is adopted.

Conventional buoyancy automatic sluice includes a buoy which generates buoyancy in the water gate, which is mounted at a predetermined water level position on the inner surface of the water gate.

Therefore, when the fresh water level rises to a predetermined position, the buoys come into contact with the surface of the water to generate buoyancy, and the buoys float on the water surface by buoyancy and at the same time the automatic flood gate opens while rotating in the direction of water discharge. The discharge is made.

On the other hand, the configuration of the hinge rotation point for the conventional automatic sluice rotation is installed through the upper end of the concrete structure (2) up and down as shown in Figure 7, the long bolt formed with a through hole at the lower end (6), a nut (7) for fixing the long bolt (6) in a fixed position on the upper surface of the concrete structure (2), a hinge bracket (8) assembled on the upper surface of the automatic sluice, and the long bolt ( It comprises a hinge bolt (9) connecting the lower end of 6) and the hinge bracket (8) by a hinge (hinge).

However, the conventional automatic sluice using the buoyancy has the following disadvantages.

First, there is a disadvantage in that the position of the floats included in the conventional automatic sluice cannot be adjusted to a predetermined level, that is, as the float is fixedly installed in the conventional automatic sluice, there is a disadvantage that the automatic opening time according to the level of fresh water can not be adjusted.

For example, if the float is fixed to a high water level in a conventional automatic flood gate, the float generates buoyancy only when the fresh water is at a high water level, and the automatic flood gate is opened, and the remaining water level, that is, the middle water level or When the discharge is required at the low water level, the buoyancy does not occur at the water level, so the water gate does not open automatically.

Second, in addition to buoyancy caused by the float, the automatic sluice rotates toward the water surface of the freshwater, and the opening operation is difficult due to corrosion of the parts constituting the hinge rotation point. This disadvantage is with reference to the accompanying Figure 7, the configuration of the hinge rotation point of the conventional automatic sluice is a long bolt 6 that penetrates the upper end of the concrete structure (2), and fixing the long bolt (6) Nut 7, a hinge bracket 8 assembled on the upper surface of the automatic sluice, and a hinge bolt 9 for connecting the long bolt 6 and the hinge bracket 8 with a hinge, etc. Bars and brackets are mainly made of iron, which is vulnerable to corrosion. Furthermore, if they are continuously exposed to water or air, they are more easily corroded. There is a disadvantage that the rotation of the water gate is not made well when closed.

The present invention has been devised to solve all the problems associated with the conventional hydrological as described above, by adopting the hoisting method using a wire rope to move and adjust the position of the floats coupled to the automatic hydrological position to a position suitable for a certain level The buoyancy can be adjusted by adding or subtracting the buoyancy of the buoys, and the hinge rotation point structure of the automatic sluice is improved to a double hinge structure that is easy to rotate while being resistant to corrosion, so that the automatic opening and closing of the sluice can be performed smoothly. The purpose of the present invention is to provide an automatic hydrology.

The present invention for achieving the above object is a hydrological frame for opening and closing the channel of the concrete structure; A buoyancy generating buckle mounted on the rear surface of the sluice frame so as to be lowered and lowered along a guide rail formed at both ends thereof; A float height adjusting device for elevating the float to a desired level using a wire rope or chain; It characterized in that it comprises a double hinge device for connecting between the concrete structure and the upper end of the sluice frame.

As a preferred embodiment, the float height adjusting device and the worm gear type manual rotating device disposed on the upper surface of the concrete structure; A pair of fixing rings integrally formed at an upper end portion of the rear surface of the sluice frame; A drum disposed in the fixing ring; A rotating body engaged with the shaft of the drum protruding outward of the fixing ring; One end is integrally fixed to the output shaft of the worm gear type manual rotating device, and the other end is a power transmission flexible cable integrally fixed to the outer surface of the rotating body; A wire rope having a predetermined length wound around the drum, one end of which is fixed integrally to an upper surface of the sub-ball, and the other end of which is integrally fixed to the bottom of the sub-ball; It is mounted to the lower end portion of the front of the frame for the hydrological adjustment roller to serve as a guide when unwinding and winding the wire rope; characterized in that consisting of.

In the present invention, the double hinge device and the hinge bracket is fixedly mounted on both sides of the upper surface of the sluice frame; A first rotating shaft penetrated in the transverse direction to the hinge end of the hinge bracket; A height bolt and a support for height adjustment fastened through the concrete structure; Casing and integrally connected to the lower end of the height adjustment bolt and the support; A second rotating shaft rotatably housed in the casing by a pair of bearings; An upper end is formed integrally with the second rotary shaft, and a lower end portion is connected to the connecting arm having a structure in which a through hole is formed to be inserted.

In addition, the present invention is characterized in that the guide bar is integrally formed on both side surfaces of the buckle, the guide bar is characterized in that a plurality of guide rollers are fitted to the guide rail so as to enable rolling.

According to the present invention, the above-described problem solving means has the following effects.

First, the position of the floats contained in the automatic sluice can be easily adjusted to a certain level with a simple manual operation, and at the same time the buoyancy of the floats can be easily adjusted. In other words, when the rotational force is transmitted to the drum of the sluice frame through the flexible wire by simple manual operation of the worm gear-type manual rotator, the buckle included in the automatic sluice is easily moved to a constant water position by the wire rope wound on the drum. The up and down movement can be adjusted, and it is possible to easily adjust the buoyancy by varying the submerged position of the float.

Secondly, the opening or closing rotation operation of the automatic sluice can be made smoothly even in long-term use by the double hinge device. In other words, due to corrosion (rust) caused by long-term use in the past, the phenomenon of sticking occurs at the hinge rotation point of the automatic sluice. It can be easily solved by the application, and also because the weight of the water gate is reduced by buoyancy of the float, the water gate is smoothly adhered to the frame installed in the concrete structure.

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

1 is a front view showing an automatic sluice using buoyancy according to the present invention, Figure 2 is a side view thereof.

As shown in Figure 1 and 2, the automatic sluice gate 100 using the buoyancy according to the present invention is installed in the channel of the concrete structure (structure formed by the water discharge point of the corresponding fresh water) and installed at the water channel automatically It is to open and close.

The body for substantially opening and closing the waterway of the concrete structure 40 is a sluice frame 10, the sluice frame 10 can open and close the waterway of the concrete structure using a stainless material resistant to corrosion while resisting water pressure It is manufactured in size.

At both ends of the sluice frame 10, guide rails 12 for guiding the float 20 to move up and down are formed in the vertical direction.

On the rear of the hydrological frame 10, a buoy 20 for floating buoyancy is mounted to be adjustable in an up and down position, and guide bars 22 are integrally formed on both side surfaces of the buoy. The 22 is equipped with a plurality of rolling guide rollers 24.

Accordingly, by inserting the guide roller 24 of the float 20 into the guide rail 12 of the hydrological frame 10 so as to enable rolling, the float 20 may be formed by the guide roller 24 of the hydrologic frame. It is possible to move up and down by the movement of the rolling motion along the guide rail (12).

At this time, the inlet width of the guide rail 12 adopts a structure formed smaller than the size of the guide roller 24 so that the guide roller 24 is not separated from the guide rail 12. The structure in which the guide roller 24 is not separated from the guide rail 12 may adopt various mechanical structures for the guide rail 12.

Reference numeral 60 is an index rubber attached to the front rim of the water frame 10, and reference numeral 61 is a frame mounted on the concrete structure.

Here, the configuration and operation of the float height adjusting device for driving the float up and down at a constant water level will be described.

Float height adjusting device 30 according to the present invention is a device that allows the administrator or user to adjust the height of the float to a position suitable for a certain water level (low water level, medium water level, high water level), the worm gear type manual rotary device 34 is fixedly disposed on the upper surface of the concrete structure 40.

As shown in FIG. 5, the worm gear manual rotary device 34 is connected to the worm gear 34b disposed in a predetermined arrangement in the gearbox 34a and to the input side of the worm gear 34b. And an output shaft 34d integrally fastened to the output center gear center of the worm gear 34b.

In addition, as a configuration included in the float height adjusting device of the present invention, the drum 36 is mounted on the upper end of the front door of the sluice frame 10.

The drum 36 is integrally formed so that a pair of fixing rings 35 are spaced apart from the front surface of the sluice frame 10 at an upper end thereof, and the drum 36 is rotatably coupled to the fixing rings 35. do.

At this time, the rotating body 37 is integrally connected to the shaft of the drum 36 protruding outward of the fixing ring 35.

Power transmission flexible cable 38 is provided as a means for transmitting the rotational force of the worm gear-type manual rotating device 34 to the drum, one end (upper end) of the flexible cable 38 is the worm gear It is integrally coupled to the output shaft 34d of the rotary machine 34, and the other end (lower end) is integrally coupled to the outer surface of the rotary body 37.

The flexible cable 38 is a power transmission cable made by twisting wires in multiple layers, and the output shaft 34d and the rotating body 37 of the worm gear-type manual rotating device 34 in a loose state having a free length. It is integrally connected to the liver.

On the other hand, a wire rope 32 having a predetermined length is wound around the drum 36, one end (upper end) of which is fixed integrally to the upper surface of the buckle 20, and the other end (lower end) Via the adjustment roller 39 is fixed integrally to the bottom surface of the buckle 20.

The adjusting roller 39 is mounted on the lower end of the front door of the sluice frame 10, and serves as a guide when the wire rope 32 is unwinded and wound. The wire rope 32 may be replaced by a chain as necessary.

Referring to the operation of the float height adjusting device having such a configuration as follows.

First, when the administrator or the user rotates the lever 34c of the worm gear manual rotary device 34, the worm gear 34b in the gear box 34a rotates, and the output side gear of the worm gear 34b is rotated. The output shaft 34d integrally fastened to the central portion rotates.

Subsequently, the flexible cable 38 integrally fixed to the output shaft 34d rotates in the same direction, and at the same time, the rotary body 37 integrally connected to the lower end of the flexible cable 38 rotates.

At the same time, the rotational force of the rotating body 37 is transmitted to the drum 36, and the wire rope 32 is wound around the drum 36 or released from the drum by the rotation of the drum 36.

Therefore, when the wire rope 32 extending toward the bottom of the float 20 is pulled upward from the bottom and wound on the drum 36, the wire rope 32 extending toward the upper surface of the float 20 is simultaneously It is released downward from the drum 36.

At the same time, the wire rope 32 connected to the bottom surface of the float 20 via the adjusting roller 39 is pulled downward from the upper portion so that the position of the float 20 is moved downward.

Accordingly, the buoy 20 is submerged deeper into the water to generate a greater buoyancy, on the contrary, the wire rope 32 extending toward the upper surface of the buoy 20 is pulled upward from the bottom drum 36 At the same time, the wire rope 32 extending toward the bottom of the float 20 is unwinded downward from the drum 36, and the position of the float 20 is moved upward so that the buoyancy of the float is reduced. Can be adjusted.

As such, according to the present invention, the buoyancy of the buoy 20 can be easily adjusted by adjusting the position of the buoy 20 up and down according to the water level during high or low tide.

Here, when the automatic sluice according to the present invention is opened or closed, explaining the role of the ball.

4A shows an open state of the automatic sluice, that is, a state in which water stored in the river is discharged toward the sea, and FIG. 4B shows a state in which the automatic sluice is closed when discharge is completed.

As shown in Figure 4a, when the water on the stream side is above a certain level, by the water pressure the automatic sluice 100 is rotated around the hinge rotation point is opened so that the water on the river side is discharged to the sea.

At this time, the buoy 20 mounted on the front of the hydrological frame 10 of the automatic sluice 100 floats on the water surface where the effluent and seawater are combined, and the buoyancy generated in the buoy 20 is discharged Force to keep the automatic sluice 100 in the open state before the end, and after the discharge is finished, the force to support the sluice 100 to rotate smoothly in the closing direction again By acting as the water gate 100 is to be easily closed.

As shown in Figure 4b, when the discharge of the water stored in the river is almost finished, the water pressure of the water to the automatic sluice 100 is lowered, the automatic sluice 100 is rotated in the closing direction about the hinge rotation point .

At this time, the buoyancy generated in the buoy 20 acts as a force to suppress the automatic sluice 100 to rotate rapidly in the closing direction again to serve to induce the automatic sluice 100 to close slowly. .

In other words, when the automatic sluice 100 is suddenly closed in the closing direction by its own weight, a concentrated load may be applied to the hinge rotation point, such that the structures of the hinge rotation point may be damaged, but the present invention According to the buoyancy of the buoy 20 is to act to reduce the weight of the automatic sluice 100, the automatic sluice 100 is closed by rotating at a gentle speed, after all the automatic sluice 100 is closed as before It is possible to prevent the concentrated load from acting on the hinge rotation point while closing in a sharp direction.

Therefore, the automatic sluice 100 rotates slowly at a gentle speed so that the sluice 100 is smoothly closed, so that the water-resistant rubber 60 coupled to the sluice 100 is connected to the frame 61 of the concrete structure 40. It comes in close contact securely.

Here, the double hinge device constituting the hinge rotation point of the automatic sluice according to the present invention will be described.

3A and 3B are cross-sectional views illustrating a double hinge device according to the present invention.

The double hinge device 50 of the present invention has a main point in that the hinge rotation point can be easily rotated at the time of opening and closing of the automatic sluice even when the hinge rotation point is fixed by corrosion (rust) in the long term use of the automatic sluice.

The double hinge device 50 penetrates the concrete structure 40 and the height adjustment long bolt 54 and the support 55 is fastened, the predetermined height at the lower end of the height adjustment long bolt 54 and the support 55. The casing 56 having an inner space is integrally connected.

In addition, a bearing 57 is fixedly disposed at both sides of the casing 56, and a second rotation shaft 58 is connected between the bearings 57.

At this time, the front surface of the casing 56 in the open state of the bearing 57 and the second rotating shaft 58, and then the open front of the casing 56 is a separate cover plate using welding or the like. It can be attached and sealed.

On the other hand, a hinge bracket 52 having a hinge end 52a is fixedly mounted on both sides thereof on the upper surface of the hydrological frame 10, and a first rotating shaft (1) is attached to the hinge end 52a of the hinge bracket 52. 53) is fastened.

In particular, the first rotary shaft 53 and the second rotary shaft 58 are connected to the connecting arm 59 in the form of a long vertical link bar, and the upper end of the connecting arm 59 is connected to the second rotary shaft 58. The first rotary shaft 53 and the second rotary shaft 58 are integrally formed by inserting the first rotary shaft 53 through the through hole 59a formed at the lower end of the connecting arm 59. The arm 59 is connected to each other.

At this time, the rotation point of the sluice frame 10 is two places of the first rotation shaft 53 and the second rotation shaft 58.

Therefore, when the sluice frame 10 is rotated to open and close, the second rotating shaft 58 may be corroded (rusted) to the first rotating shaft 53 and the hinge bracket 52 due to long-term use, even if a sticking phenomenon occurs. ) Is the opening and closing rotation point of the sluice frame 10 is to be able to open and close the sluice frame 10 smoothly at all times, and also coupled to the connecting arm 59 during high tide of the sea by high water Since the second rotary shaft 58 smoothly operates in the casing 56 together with the bearing 57, the automatic sluice 100 is safely closed so that the second rotation shaft 58 can be in close contact with the frame 61 of the structure.

1 is a front view showing an automatic sluice using buoyancy according to the present invention.

Figure 2 is a side view showing an automatic sluice using buoyancy according to the present invention.

Figure 3a and Figure 3b is a cross-sectional view and a longitudinal sectional view showing the hinge rotation point configuration of the automatic sluice using buoyancy according to the present invention.

Figure 4a is a side cross-sectional view illustrating an open state of the automatic sluice using buoyancy according to the present invention, Figure 4b is a side cross-sectional view illustrating a closed state of the automatic sluice using buoyancy according to the present invention.

Figure 5 is a schematic configuration diagram of the worm gear-type manual rotary device adopted in the present invention.

6 is a schematic diagram illustrating a conventional manual hydrological structure.

7 is a front view illustrating a hinge rotation point structure of a conventional automatic sluice.

<Explanation of symbols for the main parts of the drawings>

10: sluice frame 12: guide rail

20: float 22: guide bar

24: guide roller 30: ball height adjusting device

32: wire rope 34: worm gear manual rotation device

35: fixing ring 36: drum

37: rotating body 38: flexible cable

39: adjusting roller 40: concrete structure

50: double hinge device 52: hinge bracket

53: first rotating shaft 54: long bolt for height adjustment

55: support 56: casing

57: bearing 58: second rotating shaft

59: connecting arm 60: index rubber

Claims (4)

delete The buoyancy generating buckle 20 mounted to be lowered and lowered along the guide rails 12 formed at both ends of the sluice frame 10 for opening and closing the channel of the concrete structure 40 and the sluice frame 10. And, the buckle height adjusting device 30 for raising and lowering the buckle 20 to a predetermined level using a wire rope 32, and between the upper end of the concrete structure 40 and the sluice frame 10 In the automatic sluice using the buoyancy of the double hinge device 50 to connect, The float height adjusting device 30, the worm gear type manual rotary device 34 is disposed on the upper surface of the concrete structure 40; A pair of fixing rings (35) integrally formed at an upper end portion of the back of the sluice frame (10); A drum (36) disposed in the fixing ring (35); A rotating body 37 engaged with the shaft of the drum 36 protruding outward of the fixing ring 35; One end is integrally fixed to the output shaft (34d) of the worm gear-type manual rotary device 34, the other end is a power transmission flexible cable 38 is integrally fixed to the outer surface of the rotating body 37 and ; A predetermined length is wound around the drum 36, one end of which is fixed to the upper surface of the buckle 20 integrally and the other end of the wire rope 32 is fixed to the bottom of the buckle 20 and ; Automatic sluice using buoyancy, characterized in that consisting of; adjustment roller (39) which is mounted on the lower end of the back of the sluice frame (10) serves as a guide when the wire rope (32) is unwinded and wound. The method according to claim 2, The double hinge device 50, the hinge bracket (52) fixedly mounted on both sides of the upper surface of the sluice frame (10); A first rotating shaft (53) coupled to the hinge end (52a) of the hinge bracket (52) in a transverse direction; A height adjusting bolt 54 and a support 55 which are fastened to penetrate the concrete structure 40; A casing 56 integrally connected to the lower end of the height adjusting long bolt 54 and the support 55; A second rotating shaft 58 rotatably housed by a pair of bearings 57 in the casing 56; The upper end is formed integrally with the second rotary shaft 58, the lower end portion is connected to the through hole (59a) is formed so that the first rotary shaft 53 is inserted; 59; water gate. The method according to claim 2, Guide bars 22 are integrally formed on both side surfaces of the sub-ball 20, and the guide bars 22 are equipped with a plurality of guide rollers 24 which are fitted to the guide rails 12 in a cloudable manner. Automatic sluice using buoyancy.

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