KR101398913B1 - Winch type vanishing water gate - Google Patents

Abstract

The present invention relates to a vanishing floodgate (10) installed in a waterway, a lock gate, a submerged weir, a spillway, etc. The objective of the present invention is to stably maintain the horizontal state of the floodgate (10) during the opening and closing of the floodgate (10) by respectively installing balance pulleys (15), which rotate freely, on both upper ends of the floodgate (10) and coupling a driving line (40) such as a wire rope to the balance pulleys (15) to winch the floodgate (10). According to the present invention, the vanishing floodgate (10) can be stably horizontally lifted only by winch equipment installed on the bank of a waterway. Thus, the vanishing floodgate (10) can be effectively driven without the construction of winch facillities, which traverses the waterway, as well as without the installation of a driving device (41) for opening and closing the floodgate (10) in a floodgate chamber (30) below the waterway.

Description

WIND TYPE VANISHING WATER GATE

The present invention relates to a top-down wedge (10) installed on a waterway, a Tongnan gate, an underwater boat and a waterway, and a water gate (30) in which a water gate (10) A balance pulley 15 is provided at both ends of the upper end of the water gate 10 so as to be freely rotatable in the top-down water gate 10 where the water gate 10 descends to the lower portion of the water channel. the drive line 40 is connected to both ends of the water gate 10 by connecting the drive wire 40 such as a wire rope to lift the water gate 10 so that the water gate 10 is lifted And the horizontal state can be stably maintained during the opening and closing of the water gate 10.

There are various kinds of waterways such as drainage roads, main operation waterways and agricultural waterways, waterway structures penetrating seawalls, waterway structures such as waterways and dams that cross rivers, waterways for controlling water flow, (10) are installed. These gates (10) have various types such as a tainter gate or a sluice gate depending on the type and the manner of operation.

The slosge gate is a type of the water gate 10 in which the water gate 10 transversely opening and closing the water channel opens and closes the water channel and is constructed in such a manner that the water gate 10 is lifted by installing a win- , And a support structure for installing a winch on the upper part of the water gate (10). In the case of the water gate (10) for opening and closing the water channel, a rigid bridge type structure And installs additional equipment such as winches.

Such a transversal structure not only encroaches on the cross section due to drifts captured during the flood, but also causes a problem that the debris collides with the connection part between the hoist and the gate (10) Of course, there is a problem that seriously degrades the overall landscape of the waterway.

In particular, since the conventional slosge gate which is opened and closed by the winch is opened from the lower part of the water channel, when the application is applied to the water gate 10 installed at the shore connection portion of the water channel, Serious problems are introduced.

In this case, an actuator such as a hydraulic cylinder for constructing the water gate 30 for storing the water gate 10 in the lower part of the water channel and driving the water gate 10 is installed to allow the water gate 10 to be moved up and down 10), that is, a downwardly open water gate 10 has been developed, and related art is disclosed in Japanese Patent No. 1286623. [

It is not only possible to drive the water gate 10 without the use of any lifting device that traverses the upper part of the water channel through the top-down water gate 10 including the patent No. 1286623, It is possible to effectively prevent leakage of water to the inside of the water gate 30 during operation of the water gate 10 because the driving facility such as a hydraulic cylinder is located in the water gate 30 in the lower part of the water channel. There is a problem in that it is not easy to access the workforce to the drive facility.

Therefore, a separate winch can be installed at both sides of the water gate 10, and both side ends of the water gate 10 can be connected to the win- dow to consider driving the water gate 10 on the ground without a structure for crossing the water channel However, in this case, there arises a problem that the elevating speeds of both side ends of the water gate 10 must be exactly matched.

That is, the water gate 10 can be stably raised and lowered without being inclined or deformed only by winding or unwinding the wire rope connected to both sides of the water gate 10 and connected to the win- To do this, it is necessary to accurately synchronize the winches on both sides.

Particularly, not only during the lifting movement of the water gate 10 but also during the initial driving and stopping, the rotation speed of the winches on both sides, the rotation start and stopping points, and the operation clearance must be precisely matched, The tension of the tube should be exactly the same, which can not be realized in reality.

In this case, when the water gate 10 rises, the rack joined to the water gate 10 protrudes to the upper part of the water channel 10, so that it is possible to use a rack and a pinion method without using a wire winding hoist and a wire rope. There is a problem that the aesthetic appearance is hindered and the intention of introducing the top-down wedge 10 to eliminate the protruding structure on the upper side of the waterway is discolored.

Accordingly, the top-down type water gate 10 has various problems such as efficient operation of the water channel, prevention of inflow of similar water, and securing of a landscape, but the application to the actual water channel is poor due to the above-

SUMMARY OF THE INVENTION It is an object of the present invention to provide a top-down type water gate 10 in which a water gate 30 in which a water gate 10 is stored in a lower portion of a water channel, A balancing pulley 15 is provided at both ends of the upper end of the water gate 10 and a driving line 40 closely attached to the lower portion of the balancing pulley 15 is coupled to one end of the driving line 40, And the other end of the drive line 40 is connected to the other side of the water channel so that the drive line 40 is connected to the drive unit 41 as the drive unit 41 is operated. Wherein the fixed side frame (51) is provided on the other side of the driving device (41) of the water channel, and the fixed frame (51) The end of the driving wire 40 is coupled to the fixing pin 52, Im 51 volumes sentence is characterized by a top-down water gate separated from the drive line 40, the fixed frame 51 as the end of the stripping the fixing pin 52 in.

In the top-down sluice gate 10 in which the sluice gate 10 in the lower portion of the water channel is constructed so that the sluice gate 10 descends to the lower portion of the waterway, The balancing pulley 15 is installed on the both sides of the balancing pulley 15 and the driving line 40 is closely contacted to the lower portion of the balancing pulley 15. The both ends of the driving line 40 are driven And is connected to the device 41 so that the two side balancing pulleys 15 to which the driving line 40 is coupled are rotated as the driving device 41 is operated to elevate the water gate 10.

It is possible to stably raise and lower the top-down type water gate 10 only by the lifting facility installed in the water channel through the present invention and thus the driving device 41 for opening and closing the water gate 10 is not constructed in the water channel lower water gate 30 Of course, effective operation of the top-down gates 10 is possible without construction of a hoisting facility across the waterway.

In particular, it is possible to stabilize the operation of the water gate 10 without constructing a precise synchronization system between the top-down water gate 10 and the lifting facilities connected thereto, thereby reducing the related construction cost and maintenance cost and improving the practical usability of the top- The effect can be obtained.

In addition, the problem of unevenness in the lifting and lowering of the water gate 10 due to the difference in tension between the wire ropes, which was a problem in the conventional roll-wound type water gate 10 in which multiple wire ropes are directly bound to the water gate 10 Not only the deformation or breakage of the water gate 10 due to the unbalanced driving of the water gate 10 but also the damage of the water gate 10 to the water channel contact structure can be suppressed as well as the water gate 10 and the related structure It is possible to secure durability.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.
2 is a partial cutaway perspective view of the structure of the present invention
Fig. 3 is a perspective view of a water-
Fig. 4 is a schematic cross-sectional view of the present invention,
Fig. 5 is a schematic cross-sectional view of the present invention in which the gate is completely lowered
6 is a schematic cross-sectional view of an embodiment of the present invention in which a driving device is provided on both sides
7 is an explanatory diagram of the emergency driving method of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings.

1 is a perspective view showing the external appearance of a waterway to which the present invention is applied. As shown in the drawing, the present invention is a top-down waterway door 10 in which a waterway door 30 is formed at a lower part of a waterway, In the drawing, the water gate 30 and the water channel 21 exposed in the lower part of the water channel have a structure buried in the ground.

In the embodiment shown in Fig. 1, a driving device 41 having a winding part 42 is mounted on one side channel wall 21 of a channel, a fixing pin 52 is fixed to the other side channel wall 21 of the channel, The drive wire 40 connected to both ends of the upper end of the upper end of the water gate 10 is fixed to the winding part 42 of the drive device 41 and the fixed frame 51 Is connected to the pin (52).

2, which is a partially cutaway perspective view of a water gate structure 10 to which the present invention is applied, a water channel 21 having water channel walls 21 formed on both sides of a water channel floor 22 is provided with a water channel 22, And a side storage room 35 protruded outward from the both side water channel walls 21 and connected to the water gate 30 is formed at a number of points where the water gate 30 is formed. An engaging groove 33 is formed on the inner side surface of the water passage wall 21 at a position where the side storage chamber 35 is formed so as to lead to the water passage chamber 30. The water passage 10 is formed on both side water passage walls 21 And is housed in the hydrologic chamber 30 at the lower portion of the water channel bottom 22 when it is lowered while being coupled to the formed coupling groove 33.

2, a plurality of rollers 19 having diameters that coincide with the widths of the engaging grooves 33 are mounted on both ends of the water gate 10 so as to ensure smooth ascending and descending activities of the water gate 10 And an engaging groove 33 in which the water gate 10 is directly in contact with the water gate 10 for closing the water gate 10 and an exponent material on both sides of the water channel upper and lower sides of the opening of the water gate 30 29 may be provided.

FIG. 3 is a partial cutaway perspective view showing the water gate 10 according to the present invention. As shown in FIG. 3, the water gate 10 of the present invention has a grid-like reinforcing rib (not shown) like a conventional sluice gate A pair of equilibrium pulleys 15 are provided which are freely rotatable on the upper part of the sluice gate 10.

3, a balance pulley 15 is provided at both ends of the upper end of the water gate 10, and these balance pulleys 15 are installed in the structure of the water gate 10, that is, The balancing pulley 15 is provided between the plates constituting the front and rear sheathing so that both ends of the rotary shaft of the balancing pulley 15 are joined to the front and rear sheathing plates and between the side balancing pulleys 15, A parallel cavity is formed in the balance pulley 15 and an outlet hole 16 is formed in the upper end plate body on the upper portion of the balance pulley 15. [

3 to 5, a supporting roller 17 that rotates freely is provided under the driving line 40 between the inner balance pulleys 15 of the water gate 10, and unnecessary deflection of the driving line 40 And the tension of the driving line 40 can be kept constant. The structure of the supporting roller 17 is particularly advantageous when the water gate 10 of the present invention is applied to a large-scale water channel.

The water gate 10 of the present invention is driven by a driving line 40 such as a wire rope coupled to a balancing pulley 15 on both sides, and a specific driving method thereof is shown in Figs.

1, 4, and 5 illustrate an embodiment in which a single drive device 41, that is, a single winch is applied. One end of a drive line 40 coupled to the balance pulley 15 is connected to one end (41) and the other end is fixed to the water channel.

A balancing pulley 15 is provided at both ends of the upper end of the water gate 10 and a driving line 40 closely attached to the lower portion of the balancing pulley 15 is coupled, And the other end of the drive line 40 is connected to the other side of the channel so that the drive line 40 is connected to the drive device 41 as the drive device 41 is operated, The two side balance pulleys 15 are rotated, so that the water gate 10 is raised and lowered while keeping the water level.

The same tension is exerted on the entirety of the drive line 40 coupled to the balance pulley 15 mounted freely rotatably on both ends of the upper end of the water gate 10, Both sides of the water gate 10 can be raised and lowered with the same tension so that the horizontal state can be stably maintained when the water gate 10 is lifted and lowered and also the forces acting on both side ends of the water gate 10 can be accurately matched So that it is possible to prevent deformation and breakage of the water gate 10 and to prevent damage to the structure in contact with the water gate 10.

1, 4, and 5, in the concrete wiring structure of the drive wire 40, a supporting pulley (not shown) is mounted on the upper side of the side housing chamber 35 protruded outside the water channel walls 21 on both sides of the water channel. The drive device 41 and the fixed frame 51 are provided outside the both side support pulleys 38 and the drive line 40 wound around the winding portion 42 of the drive device 41 A structure that is coupled to the fixing pin 52 of the fixed frame 51 via the supporting pulley 38 on the side of the driving unit 41, the pair of balancing pulleys 15 and the supporting pulley 38 on the fixed frame 51 side .

4, by providing the support pulley 38 directly above the two-sided balancing pulley 15, the vertical movement of the upper side drive line 40 in the axial direction is ensured So that the drive device 41 can be embedded on the side of the water channel.

4 and 5 show a fully closed state and a fully opened state of the water gate 10 of the present invention using the single drive device 41 of the above described structure. As the portion 42 rotates and the drive wire 40 is pulled or reeled, the water gate 10 is lowered or raised.

6 shows an embodiment in which the drive device 41 is provided on both sides of the water channel and the drive line 40 connecting these drive devices 41 is coupled to the balance pulley 15 to raise and lower the water gate 10 The drive device 41 is doubly configured so as to reduce the required output of the drive device 41 and enable the emergency operation even in the event of failure of one drive device 41. [

A balancing pulley 15 is provided at both ends of the upper end of the water gate 10 and a driving line 40 closely attached to the lower portion of the balancing pulley 15 is coupled. Are connected to drive devices 41 provided on both side portions of the water channel so that the both side drive devices 41 are driven simultaneously or the drive devices 41 of either side of the both side drive devices 41 are driven The balancing pulley 15 to which the line 40 is coupled rotates, and the gate 10 is moved up and down while maintaining the horizontal.

It is preferable to match the rotational speeds of the two side drive devices 41 as much as possible when the drive device 41 is installed on both sides of the water channel and the both side drive devices 41 are simultaneously operated. However, The tension of the entire drive line 40 is uniformly distributed and maintained by the pair of balancing pulleys 15 that are freely rotated even if they do not coincide with each other.

As described above, when the driving devices 41 are formed on both sides of the water channel, the output required for the elevation driving of the water gate 10 can be distributed to the two side driving devices 41, , The production cost of the hoist machine increases exponentially as the output increases, and the construction cost of the gate 10 can be drastically reduced by replacing the large hoist machine with a plurality of small hoist machines.

7 illustrates an emergency operation state of the water gate 10 in the event of failure of the drive unit 41 in the embodiment of the present invention to which the single drive unit 41 is applied, It is possible to separate the driving line 40 and draw it from the ground when necessary by applying the fixing pin 52 detachably attachable to the fixed frame 51 and the fixed frame 51 when binding the line 40 .

That is, the fixing frame 51 is provided on the other side of the water channel driving device 41, the fixing pin 52 is coupled to the fixing frame 51, and the end of the driving line 40 is fixed to the fixing pin 52 And the end of the driving line 40 can be separated from the fixed frame 51 as the fixing pin 52 is detached from the fixed frame 51. Although not shown in the figure, 40 are connected to a separate winch or a crane for towing the water gate 10 in an emergency.

10: The water gate
15: Balance pulley
16: Entrance and exit
17: support roller
18: reinforcing rib
19: Roller
21: Waterway wall
22: Waterway floor
29: Index material
30: Hydrology room
33: coupling groove
35: Side compartment
38: Support pulley
40:
41: Driving device
42:
51: Fixed frame
52: Fixing pin

Claims (3)

A top-down type sluice gate 10 in which a sluice gate 10 is installed at a lower portion of a water channel and the sluice gate 10 descends to a lower portion of a water channel and is open at both ends of the upper end portion of the sluice gate 10, And a drive line 40 which is in close contact with the lower part of the balancing pulley 15 is coupled with one end of the drive line 40 being connected to a driving device 41 provided on one side of the channel, In a top-down wedge (10)
The other end of the drive line 40 is connected to the other side of the waterway;
A support pulley 38 is provided directly above the hydrator 10 balancing pulley 15 and the support pulley 38 is installed on the upper side of the side containment chamber 35 protruded outside the water channel walls 21 on both sides of the water channel ;
A supporting roller 17 that rotates freely is provided under the driving line 40 between the gate 10 and the inner balance pulley 15 to suppress deflection of the driving line 40;
Wherein the water balance (10) is lifted and lowered by rotating the balancing pulley (15) to which the drive line (40) is coupled as the drive unit (41) is operated.
A top-down type sluice gate 10 in which a sluice gate 10 is installed at a lower portion of a water channel and the sluice gate 10 descends to a lower portion of a water channel and is open at both ends of the upper end portion of the sluice gate 10, And a drive line 40 which is in close contact with the lower part of the balancing pulley 15 is engaged and both ends of the drive line 40 are connected to drive units 41 In the top-down wedge (10)
A support pulley 38 is provided directly above the hydrator 10 balancing pulley 15 and the support pulley 38 is installed on the upper side of the side containment chamber 35 protruded outside the water channel walls 21 on both sides of the water channel ;
A supporting roller 17 that rotates freely is provided under the driving line 40 between the gate 10 and the inner balance pulley 15 to suppress deflection of the driving line 40;
Wherein the water balance (10) is lifted and lowered by rotating the balancing pulley (15) to which the drive line (40) is coupled as the drive unit (41) is operated. delete

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