KR20180017769A - floodgate device - Google Patents

Abstract

The present invention relates to an inversion floodgate and, more specifically, relates to an inversion floodgate having a driving type structure on a water surface. When a driving device of the inversion floodgate is formed, a structure thereof is simplified to reduce a failure rate and costs consumed for constructing equipment. Moreover, as the driving device is placed on a water surface, a failure of the driving device, which is caused by sediment or the like under water, is prevented in advance. When the driving device is out of order, the driving device can be simply repaired on a water surface to very conveniently maintain and manage the driving device. Therefore, corrosion of the driving device is prevented to increase durability.

Description

A floodgate device with a water -

More particularly, the present invention relates to a conductive water gate, and more particularly, to improve the driving system of a conductive water gate in order to maximize the functions of a conventional conductive water gate, thereby realizing structural simplification and convenient maintenance, The present invention relates to a conductive water gate having a water surface-mounted driving structure for bringing an extension of the water surface.

Generally, in order to store water to be used for agricultural or industrial purposes, or to purify polluted water, an underwater boat or a water gate is installed in the irrigation channel of a river or a reservoir or a related water channel, It is always kept at a constant height.

On the other hand, the conventional water gates that have been used in the past are water-type water gates that open and close the water gates by raising and lowering the elevation control handles on the upper side of the water gates, and the water gates are relatively simple in structure, However, in order to control the water level, which is the greatest function of the watercraft, when the watercourse is opened, the water level is monitored, and when the water level is lowered to a certain level below the water level There is a problem that the water level control is considerably inconvenient such as closing the water gate.

Therefore, in order to improve the above-mentioned conventional roll-type sluice gate, there has been an increase in the number of the conduction sluice gate having the operating structure of the sluice gate in the recent years. It is easy to control the water level by constantly maintaining the water level at all times.

However, the conventional conductive water gate as described above has a complicated structure because the water door is rotated by a cylinder operation structure in general, and in particular, a driving device such as a cylinder for driving the water gate is installed on the floor or in water It is necessary to carry out work in water in order to repair such a fault, and it is very inconvenient to maintenance such as troublesome maintenance, Particularly, due to the nature of operation in water, there is a problem that the corrosion is easily generated and the life span is not so long.

Therefore, it is urgent to improve the conductivity of the watertight water, which is excellent in water level control as described above.

Korea Utility Model Registration No. 20-0306425.

The present invention has been devised to solve the above-mentioned problems, and it is an object of the present invention to reduce the cost of constructing the apparatus while reducing the failure rate by simplifying the structure of the apparatus for driving the water- Is placed on the surface of the water to prevent the failure of the driving device due to sediments in the water, etc., and it is possible to perform simple maintenance on the water surface even in the event of a trouble, and maintenance thereof is very convenient, The present invention is directed to providing a conductive water gate having a water surface-mounted driving structure for extending the service life.

In order to accomplish the above objects, there is provided a conductive water gate, comprising: a shaft tread formed at the bottom of a waterway between the two side door frames; The lower end of which is open at the lower end of the shaft; And a drive device for interrupting the upward and downward movements of the watercraft, wherein the drive device comprises: a rack bar, one end of which is hinged to the rear surface of the watercraft from the rear of the watercourse; A fixing plate which is installed at a position higher than the upper end of the watertight door in a state where the water gate is standing up and which is paired on both sides in the width direction of the opposite side of the watertight doors of both sides and a fixing plate which connects both sides of the fixing plate so as to prevent interference with the rack bar Mounting brackets with side plates; And a forward / reverse drive type decelerating motor provided on a mounting bracket and having a drive shaft on which a pinion engaging with the rack bar is formed.

As described above, the conductive water gate having the above-mentioned water surface drive type structure is structurally significantly simplified such that the drive device for interrupting the water gate is provided with a pinion and rack bar operation structure driven by a motor, so that the failure rate is minimized It is possible to obtain the effect of reducing the cost required for constructing the equipment.

Further, since the driving device is located above the water surface, it is possible to prevent the failure of the operating yarn and the failure of the driving device due to sediment in the water.

In addition, it is possible to perform simple maintenance on the water surface even in the event of a failure, and its maintenance is very convenient. In particular, the effect of preventing the corrosion of the driving device due to moisture is prolonged.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view of a watertight door having a water surface-mounted drive structure according to the present invention; Fig.
2 is a sectional view of a watertight door having a water surface drive type structure according to the present invention.
3 is an exploded perspective view of another embodiment of a conductive watertight door having a water surface drive type structure according to the present invention.
4 is an exploded perspective view of another embodiment of a watertight door having a water surface-mounted drive structure according to the present invention.
5 is a cross-sectional view of another embodiment of a watertight door having a water surface-actuated structure according to the present invention.
6 is a cross-sectional view of another embodiment of a conductive watertight door having a water surface drive type structure according to the present invention.
7 is a side view of still another embodiment of a watertight door having a water surface-mounted drive structure of the present invention.
FIG. 8 is a water storage state diagram of a watertight container having a water surface-mounted driving structure according to the present invention. FIG.
Fig. 9 is a view showing the water gate opening state of the watertight conduit having the above water surface driving type structure.
10 is an open state view according to another embodiment of a watertight door having a water surface-mounted drive structure according to the present invention.
11 is a view showing the operation of a pressurizing means according to another embodiment of the present invention for a watertight conveying structure having a water surface drive type structure.
Fig. 12 is a watertight state view of a watertight door having a water surface drive type structure according to the present invention. Fig.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may appropriately define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It should be understood that various equivalents and modifications may be present.

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

FIG. 1 is a perspective view of a conductive watertight door having a water surface-mounted driving structure according to the present invention, and FIG. 2 is a sectional view of a conductive watertight door having a water surface-mounted driving structure according to the present invention.

As shown in Figs. 1 and 2, the conductive water gate 1 having a water surface-mounted driving structure according to the present invention comprises a shaft portion 100, a water gate 200, and a driving device 300.

The shaft portion 100 is formed with a pair of countertop frames 10 opposed to each other to form a normal conducting water gate and a concrete structure in which a waterway 20 is formed between the countertop frames 10 The shaft portion 100 is provided on the bottom surface of the water channel 20 between the male door frame 10 and the water channel 20 in the width direction of the water channel 20.

In the present invention, the lower end of the water gate 200 is formed in the shaft portion 100 and is rotatable around the shaft portion 100 as shown in FIG. It accomplishes.

The driving device 300 includes a rack bar 310, a mounting bracket 320 and a deceleration motor 330. The rack bar 310 rotates upward and downward of the water gate 200 formed in the shaft portion 100, .

First, the rack bar 310 has a plurality of gears formed on one surface thereof and has a predetermined length. One end of the rack bar 310 is disposed behind the water channel 20, that is, on the side where the water is stored, And the hinge H is connected to the rear surface of the hinge.

At this time, the rack bar 310 connected to the water gate 200 is positioned lower than the center of the water gate 200 in the horizontal direction, so that the rack bar 310 has sufficient resistance against the water pressure acting on the water gate so that the water gate 200 is twisted It is desirable to prevent such deformation.

The driving unit 300 includes a mounting bracket 320 fixed to the barrel frame 10 and having a rack bar 310 and a decelerating motor 330 as described below.

At this time, the mounting bracket 320 firstly includes a pair of fixing plates 321 and 321 ', which pair each side in the opposite width direction of the two side door frames 10, and a pair of rack bars 321 and 321' And the side plates 322 and 322 'that do not interfere with the mounting brackets 310. The mounting brackets 320 are configured to have an upper and a lower through-

The mounting bracket 320 is installed in the handlebar frame 10 so that its position is at least higher than the height of the water gate 200 in a state where the water gate 200 can stand up and store water as much as possible, As shown in FIG.

The driving unit 300 includes a decelerating motor 330 installed in the mounting bracket 320 and capable of driving in the forward and reverse directions. The decelerating motor 330 is provided with a driving shaft 331 for drawing out the driving shaft 331, Shaped pinion 332 having gear teeth meshed with the rack bar 310 is formed.

1 and 2, the mounting bracket 320 is installed on one side of the tailstock 10 (see FIG. 1), and the mounting bracket 320 Through the fixing plates 321 and 321 'on either side, and can be fixed through normal anchor bolting or the like when fixed.

The deceleration motor 330 is accommodated in the mounting box 340 together with the pinion 332 and the mounting box 340 is freely rotatable on the fixing plates 321 and 321 'from the inside of the mounting bracket 320 The rack bar 310 is extended from the lower portion of the mounting bracket 320 to the upper portion while penetrating through the installation box 340 and is engaged with the pinion 332 in the installation box 340. [ .

When the rack bar 310 penetrates through the installation box 340 and the pinion 332 is engaged with the rack box 310 as described above, the rack bar 310 is separated from the inside of the installation box 340 by a separate idler roller And the like.

3 to 5, the mounting bracket 320 may be installed between the two side door frames 10 through the support base 320a when the decelerating motor 330 is installed in the mounting bracket 320. [ As shown in FIG.

When the decelerating motor 330 is mounted to the mounting bracket 320, the decelerating motor 330 is fixed to any one of the fixing plates 321 and 321 'of the mounting bracket 320. At this time, Is constructed so as to be extended to another one of the fixed plates 321 and 321 'to which the deceleration motor 330 is fixed as described above.

That is, the deceleration motor 330 is configured to be installed inside the mounting bracket 320. At this time, the rack bar 310 is moved from the lower portion of the mounting bracket 320 passing through the upper and lower portions to the inlet and the pinion 332 And is configured to be drawn out to the upper portion of the mounting bracket 320.

The rack bar 310 and the pinion 332 are maintained in a state in which they are always engaged with each other. To this end, first, the length of the rack bar 310 on the opposite side of the gear portion of the rack bar 310 The guide groove 311 is formed.

The side plate 322 on the side of the rack bar 310 is further configured to include a pressing means 400 so as to apply a force of a force between the rack bar 310 and the pinion 332.

The pressing unit 400 includes a fixing block 420. The fixing block 420 is fixed to the side plate 322 and a pressing spring 410 having an elastic force to always push the fixing block 420 And a guide roller 430 is formed at the end of the pressing spring 410. The guide roller 430 is inserted into the guide groove 311 of the rack bar 310. [

That is, the pressing means 400 is connected to the rack bar 310 in a state where the guide roller 430 is always inserted in the guide groove 311 of the rack bar 310 while being fixed to the side plate 322 The pressing force of the pushing spring 410 is applied to the rack bar 310 to maintain the engagement between the rack bar 310 and the pinion 332.

In order to construct the conductive water gate 1 according to the present invention, the water gate 200 is rotated upward and downward with respect to the water gate 10. For this purpose, the water gate 200 and the water gate 200 The water leakage preventing means 500 for preventing the stored water from leaking to the opposite side of the water gate 200 through the clearance between the water gate 10 and the water gate 200 .

The water leakage preventing means 500 is installed on the opposite side of the water gate 200 from the rear of the water gate 200 to the opposite side of the water gate 200 from the bottom of the water channel 20, A leakage preventing member 510 having a height higher than the height is constituted.

The water leakage blocking member 510 is formed in the shape of a plate bent in the form of "⊂" so as to form a watertight groove 511 opened to the side of the water gate 200 in a plan view. A watertight groove 511 is formed in the water leakage blocking member 510, A watertight pad 512 is formed in a vertical direction at an end portion on the opening side of the watertight pad.

The water leakage preventing means 500 is provided at both sides of the rear side of the water gate 200 to have a height corresponding to the height of the water gate 200 and to intercept the water leakage blocking member 510, (520).

At this time, the watertight plate 520 constitutes a fixing portion 521 which is fixed to both sides of the water gate 200 through an anchor bolt B or the like, and the end portion of the fixing portion 521 forms a curved curvature, And a guide portion 523 formed in the watertight groove 511 at the rear end of the water pressure acting portion 522. The guide portion 523 is formed in the watertight groove 511 at this time, The two side surfaces are in close contact with the watertight pads 512 in a state in which the water gate 200 is built in.

That is, the waterproofing means 500 is in a state in which the guide portion 523 of the watertight plate 520 is always in close contact with the watertight pad 512, and water is supplied to the gap between the watertight door 10 and the watertight door 200 Thereby preventing the water from leaking through.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the operation of a conductive watercourse having the above-described water-surface driving structure according to the present invention will be described in detail with reference to the accompanying drawings.

First, the conductive water gate 1 having a water surface-mounted driving structure according to the present invention is configured to be capable of adjusting the level of water stored by a rotary operation like a normal conductive water gate. First, So that the water level of the stored water can be maintained at a maximum level.

Then, when discharging the stored water and adjusting the water level, the water level of the upper water level can be adjusted by rotating the water gate 200 like a normal conductive water gate.

9 and 10, it is possible to drive the decelerating motor 330 in order to rotate the water gate 200. When the decelerating motor 330 is pushed down to the lower side of the rack bar 310 The driving force in the rotational direction may be given.

Rotation force is applied to the pinion 332 formed on the drive shaft 331 along with the driving of the deceleration motor 330. The rack bar 310 meshed with the pinion 332 is rotated by the rotation of the pinion 332 So that the end of the rack bar 310 pushes the connected sluice gate 200. At this time the sluice gate 200 is laid on the axis of the shaft portion 100 and the height of the upper end of the sluice gate 200 .

However, in order to increase the water level, the operation of the decelerating motor 330 is operated in the opposite direction to pull the rack bar 310 to raise the water gate And detailed description thereof will be omitted.

That is, as described above, according to the driving operation of the decelerating motor 330, the rack bar 310 advances and the inclination of the water gate 200 can be adjusted and the water level can be adjusted accordingly. At this time, Of the rack bracket 310 is advanced through the upper and lower through portions of the mounting bracket 320. [

9, the rack bar 310 may be engaged with the pinion 332 at any time during the slope adjustment of the water gate 200. In this case, The mounting box 340 is mounted on the mounting bracket 320 when the mounting box 340 is received in the mounting box 340 and the mounting box 340 is mounted on the mounting bracket 320 in accordance with the angle change of the rack bar 310 And rotates around the axis 341 to correspond to the change in the angle of the rack bar 310.

The maintenance of the rack bar 310 and the pinion 332 can be performed by the pressing means 400 when the deceleration motor 330 is fixed to the mounting bracket 320 as shown in FIG.

11, the urging force of the urging spring 410 to always push the guide roller 430 is applied to the urging means 400, and the guide roller 430 urges the guide roller 430 in the direction The rack bar 310 is always pushed in the guide groove 311 so that the pitching force of the rack bar 310 and the pinion 332 is always maintained.

In this case, the pushing means 400 for applying a force of the rack bar 310 and the pinion 332 moves the rack bar 310 in the process of rotating the water gate 200 as described above The rolling force of the guide roller 430 acts on the guide groove 311 of the rack bar 310 and the rack bar 310 is not restricted by the movement of the rack bar 310. Accordingly, So that the pinion 332 and the pinion 332 are engaged with each other.

In the meantime, in the present invention, when water is stored through the water gate 200, the stored water is prevented from leaking to the opposite side of the water gate 200. This will be described with reference to FIGS. 6 and 7, The water leakage preventing member 500 is constructed such that the water leakage preventing member 510 is formed on the male door frame 10 and the watertight plate 520 is formed on the water gate 200, And the tight seal between the watertight plate 520 and the watertight plate 520.

12, the water pressure always acts on the water leakage blocking member 510 to cause the water leakage blocking member 510 to be brought into close contact with the barrel 10 side, The watertight pads 512 formed at the end portion of the watertight groove 511 at the open end side are brought into close contact with the guide portions 523 of the watertight plate 520 in the watertight grooves 511 so that the watertightness becomes possible.

The water pressure acting on the watertight plate 520 is applied to the watertight action portion 522 forming the curved curvature. The water pressure applied at this time is to open the guide portion 523 to the outside, that is, The adhesion between the guide portion 523 and the watertight pad 512 is increased.

That is, in the water leakage preventing member 510 and the watertight plate 520 of the water leakage preventing means 500, a hydraulic pressure acts on the water and the watertightness of the guide portion 523 of the watertight plate 520 and the watertight pad 512 The leakage of water due to the close adhesion force is prevented, and prevention of the leakage of water can be equally performed in the state where the water gate 200 is standing up or in a state where it is operated.

The conductive water gate having the above water surface driving type structure according to the present invention has a structure in which the driving device 300 for conducting the water gate 200 has a relatively simple structure and a simple structure of the deceleration motor 330 and the rack bar 310, The configuration is very simple and it is possible to easily check the operation state from the outside, thereby reducing the failure rate and reducing the cost for constructing the facility.

In addition, since the drive unit 300 is located above the water surface, it is possible to prevent breakdowns due to failure and corrosion caused by sediment in the water, and in case of failure, maintenance can be easily performed from the outside, It is very convenient, and its life span is also significantly improved.

As described above, the conductive water gate having the above water surface driving type structure of the present invention is advantageous in that it is very easy to control the water level like a conventional conductive water gate, and its failure rate is reduced and maintenance becomes very convenient.

10: Male frame 20: Water channel
100: Shaft part 200: Water gate
300: drive device 310: rack bar
311: Guide groove 320: Mounting bracket
320a: Supporting base 321, 321 ': Fixing plate
322,322 ': Side plate 330: Deceleration motor
331: drive shaft 332: pinion
340: Installation box 341: Axis
400: pressing means 410: pressing spring
420: fixing block 430: guide roller
500: leak preventing means 510: leak-barrier member
511: watertight groove 512: watertight pad
520: watertight plate 521:
522: water pressure acting portion 523: guide portion

Claims (5)

In conducting gates,
(100) formed at the bottom of the channel (20) between the two side door frames (10);
A water gate 200 having a lower end formed in the shaft portion 100 and rotating up and down; And
And a driving device (300) for interrupting upward and downward rotation of the water gate (200)
The driving device 300 includes:
A rack bar 310 which is hinged to the rear surface of the water gate 200 at one end thereof from the rear of the water channel 20;
A pair of fixing plates 321 and 321 'which are installed on the male door frame 10 at a position higher than the upper end of the water gate 200 in a state where the floodgates are standing and form a pair of opposite sides in the opposite width direction of the two side door frames 10' A mounting bracket 320 having side plates 322 and 322 'for connecting both sides of the fixing plates 321 and 321' so as to prevent interference with the rack bar 310; And
And a forward and reverse drive type reduction motor (330) having a drive shaft (331) provided on a mounting bracket (320) and formed with a pinion (332) engaged with the rack bar (310) Conducting watershed with structure.
The method according to claim 1,
The mounting bracket (320)
Is fixed to the male door frame 10 on either side through the fixing plates 321 and 321 'on either side,
The deceleration motor 330 is accommodated in the installation box 340 together with the pinion 332 and the installation box 340 is rotatably supported on the fixing plates 321 and 321 ' 341)
The rack bar (310) is configured to engage with the pinion (332) inside the installation box (340) while passing through the installation box (340) from the lower part of the installation bracket (320) Conducting watershed with structure.
The method according to claim 1,
The mounting bracket (320)
Is configured to be fixed to the male housing (10) through a support base (320a)
In the deceleration motor 330,
The driving shaft 331 is fixed to one of the fixing plates 321 and 321 'of the mounting bracket 320 while the driving shaft 331 is formed in another one of the fixing plates 321 and 321' ,
The rack bar (310) is constructed to be coupled to the pinion (332) while being configured to be drawn out from the lower part to the upper part between the upper and lower side plates (322) and (322 ' Conducting watershed with.
The method of claim 3,
A guide groove 311 is further formed on the opposite surface of the rack portion of the rack bar 310 in the longitudinal direction,
A fixing block 420 is formed at one end of the side plate 322 on the side of the rack bar 310 of the mounting bracket 320 and is fixed to the side plate 322. The other end of the fixing block 420 is inserted into the guide groove 311 of the rack bar 310 A guide roller 430 having a rolling force along the guide groove 311 and pressing means 400 as a pressing spring 410 for applying an elastic force to the rack bar 310 at all times ,
The rack bar (310) is configured such that a pressing force of the pressing spring (410) of the pressing means (400) applies a pressing force with the pinion (332) constantly. .
The method according to claim 1,
Further comprising a water leakage preventing means (500)
The water leakage preventing means (500)
The watertight grooves 511 are formed at the opposite sides of the opposite side of the watertight grooves 511 at the opposite side of the watertight grooves 511 in such a manner as to form a watertight groove 511 opened to the watertight door 200 in a plan view And a water leakage blocking member 510 formed with watertight pads 512,
At both sides of the rear side of the water gate 200 are provided a fixed portion 521 fixed to the water gate 200, a water pressure acting portion 522 curved rearward at a curvature at an end of the fixed portion 521, And a watertight plate 520 extending from the rear end of the acting portion 522 and having a guide portion 523 which is in close contact with the watertight pads 512 in the watertight groove 511,
The guide part 523 is received in the watertight groove 511 of the water leakage blocking member 510 while the guide part 523 is in tight contact with the watertight pad 512 to be watertight Conductive watershed with a water surface driven structure characterized by.

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