KR101036941B1 - Water-controlled hydrogate - Google Patents

Abstract

The present invention relates to a water-controlled hydrological device, in the case of discharging a large amount of water by forming an auxiliary sluice in the main sluice, while discharged through the opening of the main sluice, when a small amount of water is discharged installed in the auxiliary sluice The purpose is to match the pump on the outlet of the main sluice so that discharge can be achieved through the pump. The present invention configured for this purpose is a hydrological support structure formed with a guide groove up and down on the opposite surface; A main sluice having both ends inserted into a guide groove of the sluice support structure and being installed to be elevated, and having a discharge groove having a predetermined size in the center of the lower half; A main sluice actuator for opening and closing the sluice by elevating the main sluice up and down; Rails which are installed in the vertical direction on both front sides of the main sluice, each of which has a rail groove; Both ends are inserted into the rail groove of the rail is installed to be elevated, but the auxiliary gate for closing the discharge groove of the main gate; A discharge pump installed at the center of the auxiliary sluice on the same vertical line as the discharge groove of the main sluice but discharging water through driving when coinciding with the discharge sluice of the main sluice; And an auxiliary sluice actuator for elevating the auxiliary sluice to close the discharge groove of the main sluice or to match the discharge groove of the main sluice with the discharge pump.

Description

Water meter control device {A FLOOD-GATE}

The present invention relates to a water-controlled hydrologic apparatus, and more particularly, in the case of discharging a small amount of water by forming an auxiliary sluice in the main sluice, the pump installed in the auxiliary sluice matches the discharge port of the main sluice and discharged through the pump. It relates to a water-controlled hydrological device that can be made.

In general, as the importance of industrial water and agricultural water is rapidly increasing along with the general development of the industrial structure, the importance of hydrological devices that properly control the amount and discharge of water stored in a certain reservoir space is greatly increased. In particular, irrigation canals and waterways such as rivers and reservoirs are used for the purpose of storing a certain amount of water when needed to use farmland management or irrigation water.

On the other hand, the waterway as described above is provided with a hydrological device for opening and closing the water gate to manage the irrigation water, that is, when the amount of rain to store the water in case of drought when the amount of rain is large. Such a hydrologic device is divided into a conductive type in which the water gate is conducted in the same direction as the discharged water and a bottom discharge type in which the flowing water is discharged to the bottom of the water gate.

In the above-described configuration of the hydrological device, the conductive hydrological device has an advantage in that when a flood occurs, foreign substances can be completely discharged without catching a hydrological gate. On the other hand, the lower drainage hydrologic device does not need sedimentary dredging because sediment does not accumulate, and since the fishery is naturally formed, it is not necessary to construct a separate fishery, which can reduce construction period and construction cost, Since the bottom is discharged, there are excellent advantages such as water quality improvement.

In particular, in the configuration of the hydrological gate according to the prior art as described above, the conductive hydrological device and the bottom discharge hydrological device has advantages such as minimizing flood damage by horizontal opening when the water level increases rapidly. Sluice devices are developed that combine the advantages of the lower drainage device.

However, in the configuration of the hydrological device according to the prior art as described above, since the size of the hydrological gate is basically large, there is a problem that a large amount of water is discharged or discharged when a small amount of water is discharged or discharged. . Therefore, there is a problem in controlling the amount of discharged water.

The present invention has been made to solve all the problems of the prior art, in the case of releasing a large amount of water by constituting an auxiliary sluice in the main sluice, while the discharge through the opening of the main sluice, when a small amount of water is discharged It is an object of the present invention to provide a water-controlled hydrological device in which a pump installed in the auxiliary floodgate is discharged through the pump by matching the discharge port of the main floodgate.

In addition, the technique according to the present invention has an object to facilitate the control of the discharge amount by elevating the main gate and the auxiliary gate as the number of water to be discharged by configuring the auxiliary gate and the pump in the main gate. .

The present invention configured to achieve the above object is as follows. That is, the water-controlled hydrological device according to the present invention is a hydrological support structure formed with a guide groove up and down on the opposite surface; A main sluice having both ends inserted into a guide groove of the sluice support structure and being installed to be elevated, and having a discharge groove having a predetermined size in the center of the lower half; A main sluice actuator for opening and closing the sluice by elevating the main sluice up and down; Rails which are installed in the vertical direction on both front sides of the main sluice, each of which has a rail groove; Both ends are inserted into the rail groove of the rail is installed to be elevated, but the auxiliary gate for closing the discharge groove of the main gate; A discharge pump installed at the center of the auxiliary sluice on the same vertical line as the discharge groove of the main sluice but discharging water through driving when coinciding with the discharge sluice of the main sluice; And an auxiliary sluice actuator for elevating the auxiliary sluice to close the discharge groove of the main sluice or to match the discharge groove of the main sluice with the discharge pump.

On the other hand, in the configuration of the present invention as described above, a plurality of pressure rollers are rotatably installed on each of the rails so as to press the auxiliary sluice to the front of the main sluice may be further configured.

In addition, the rail groove of the rail in the configuration according to the present invention may be configured to be narrow on the horizontal line formed with the discharge groove of the main sluice may be configured to be in close contact with the front of the main sluice.

According to the technique of the present invention, when a large amount of water is discharged by constituting an auxiliary sluice in the main sluice, the water is discharged through the opening of the main sluice, whereas when a small amount of water is discharged, a pump installed in the auxiliary sluice discharges the main sluice. The phases can be matched to allow discharge through the pump.

In addition, the technology according to the present invention has the advantage that the amount of water to be discharged by configuring the secondary sluice and the pump in the main sluice to facilitate the adjustment of the discharge amount by elevating the main sluice and the auxiliary sluice.

1 is a perspective configuration showing a closed state of the water gate of the water-controlled hydrological device according to the present invention.
2 is a side cross-sectional view of FIG.
Figure 3 is a perspective configuration showing a small amount of water discharged through the water-controlled hydrological device according to the present invention.
4 is a side cross-sectional view of FIG. 3.
Figure 5 is a perspective configuration showing a large amount of water discharged through the water-controlled hydrological device according to the present invention.
6 is a side cross-sectional view of FIG.

Hereinafter will be described in more detail the water-controlled hydrological device according to a preferred embodiment of the present invention.

1 is a perspective configuration showing a closed gate of the water-controlled hydrological device according to the present invention, Figure 2 is a side cross-sectional view of Figure 1, Figure 3 is a small amount through the water-controlled hydrological device according to the present invention Fig. 4 is a side cross-sectional view of Fig. 3, Fig. 5 is a perspective view showing a large amount of water discharged through a water-controlled hydrological device according to the present invention. It is a side cross-sectional block diagram of 5.

As shown in Figure 1 to Figure 6 of the water-controlled hydrological device 100 according to the present invention is the hydrological support structure 110, the hydrological support structure 110, the guide groove 112 is formed on the opposite surface up and down Both ends are inserted into the guide grooves 112 so as to be lifted up and down, and the main water gate 120 and the main water gate 120 having a predetermined size of the discharge groove 122 are formed at the center of the lower half to open and close the water gate. The main sluice actuator 130 and the main sluice 120 are formed to face each other in the vertical direction in the vertical direction, respectively, the rail 140 having the rail groove 142 formed therein, the rail groove 142 of the rail 140. The both ends are inserted into the upper and lower sides of the auxiliary sluice 150 to close the discharge groove 122 of the main sluice 120, and the auxiliary sluice on the same vertical line as the discharge groove 122 of the main sluice 120 ( 150) is installed in the center of the drive when it matches the discharge groove 122 of the main sluice 120 Lifting the discharge pump 160 and the auxiliary sluice 150 for discharging the water through to close the discharge groove 122 of the main sluice 120 or discharge groove 122 and the discharge pump 160 of the main sluice 120 It consists of a configuration including an auxiliary sluice actuator 170 to match.

In the water-controlled hydrological device 100 according to the present invention configured as described above, as shown in FIGS. 1 and 2, the main gate 120 and the auxiliary gate 150 descend so that the water gate and the discharge groove 122 are provided. In the case of discharging a small amount of water in a fully closed state, as shown in FIGS. 3 and 4, the auxiliary floodgate 150 is raised by driving the auxiliary floodgate actuator 170 to discharge the grooves of the main floodgate 120. Reference is made to 122 and the discharge pump 160 installed in the auxiliary sluice 150.

Next, as described above, when the discharge pump 160 installed in the discharge groove 122 of the main sluice 120 and the discharge pump 160 installed in the auxiliary sluice 150 coincides with the water, the water is the main sluice 120. ) Is discharged to the discharge pump 160 of the auxiliary sluice 150 through a water channel through the discharge groove 122.

On the other hand, as shown in Figures 1 and 2 when the main gate 120 and the auxiliary gate 150 is lowered to discharge a large amount of water in the state in which the water gate and the discharge groove 122 is all closed 5 And as shown in Figure 6 by operating the main sluice actuator 130 and the auxiliary sluice actuator 170 at the same time so that the main sluice 120 and the auxiliary sluice 150 are raised at the same time the lower end of the hydrologic support structure 110 Open to release a large amount of water.

Hereinafter, each component of the water-controlled hydrological device 100 according to the present invention will be described in detail. First, the sluice support structure 110 is for supporting the main sluice 120 to be lifted and lifted, and the sluice support structure 110 is shown at both sides across a waterway such as a water channel as shown in FIGS. 1 to 6. It is installed. At this time, the sluice support structure 110 is provided on both sides but is made of a configuration in which the guide groove 112 is formed on the opposite surface up and down.

Next, the main sluice 120 constituting the present invention is to allow the discharge or storage of water to be made by opening and closing the sluice formed by the sluice support structure 110, such a main sluice 120 is 1 to FIG. As shown in 6, both ends are inserted into the guide grooves 112 of the sluice support structure 110 so as to be elevated, and the discharge grooves 122 having a predetermined size are formed in the center of the lower half.

The main sluice 120 configured as described above is formed in a plate shape having a size corresponding to the width between the guide grooves 112 of both sluice support structures 110 so that both ends are inserted into the guide grooves 112 and installed to be elevated. It is done. In addition, the discharge groove 122 is formed in the center of the main sluice 120 to a certain size so that the discharge groove 122 is formed in the center of the lower half of the main sluice 120 so that the discharge groove 122 can be immersed in the stored water even when the water level is low do.

The main sluice actuator 130 constituting the present invention is to elevate the main sluice 120 to open or close the sluice to discharge or store water, and the main sluice actuator 130 is illustrated in FIGS. As shown in FIG. 6, the upper and lower structures (not shown) or steel structures (not shown) that connect the upper portions of the two hydrologic support structures 110 are fixed to each other so that the lower end is disposed on the upper center of the main floodgate 120. Connected.

The main sluice actuator 130 configured as described above used a hydraulic type that can exert large force in general. That is, the main sluice actuator 130 is made of a cylinder-like configuration including a piston. The main sluice actuator 130 configured as described above is operated by the action of hydraulic pressure to raise or lower the main sluice 120 to open the sluice which is a space between the sluice supporting structures 110 so that water can be discharged or The water gate, which is a space between the supporting structures 110, is closed so that the reservoir can be made.

Next, the rail 140 constituting the present invention is to guide the lifting and lowering of the auxiliary gate 150 to discharge the stored water in a small amount, such a rail 140 as shown in Figures 1 to 6 On both sides of the front of the main sluice 120 is installed in the vertical direction.

As described above, the rail groove 142 for inserting and supporting the both ends of the auxiliary sluice 150 on the opposite surface of the rail 140 installed in the vertical direction on both front sides of the main sluice 120 to move up and down. Each is formed.

Meanwhile, in the configuration of the rail 140 as described above, the rail groove 142 is configured to be narrowed on the horizontal line on which the discharge groove 122 of the main sluice 120 is formed, and the auxiliary sluice 150 includes the main sluice 120. It is configured to be in close contact with the front of the. That is, the rail groove 142 is formed in a configuration in which the discharge grooves 122 of the main sluice 120 are formed on the horizontal line so that the closing of the discharge grooves 122 of the main sluice 120 can be more strongly performed. have.

The auxiliary sluice 150 constituting the present invention is to open and close the discharge groove 122 formed in the center of the lower half of the main sluice 120, the auxiliary sluice 150 is a rail as shown in Figures 1 to 6 Both ends are inserted into the rail grooves 142 of the 140 and are installed to be elevated, but the discharge grooves 122 of the main sluice 120 are closed.

On the other hand, the auxiliary sluice 150 configured as described above is formed in a plate shape of the width corresponding to the width between the rail grooves 142 formed on each of the rails 140, both ends of the rail groove 142 of the rail 140 It is inserted in a liftable manner on the top. As described above, the auxiliary sluice 150 configured as described above is further in close contact with the front of the main sluice 120 through the rail groove 142 having a configuration narrowing on a horizontal line on which the discharge groove 122 of the main sluice 120 is formed. The discharge groove 122 of the main sluice 120 can be tightly closed.

Next, the discharge pump 160 constituting the present invention is for discharging the stored water in a small amount, the discharge pump 160 is the discharge groove of the main sluice 120 as shown in Figs. It is installed in the center of the secondary sluice 120 on the same vertical line as the 122 to discharge the water through the drive when coinciding with the discharge groove 122 of the main sluice 120.

In other words, the discharge pump 160 is installed to discharge the stored water in a small amount, and descends to the lower end of the hydrologic support structure 110 of the main hydrology 120 to completely close the hydrology between the hydrologic support structures 110. When the auxiliary floodgate 150 is raised to match the discharge groove 122 of the main floodgate 120 and the discharge pump 160 of the auxiliary floodgate 150, and then driven through electrical application, The discharge is discharged through the discharge pump 160 via the discharge groove 122.

Meanwhile, the auxiliary sluice actuator 170 constituting the present invention lifts the auxiliary sluice 150 to open or close the discharge groove 122 of the main sluice 120 so that a small amount of stored water can be discharged. For this purpose, the auxiliary sluice actuator 170 to lift the auxiliary sluice 150 as shown in Figures 1 to 6 to close the discharge groove 122 of the main sluice 120 or of the main sluice 120 The discharge groove 122 and the discharge pump 160 to match.

The auxiliary sluice actuator 170 configured as described above used a hydraulic type that can exert large force in general. That is, the auxiliary sluice actuator 170 is made of a cylinder-like configuration including a piston. The auxiliary sluice actuator 170 configured as described above is operated by the action of hydraulic pressure to raise or lower the auxiliary sluice 150 to match the discharge groove 122 and the discharge pump 160 of the main sluice 120 or the main sluice. The discharge groove 122 of the 120 is closed.

In addition, the auxiliary sluice actuator 170 configured as described above, like the main sluice actuator 130, an upper structure (not shown) or a steel structure (not shown) that connects the upper portions of both sluice support structures 110. The bottom is fixed to the support is connected to the top of the auxiliary gate 150.

On the other hand, in addition to the above-described configuration, the water-controlled hydrological device 100 according to the present invention is rotatably installed up and down on each of the rails 140 so that the auxiliary gate 150 is pressed against the front of the main gate 120. A plurality of pressing roller 180 may be further configured. At this time, the plurality of pressure roller 180 is installed on the rail groove 142 of the rail 140 made of a configuration narrowed on the horizontal line formed with the discharge groove 122 of the main sluice 120 as described above.

As described above, the water-controlled watermark device 100 according to the present invention is to discharge the water stored in the water through the configuration of the discharge groove 122, the auxiliary water gate 150 and the discharge pump 160 in a small amount of the main water gate It is possible to easily discharge a small amount of water by matching the discharge groove 122 and the discharge pump 160 while raising the auxiliary gate 150 without opening the 120.

The present invention is not limited to the above embodiments, and various modifications can be made within the scope of the technical idea of the present invention.

100. Hydrologic device 110. Hydrologic support structure
112. Guide groove 120. Main gate
122. Discharge groove 130. Main sluice actuator
140.Rail 142.Rail groove
150. Secondary gate 160. Discharge pump
170. Auxiliary Gate Actuator 180. Press Roller

Claims (3)

A hydrologic support structure having guide grooves formed up and down on an opposite surface, a main hydrology which is inserted at both ends into guide grooves of the hydrologic support structure to be elevated, and the main hydrogate is moved up and down to open and close the hydrologic gate. The main sluice actuator, which is installed in the vertical direction on both sides of the front sluice of the main sluice, has a rail in which a rail groove is formed, and an auxiliary sluice that is inserted into the rail groove of the rail so as to be elevated, and discharges water. In the water-controlled hydrologic device comprising a pump and an auxiliary gate actuator for elevating the auxiliary gate,
Discharge grooves are formed in a predetermined size in the center of the lower half of the main sluice, but the discharge grooves are closed by the auxiliary sluice,
Is installed rotatably up and down on each of the rails is composed of a plurality of pressure rollers to press the auxiliary sluice in close contact with the front of the main sluice,
The rail groove is formed in a narrow structure on the horizontal line formed with the discharge groove,
The discharge pump is installed in the central portion of the auxiliary sluice on the same vertical line as the discharge groove to discharge water through driving when coinciding with the discharge groove.
The water discharge control device of claim 1, wherein the discharge groove is closed or the discharge groove coincides with the discharge pump when the auxiliary gate is lifted by the auxiliary gate actuator. delete delete

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