KR101651793B1 - Tube floodgate module - Google Patents

Abstract

The present invention relates to a tube floodgate module comprising: a base unit (1000) installed in a waterway (3) of a dam (2); a tube floodgate unit (2000) installed on the base unit (1000) and lifted or lowered in order to discharge extra water when a quantity of water of the dam (2) is a predetermined quantity or greater; and a protecting unit (3000) installed on the base unit (1000) and surrounding the tube floodgate unit (2000) in order to protect the lifted or lowered tube floodgate unit (2000). Since the base unit (1000), the tube floodgate unit (2000), and the protecting unit (3000) are formed as a single integrated module, an installation time and installation costs of a tube floodgate installed in the dam (2) can be minimized and overall installation costs and installation time of the dam (2) can be reduced.

Description

Tube floodgate module

The present invention relates to a tube hydrologic module, and more particularly, to a tube hydrologic module which comprises a base unit, a tube hydrologic unit, and a protection unit as one integrated module, minimizing installation time and installation cost of the tube water installed in the dam, The present invention relates to a tube sluice module capable of easily replacing an aged tube sluice by a standardized tube sluice module suited to the size of a dam and reducing manufacturing cost and manufacturing time of the sluice tube.

Generally, hydrological systems are installed in agricultural, industrial or water supply water resources, for example, in the floodgate or underwater reservoir of a dam to secure water.

Generally, the conventional water gate is formed of iron gate, and the water level is adjusted by controlling the height while the water gate moves in the vertical direction with respect to the installation direction of the dam.

In the past, the water gate was constructed in the form of a hydrographic sluice to hold the water pressure. As such, the water gate formed by the iron is made several times thicker than the proper thickness to support the water pressure for safety, so that the cost of operating the heavy water gate is increased and the strength is lowered by the corrosion The durability is reduced, and the iron sluices whose durability is reduced in safety are frequently replaced, resulting in a great cost and waste of resources. On the other hand, there has been a problem that the environment is destroyed because it is not possible to perform freshing which frequently changes the water before deteriorating the detritus.

In order to compensate for the disadvantages of such irrigation water, the water level of the dam was adjusted by opening and closing the water gate using the water gate which can be expanded and contracted.

However, in the case of a conventional tube, there is a problem that the tube gate can be damaged due to natural shrubs or sharp floating materials due to expansion and contraction of the tube gate.

In addition, when the tube gate is broken, the level of the dam can not be easily adjusted, and the durability of the dam is lowered due to the pressure of the water discharged through the damaged gate, which seriously threatens the stability of the dam.

Further, it takes a lot of cost and time to install a protection unit for protecting the tube gate, and a separate space for installing the protection unit has to be formed, thereby increasing the installation cost and installation time of the dam.

Korean Patent Laid-Open Publication No. 10-2012-0017217

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a method for installing a tube unit, a tube gate unit and a protection unit in a single integrated module, And to reduce the installation cost and installation time of the dam as a whole.

Yet another object of the present invention is to provide a method and system for easily replacing obsolete tube gates by the standardized tube gates of the various sizes of dams, reducing the manufacturing cost and manufacturing time of the tube gates, , A tube sluice module capable of preventing the tube sluice from being broken by the protection unit and having a riblet formed on the upper surface of the protection unit to rapidly discharge water to be discharged and to distribute the load, thereby improving the stability of the dam .

In order to accomplish the object of the present invention, a tube sluice module according to a preferred embodiment of the present invention includes a base unit 1000 installed on a waterway 3 of a dam 2; A tube gate unit 2000 installed on the base unit 1000 to move up and down to flow extra water when the quantity of the dam 2 becomes a predetermined amount or more; And a protection unit 3000 installed on the base unit 1000 so as to surround the tube gate unit 2000 to protect the tube gate unit 2000 moving up and down.

The base unit 1000 of the tube hydrological module according to another preferred embodiment of the present invention further includes a base 1100 installed at the bottom of the waterway 3 of the dam 2 in the same direction as the waterway 3, ); A column portion 1200 formed on the upper portion of the base portion 1100 so as to face each other at both sides of the base portion 1100 along the height direction of the tube gate unit; And a receiving portion 1300 formed inside the base portion 1100 to receive the tube sluice unit 2000.

In addition, the receiving unit 1300 of the base unit of the tube hydrologic module according to another preferred embodiment of the present invention includes the base 1100 (not shown) inside the base 1100 so that the tube sluice 2000 can move up and down, A tube-water-installation-space part 1310 formed in a height direction of the tube-shaped water-tank installation space 1310; The length of the base 1100 in the base 1100 so as to be perpendicular to the tube sidewall installation space 1310 to form a working space and a driving unit for raising and lowering the tube sluice 2200, And a work space part 1320 formed in the direction of the first axis.

The base unit 1000 of the tube hydrologic module according to another preferred embodiment of the present invention has a penetration portion corresponding to the tube gate installation space portion 1310 of the accommodation portion 1300, And a main plate part 1400 provided on the upper surface of the base part 1100 along the longitudinal direction of the base part 1100 between the base part 1100 and the base part 1100. [

Further, the column portion 1200 of the tube gate module according to another preferred embodiment of the present invention includes an entrance 1210 formed on the upper side or the side surface of the column portion 1200; And a passage part 1220 formed in the tube part 1200 to communicate with the tube hydrologic installation space 1310 and the work space part 1320.

In addition, the tube gate unit 2000 of the tube gate module according to another preferred embodiment of the present invention is adjacent to the inside of the column portion 1200 and is parallel to the column portion 1200, A support portion 2100 fixed to the upper surface of the space portion 1310; The tube gate 2200 is connected to the support portion 2100 and opens and closes the water channel 3 of the dam 2 while being compressed or expanded in the height direction of the column portion 1200 along the support portion 2100. [ ; And an air supply part 2300 installed in the column part 1200 to supply or recover the compressed air to the tube gate 2200 through a supply pipe.

In addition, the protection unit 3000 of the tube gate module according to another preferred embodiment of the present invention includes a connection portion 3100 for protecting the upper portion of the tube gate unit 2000; A first protection part 3200 coupled to one side of the connection part 3100 by hinge connection to protect one side of the tube gate unit 2000; A second protector 3300 hinged to the other side of the connection part 3100 to protect the other side of the tube gate unit 2000; The other end of the main protector 3200 is hinged to the lower end of the first protector 3200 and slidable along the longitudinal direction of the main plate portion 1400 when the tube gate 2200 ascends / A first sliding portion 3400 connected to the plate portion 1400; And the other end is connected to the lower end of the second protector 3300 by a hinge and is slidable along the longitudinal direction of the main plate portion 1400 when the tube gate 2200 ascends and descends. And a second sliding portion 3500 connected to the main plate portion 1400.

The upper surface of the connection portion 3100 of the protection unit of the tube gate module according to another preferred embodiment of the present invention, the upper surface of the first protection portion 3200, the upper surface of the second protection portion 3300 Ribs may be formed on the upper surface of the first sliding portion 3400 and the upper surface of the second sliding portion 3500.

In addition, the first sliding portion 3400 of the protection unit of the tube gate module according to another preferred embodiment of the present invention is fixed to the main plate portion 1400 by the guide rail 1410 formed on the upper surface of the main plate portion 1400, A first moving block portion 3410 slidably installed along the longitudinal direction of the plate portion 1400; A first engaging plate portion 3420 connected to the lower end of the first protector 3200 by a hinge; And at least one first intermediate plate portion (3430) movably connected between the first moving block portion (3410) and the first engaging plate portion (3420) so as to be movable along the longitudinal direction of the main plate portion (1400); And the second sliding portion 3500 is installed to be slidable along the longitudinal direction of the main plate portion 1400 by a guide rail 1410 formed on the upper surface of the main plate portion 1400 A second movable block portion 3510; A second engaging plate portion 3520 connected to the lower end of the second protector 3300 by hinge coupling; And at least one second intermediate plate portion 3530 connected between the second moving block portion 3510 and the second engaging plate portion 3520 so as to be movable along the longitudinal direction of the main plate portion 1400; . ≪ / RTI >

In addition, the first intermediate plate portion 3430 of the protection unit of the tube hydrologic module according to another preferred embodiment of the present invention is installed on the upper portion of the first coupling plate portion 3420, (3530) may be installed on the upper portion of the second engaging plate portion 3520.

The tube hydrologic module according to the present invention is formed by integrally forming the base unit, the tube hydrologic unit, and the protection unit into one integrated module, minimizing the installation time and installation cost of the tube water installed in the dam, Can be reduced.

In addition, the tube gate module according to the present invention can easily replace the aged tube gate with a standardized tube gate module that is sized according to various dam sizes, and can reduce the manufacturing cost and manufacturing time of the tube gate There is an effect.

In addition, since the tubular hydrologic module according to the present invention minimizes the installation space of the protection unit by forming the integrated tube as the integrated module, it is possible to miniaturize the tubular hydrologic module. Therefore, The present invention can be applied to an underwater vehicle for a vehicle.

In addition, the tube gate module according to the present invention prevents the tube gate from being broken by the protection unit and prevents the tube gate from being damaged by the upper surface of the connecting portion, the upper surface of the first protection portion, the upper surface of the second protection portion, As the ribs are formed on the upper surface of the second sliding portion, when the tube sluice descends and water is discharged along the water channel of the dam, water is rapidly discharged along the riblet and the load is dispersed, There is an effect that the stability can be increased.

 On the other hand, there is an effect that it is possible to prevent the environment from being destroyed due to the flushing operation before the water is decayed through the opening of the smooth tube water door.

FIG. 1 is a perspective view of a tube gate module according to an embodiment of the present invention in a state in which a tube gate is lifted. FIG.
FIG. 2 is a perspective view of the tube gate module shown in FIG. 1 in a state in which the tube gate is lowered. FIG.
3 shows a transparent perspective view of a base unit of a tube hydrologic module according to an embodiment of the present invention.
4 illustrates a cross-sectional view of a tube gate unit of a tube gate module according to an embodiment of the present invention.
5 is an exploded perspective view of a protection unit of a tube hydrologic module according to an embodiment of the present invention.
6 is a perspective view of the protection unit of the tube gate module according to an embodiment of the present invention in an elevated state.
7 shows a side view of the protection unit shown in Fig.
8 is an enlarged view of the first protector of the protection unit shown in Fig.
Fig. 9 shows an enlarged view of the second protector of the protection unit shown in Fig. 6;

Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, like reference numerals are used to refer to like elements throughout.

FIG. 1 is a perspective view of a tube gate module according to an embodiment of the present invention in a state in which a tube gate is lifted, and FIG. 2 is a perspective view showing a tube gate of the tube gate module shown in FIG. 1 in a lowered state . FIG. 3 shows a transparent perspective view of a base unit of a tube hydrologic module according to an embodiment of the present invention, and FIG. 4 shows a sectional view of a tube hydrologic unit of a tube hydrologic module according to an embodiment of the present invention. FIG. 5 is an exploded perspective view of a protection unit of a tube gate module according to an embodiment of the present invention, FIG. 6 is a perspective view of a protection unit of a tube gate module according to an embodiment of the present invention, 7 shows a side view of the protection unit shown in Fig. Fig. 8 shows an enlarged view of the first protector of the protection unit shown in Fig. 6, and Fig. 9 shows an enlarged view of the second protector of the protection unit shown in Fig.

The terms used in the present invention are defined as follows. The "height direction" means the direction from the bottom to the top of the dam. In other words, the term "height direction" means a direction indicating the depth of water stored in the dam. "Longitudinal direction" means a direction in which water stored inside the dam is discharged to the outside of the dam, i.e., a direction in which water flows.

1 to 9, a tubular water gate module 1 according to the present invention will be described. As shown in FIGS. 1 and 2, the tutus module 1 according to an embodiment of the present invention comprises a base unit 1000, a tube gate unit 2000, and a protection unit 300.

The base unit 1000 is installed on the water channel 3 of the dam 2 to form the outer shape of the tube gate module 1.

The tube hydrologic unit 2000 is installed on the base unit 1000 so as to be ascendable and descendable. The tubular hydrologic unit 2000 is installed in the base unit 1000 so as to be able to ascend and descend so that the excess water stored in the dam 2 flows to the outside of the dam 2 when the quantity of the dam 2 becomes a certain amount or more can send.

The protection unit 3000 is installed in the base unit 1000 so as to surround the front and rear of the tube gate unit 2000 to protect the tube gate unit 2000 from rising and falling.

That is, since the protection unit 3000 is installed so as to surround the outside of the tube gate unit 2000, it is possible to prevent the tube gate 2200 from being damaged by natural shrubs, sharp floats, or the like.

As described above, since the base unit 1000, the tube hydrologic unit 2000 and the protection unit 3000 are formed by one integrated module, when the tube hydrological module 1 is installed in the dam 2, Minimizing costs, and reducing overall construction costs and construction time of the dam.

In addition, since the tube gate module 1 according to the present invention is formed of one integrated module that is standardized to various dam sizes, it is possible to easily replace the aged tube gate, Can be saved.

3, the base unit 1000 of the tube hydrological module 1 according to an embodiment of the present invention includes a base portion 1100, a column portion 1200, a receiving portion 1300, (1400).

The base portion 1100 is installed at the bottom of the waterway 3 of the dam 2 in the same direction as the waterway 3, that is, in the same direction as the flow direction of water.

The column portions 1200 are formed along the height direction of the tube sill unit 2000 at the upper portion of the base portion 1100 while facing each other at both middle portions of the base portion 1100. That is, the column portion 1200 is installed on the upper portion of the base portion 1100 so as to have a predetermined height according to the size of the dam 2 and the size of the tube gate unit 2000.

The receiving portion 1300 is formed inside the base portion 1100 to receive the tube gate unit 2000. As the receiving portion 1300 is formed, the tube gate unit 2000 can be adjusted to the amount of water stored in the dam 2 while rising and falling according to the height of the dam 2.

3, the receiving portion 1300 of the base unit 1000 of the tube hydrological module 1 according to an embodiment of the present invention includes a tube hydrangea setting space portion 1310 and a work space portion 1320 .

The tube gate installation space portion 1310 is formed in the height direction of the base portion 1100 inside the base portion 1100 so that the tube gate 2200 can move up and down. In other words, the tube gate installation space 1310 is installed such that the interior of the foundation 1100 is partly embedded therein.

The tube gate installation space 1310 is embedded in the base 1100 along the height direction of the foundation 1100 so that the tube gate 2200 of the tube gate unit 2000 is lifted or lowered It is possible to realize stable upward and downward movement of the tube sluice 2200 as there is no interference in the height direction of the dam 2 and the width direction of the dam 2. [

The work space portion 1320 is formed in the base portion 1100 so as to be perpendicular to the tube hydrology installation space portion 1310 so as to form a working space for a manager and a driver for the ascending and descending operations of the tube sluice 2000, (1100). That is, the work space portion 1320 is formed to penetrate the base portion 1100 in the longitudinal direction of the base portion 1100 while communicating with the lower end portion of the tube water gate installation space portion 1310.

As such, since the work space portion 1320 is formed, a sufficient space is secured for the maintenance of the driving portion of the tube sluice 2200 and the tube sluice 2200, thereby improving the operational convenience of the manager.

3, the main plate portion 1400 of the base unit 1000 of the tube hydrological module 1 according to the embodiment of the present invention is installed in the tube hydrangea setting space portion 1310 of the receiving portion 1300 And is provided on the upper surface of the base portion 1100 along the longitudinal direction of the base portion 1100 between the column portions 1200. [

As described above, since the main plate portion 1400 is provided on the upper surface of the base portion 1100, the protection unit 3000 described later can be easily slid in conjunction with the rising and falling of the tube sluice 2200 of the tube sluice unit 2000 Thereby protecting the tube gate 2200 while moving.

3, the column portion 1200 of the base unit 1000 of the tube hydrological module 1 according to an embodiment of the present invention includes an entrance port 1210 and a passage portion 1220.

An entrance 1210 is formed on the top or side of the column part 1200. The entrance 1210 may be formed to connect the inside of the dam 2 to the tube sidewall installation space 1310 or the work space 1320 in the lower portion of the column 1200, if necessary.

The passage portion 1220 is formed in the inside of the column portion 1200 so as to communicate with the tube gate installation space portion 1310 and the work space portion 1320.

As the entrance 1210 and the passage 1220 are formed, the administrator can easily access the tube-sidewall-installation space 1310 and the work- space 1320, thereby allowing the administrator to easily repair the tube- And the malfunction of the tube gate module 1 can be prevented and the lifetime of the tube gate module 1 can be increased.

Further, since the space for installing various driving-related parts for driving the tube hydrologic unit 2000 is secured by forming the tube hydrologic installation space 1310, the work space 1320, and the passage 1220, The size of the hydrological module 1 can be reduced.

Although not necessarily limited, the base unit 1000 may be formed of concrete, steel material, or reinforced plastic.

The base unit 1000 of the tube hydrological module 1 according to an embodiment of the present invention includes an upper plate 210 for protecting the upper portion of the tube hydrology unit 2000 and the upper portion of the column portion 1200, As shown in FIG.

That is, the upper plate is formed in the shape of a plate having one side connected to one side of the column part 1200 and the other side connected to the other side of the column part 1200, and the upper part of the column part 1200, As shown in FIG.

Further, if necessary, a filtering net may be installed at the lower part of the upper plate or at the upper part of the tube sill 2200 of the tube sill unit 2000 so as to filter foreign substances floating in the water.

4, the tube gate unit 2000 of the tube gate module 1 according to an embodiment of the present invention comprises a support portion 2100, a tube gate 2200, and an air supply portion 2300.

The support portion 2100 is parallel to the column portion 1200 and is fixed to the upper surface of the tube-side water-installation space portion 1310 at one end, adjacent to the inside of the column portion 1200. That is, the support portions 2100 are installed in pairs so as to be parallel to the column portions 1200.

Both sides of the tube gate 2200 are connected to the support portion 2100. The tube gate 2200 opens or closes the water channel 3 of the dam 2 while compressing or expanding in the height direction of the column portion 1200 along the support portion 2100.

When the compressed air is supplied from the air supply unit 2300 through the supply pipe 2300, the tube gate 2200 expands and flows into the water channel 2300 of the dam 2. In other words, the air supply unit 2300 described later and the tube gate 2200 are connected through a supply pipe. (See Fig. 1)

On the contrary, when the compressed air is recovered through the supply pipe at the air supply part 2300, the tube gate 2200 is compressed to open the water channel 3 of the dam 2 (see FIG. 2).

The air supply part 230 is installed in the column part 1200 to supply or recover the compressed air to the tube gate 2200 through the supply pipe. That is, the air supply part 230 may be installed on the upper part of the column part 1200, the tube hydrological installation space part 1310, the work space part 1320, or the passage part 1220, if necessary.

As the air supply part 230 and the supply pipe can be installed on the column part 1200 in various forms, the tube gate module 1 can be manufactured in a desired size according to the size of the dam 2.

The tube gate 2200 may be formed of an elastic material having a predetermined strength for compression and expansion.

The tube gate unit 2000 of the tube gate module 1 according to another embodiment of the present invention may further include height adjusting means.

The height adjusting means raises or lowers the tube sluice 2200 according to the level of the dam 2 to open or close the water channel 3 of the dam 2. [

The height adjusting means includes an interlocking shaft 2420, an operating shaft 2430, and a rotating shaft 2440 that are rotated by the rotational power of the driving unit 2410.

The driving unit 2410 is installed in the tube gate installation space 1310 or the passageway 1220, though not necessarily limited thereto. But is not limited to, a drive unit 2410 is formed of a power unit that is operated by a motor or an engine or a power transmission unit that is manually operated by a handle.

The height adjusting means includes an interlocking sprocket 2450 and a drive sprocket 2460 that rotate in conjunction with rotation of the interlocking shaft 2420, the operation shaft 2430 and the rotation shaft 2440.

The height adjusting means is provided with a coupling body 2470 which is moved up and down by the rotation of the interlocking sprocket 2450 and the driving sprocket 2460.

5 to 7, the protection unit 3000 of the tube gate module 1 according to an embodiment of the present invention includes a connection portion 3100, a first protection portion 3200, a second protection portion 3300 , A first sliding portion 3400, and a second sliding portion 3500. [

The protection unit 3000 according to the present invention is formed in a structure in which the tube gate 2200 of the tube gate unit 2000 can be expanded and / or folded in conjunction with the rising and falling state of the tube gate 2200.

As shown in Figs. 1 to 2 and Figs. 6 to 7, the protection unit 3000 according to the present invention is generally horizontally developed to guide the tube sluice 2200 of the dam 2 to be opened , And the tubular water gate 2200 of the dam 2 can be closed by folding the tubular body 3100 so as to be symmetrical with respect to each other.

The connection portion 3100 protects the upper portion of the tube sluice unit 2000 and forms the basis of the protection unit 3000.

The first protector 3200 is coupled to one side of the connector 3100 by a hinge. The first protector 3200 protects the inner surface of the tube gate 2200, which is in direct contact with the water stored on one side of the tube gate unit 2000, that is, the inside of the dam 2.

The second protector 3300 is coupled to the other side of the connector 3100 by hinge coupling. The second protector 3200 protects the outer surface of the tube gate 2200 that is in contact with water that is discharged to the outside of the dam 2 through the other side of the tube gate unit 2000, do.

One end of the first sliding portion 3400 is connected to the lower end of the first protector 3200 by hinge coupling.

The other end of the first sliding portion 3400 is connected to the main plate portion 1400 so as to be slidable along the longitudinal direction of the main plate portion 1400 when the tube sluice 2200 ascends and descends.

One end of the second sliding part 3500 is connected to the lower end of the second protect part 3300 by hinge coupling.

The other end of the second sliding portion 3500 is connected to the first sliding portion 3400 on the other side of the main plate portion 1400 so as to be slidable along the longitudinal direction of the main plate portion 1400 when the tube sluice 2200 ascends / As shown in FIG.

The first protector 3200, the second protector 3300, the first sliding portion 3400 and the second sliding portion 3500 may be made of a reinforcing plastic or a steel alloy As shown in FIG.

The upper surface of the first protector 3200, the upper surface of the second protector 3300, the upper surface of the first sliding portion 3400, and the upper surface of the second sliding portion 3500 The ribs are formed on the upper surface.

As the ribs are formed on the respective surfaces of the protection unit 3000 in contact with water, when the tube gate is lowered and the water is discharged along the water channel of the dam, the water is rapidly discharged along the loblet , The stability of the dam can be increased as the load is distributed

5 to 7, the first sliding portion 3400 of the protection unit 3000 of the tube hydrological module 1 according to an embodiment of the present invention includes a first moving block portion 3410, An engaging plate portion 3420, and at least one first intermediate plate portion 3430.

The first movable block portion 3410 is installed to be slidable along the longitudinal direction of the main plate portion 1400 by a guide rail 1410 formed on the upper surface of the main plate portion 1400.

The first movable block portion 3410 is formed so that the tip end of the first movable block portion 3410 facing the inside of the dam 2 as a whole is inclined with respect to the base portion 1100 in a trapezoidal shape.

As the tip of the first moving block unit 3410 is formed to be inclined, the gravel deposited on the upper part of the base part 1100 can be removed to the outside of the base part 1100 when the first sliding part 3400 is moved.

The first moving block unit 3410 is disposed at the lowermost end of the first sliding unit 3400 and guides the position fixing to the inside of the base unit 1100. The first moving block unit 3410 includes a first moving block unit 3410, 1 middle plate portion 3430 to be slidable.

The first coupling plate portion 3420 is connected to the lower end of the first protector 3200 by hinge coupling.

The first coupling plate portion 3420 is disposed at the uppermost portion of the first sliding portion 3400 and is hinged to the lower end of the first protector 3200 to enable rotation of the first protector 3200.

The first intermediate plate portion 3430 is connected to at least one of the first movable plate portion 3410 and the first coupling plate portion 3420 so as to be movable along the longitudinal direction of the main plate portion 1400.

5 to 7, two first intermediate plate portions 3430 are provided. However, the present invention is not limited thereto. The first intermediate plate portions 3430 may be formed of at least one suitable number depending on the size of the dam or the need.

In other words, the number of tubes can be formed to be able to protect the tube gate in conjunction with the vertical movement of the tube gate unit according to the size of the dam and the height of the tube gate when the tube gate is expanded.

5 to 7, the second sliding portion 3500 of the protection unit 3000 of the tube hydrological module 1 according to an embodiment of the present invention includes a second moving block portion 3510, A second engaging plate portion 3520, and at least one second intermediate plate portion 3530.

The second moving block unit 3510 is installed to be slidable along the longitudinal direction of the main plate unit 1400 by a guide rail 1410 formed on an upper surface of the main plate unit 1400.

The second moving block unit 3510 is installed symmetrically with respect to the first moving block unit 3410 and the tube gate 2200.

That is, the second movable block portion 3510 is also formed in a trapezoidal shape as a whole, and the tip of the second movable block portion 3510 toward the outside of the dam 2 is formed to be inclined with respect to the base portion 1100.

Since the tip of the second moving block 3510 is inclined, the gravel accumulated on the base 1100 can be removed to the outside of the base 1100 when the second sliding part 3500 is moved.

The second moving block unit 3510 is provided at the lowermost end of the second sliding unit 3500 and guides the position fixing to the outside of the base unit 1100. The second moving block unit 3510 includes a second moving block unit 3510, 2 middle plate portion 3530 to be slidable.

The second coupling plate portion 3520 is connected to the lower end of the second protector 3300 by hinge coupling.

The second coupling plate portion 3520 is disposed at the uppermost portion of the second sliding portion 3500 and is hinged to the lower end of the second protector 3300 to enable rotation of the second protector 3300.

The second intermediate plate portion 3530 is connected to at least one of the second movable plate portion 3510 and the second coupling plate portion 3520 so as to be movable along the longitudinal direction of the main plate portion 1400.

5 to 7, two second intermediate plate portions 3530 are provided. However, the second intermediate plate portions 3530 are not limited thereto, and may be formed of at least one suitable number depending on the size of the dam and the need.

In other words, the number of the tubes is the same as the number of the first intermediate plate portions 3430 as the number of the tube gate doors is protected by interlocking with the elevating and lowering of the tube gate unit according to the size of the dam and the height when the tube gate is expanded .

5 to 7, the first intermediate plate portion 3430 of the first sliding portion 3400 of the protection unit 3000 of the tube hydrological module 1 according to the embodiment of the present invention includes the first And the second intermediate plate portion 3530 of the second sliding portion 3500 is installed on the upper portion of the second engaging plate portion 3520.

Since the first intermediate plate portion 3430 and the second intermediate plate portion 3530 are stacked on the first and second coupling plate portions 3420 and 3520, The first intermediate plate portion 3430 and the second intermediate plate portion 3530 can be slid along the forming direction without being separated and the distance between the first intermediate plate portion 3430 and the second intermediate plate portion 3530 can be limited .

5, the first intermediate plate portion 3430 includes a first guide ring 3432, which is elongated on the side surface, and a first guide wheel 3432 mounted on the side portion through a first support 3433, 3434).

The first intermediate plate portion 3430 may include a first guide ring 3432 and a first support 3433 and a first wheel 3434 at both side portions of the first intermediate plate portion 3430 .

5, the first wheel 3434 is mounted on the side of the first intermediate plate portion 3430 through a first support 3433, the first wheel of which is vertically adjacent to the other first intermediate Can be inserted into the first guide ring of the plate portion and can slide along the guide ring.

In order to prevent contact between the first support member and the first guide ring in advance, the first support member may be formed in a L-shape.

5, according to an embodiment of the present invention, the second intermediate plate portion 3530 includes a second guide ring 3532, which is elongated on the side portion, and a second support 3533 And a second wheel 3534 mounted through the second wheel 3534.

The second intermediate plate portion 3530 may include a second guide ring 3532, a second support 3533 and a second wheel 3534 at both side portions of the second intermediate plate portion 3530 .

5, the second wheel 3534 is mounted on the side portion of the second intermediate plate portion 3530 through the second support 3533, which is in the form of a second intermediate And can be inserted into the second guide ring of the plate portion and can slide along the guide ring.

In order to prevent contact between the second support member and the second guide ring in advance, the second support member may be formed in a stepped shape.

Although not shown in the drawings, the first intermediate plate portion 3430 and the second intermediate plate portion 3530 may have a plurality of nozzles on their respective front surfaces.

The nozzle ejects high-pressure air toward the front of the first intermediate plate portion 3430 and the second intermediate plate portion 3530 through a supply source such as a compressor.

Accordingly, as the sediments enclosed in the first intermediate plate portion 3430 and the second intermediate plate portion 3530 are removed through the high-pressure air, the first intermediate plate portion 3430 and the second intermediate plate portion 3530 Smooth movement can be achieved and breakdown can be prevented in advance.

7, the first intermediate plate portion 3430 and the second intermediate plate portion 3530 are provided with a first sealing member 3431 and a second sealing member 3531 at the front end and the rear end lower portion, respectively, do.

As described above, since the first sealing member 3431 and the second sealing member 3531 made of elastic material are provided at the front and rear ends of the first intermediate plate portion 3430 and the second intermediate plate portion 3530, respectively, It is possible to minimize the inflow of foreign matter into the inner spaces of the first intermediate plate portion 3430 and the second intermediate plate portion 3530. [

The first intermediate plate 3430 and the second intermediate plate 3530 are slidably moved by the first sealing member 3431 and the second sealing member 3531 so that the first intermediate plate 3430, 2 foreign materials introduced into the inner space of the intermediate plate portion 3530 are naturally removed to prevent the first sliding portion 3400 and the second sliding portion 3500 from being damaged or damaged.

Accordingly, the life of the protection unit 3000 can be increased, and the maintenance cost of the tube sluice module 1 can be finally reduced.

As shown in FIG. 8, the first protector 3200 of the protection unit 3000 of the tube gate module 1 according to an embodiment of the present invention is formed in a flat plate shape as a whole.

The first protector 3200 includes at least one first rib 3210 formed in a horizontal direction on an upper surface thereof.

The first rib 3210 has hollow portions on both sides thereof, and a first arm 3220 capable of advancing or retracting is inserted into the hollow portion.

The first arm 3220 is inserted into the first armrest formed on the water channel side of the dam to guide the position fixing of the protection unit.

Further, the first rib 3210 may be provided with a turbine if necessary, so that power generation can be achieved in accordance with the flow of water.

9, the second protection portion 3300 of the protection unit 3000 of the tube hydrological module 1 according to an embodiment of the present invention is formed in a generally flat plate shape.

The second protector 3300 includes one or more second ribs 3310 formed on the upper surface in a horizontal direction.

The second rib 3310 is formed with hollow portions on both sides thereof, and a second arm 3320 capable of advancing or retracting is inserted into the hollow portion.

The second arm 3320 is inserted into the second armrest formed on the water channel side of the dam to guide the position fixing of the protection unit.

The second protector 3300 includes a through hole 3330 penetrating the second rib 3310 in the direction of the top surface of the second rib 3310 and the turbine 3340 is inserted into the through hole 3330.

The turbine 3340 passes through the connection portion 3100 of the protection unit 3000 and converts the kinetic energy of the water flowing along the upper surface of the second protection portion 3300 into rotary motion to enable power generation.

The electricity generated by the rotation of the turbine 3340 can be supplied to an area where power supply is not smooth in the vicinity of the installation area of the dam and can be reused as a driving power for driving the drive part 2410, can do.

The present invention is not limited to the modifications shown in the drawings and the embodiments described above, but may be extended to other embodiments falling within the scope of the appended claims.

1: Tube hydrologic module, 2: Dam,
3: water channel, 1000: base unit,
1100: base portion, 1200: column portion,
1210: entrance, 1220: passage,
1300: receptacle part, 1310: tubing room installation space part,
1320: work space part, 1400: main plate part,
1410: guide rail, 2000: tube gate unit,
2100: support part, 2200: tube gate,
2300: air supply unit, 3000: protection unit,
3100: connection part, 3200: first protection part,
3300: second protect portion, 3400: first sliding portion,
3410: first moving block part, 3420: first engaging plate part,
3430: first intermediate plate portion, 3431: first sealing member,
3500: second sliding portion, 3510: second moving block portion,
3520: second engaging plate portion, 3530: second intermediate plate portion.
3531: Second sealing member.

Claims (10)

A base unit (1000) installed on the waterway (3) of the dam (2);
A tube gate unit 2000 installed on the base unit 1000 to move up and down to flow extra water when the quantity of the dam 2 becomes a predetermined amount or more; And
(3000) installed in the base unit (1000) so as to surround the tube gate unit (2000) to protect the tube gate unit (2000) moving up and down,
The base unit (1000)
A base 1100 installed at the bottom of the waterway 3 of the dam 2 in the same direction as the waterway 3;
A column portion 1200 formed on the upper portion of the base portion 1100 so as to face each other at both sides of the base portion 1100 along the height direction of the tube gate unit; And
And a receiving portion 1300 formed inside the base portion 1100 to receive the tube sluice unit 2000,
The receiving portion 1300 includes:
A tube gate installation space 1310 formed in the base part 1100 in a height direction of the base part 1100 so that the tube gate 2000 can be raised and lowered; And
A driving part for moving up and down the tube sluice 2200 is installed in the base part 1100 so as to be perpendicular to the tube sidewall installation space part 1310 in order to form a working space, And a work space 1320 formed with a plurality of workpieces,
The base unit 1000 includes a penetration portion corresponding to the tube gate installation space portion 1310 of the accommodation portion 1300 and extends in the longitudinal direction of the base portion 1100 between the column portions 1200. [ And a main plate portion (1400) installed on an upper surface of the base portion (1100).
delete delete delete The method according to claim 1,
The column section 1200 includes:
An entrance 1210 formed on the top or side of the column part 1200; And
And a passage part (1220) formed in the tube part (1200) so as to communicate with the tube hydrangea setting space part (1310) and the work space part (1320).
6. The method of claim 5,
The tube gate unit 2000 includes:
A support portion 2100 which is adjacent to the inside of the column portion 1200 and is parallel to the column portion 1200 and has one end fixed to the upper surface of the tube sluice room installation space 1310;
The tube gate 2200 is connected to the support portion 2100 and opens and closes the water channel 3 of the dam 2 while being compressed or expanded in the height direction of the column portion 1200 along the support portion 2100. [ ; And
And an air supply part (2300) installed in the column part (1200) for supplying or recovering compressed air to the tube gate (2200) through a supply pipe.
The method according to claim 6,
The protection unit (3000)
A connection portion 3100 for protecting the upper portion of the tube gate unit 2000;
A first protection part 3200 coupled to one side of the connection part 3100 by hinge connection to protect one side of the tube gate unit 2000;
A second protector 3300 hinged to the other side of the connection part 3100 to protect the other side of the tube gate unit 2000;
The other end of the main protector 3200 is hinged to the lower end of the first protector 3200 and slidable along the longitudinal direction of the main plate 1400 when the tube gate 2200 ascends / A first sliding portion 3400 connected to the plate portion 1400; And
And the other end is connected to the lower end of the second protector 3300 by a hinge connection so that the tube can be slidably moved along the longitudinal direction of the main plate portion 1400 when the tube gate 2200 ascends and descends. And a second sliding part (3500) connected to the plate part (1400).
8. The method of claim 7,
An upper surface of the first protector 3200, an upper surface of the second protector 3300, an upper surface of the first sliding portion 3400, and an upper surface of the second sliding portion 3400. [ And riblets are formed on the upper surface of the part (3500). 9. The method of claim 8,
The first sliding portion 3400 includes:
A first moving block portion 3410 installed to be slidable along the longitudinal direction of the main plate portion 1400 by a guide rail 1410 formed on an upper surface of the main plate portion 1400;
A first engaging plate portion 3420 connected to the lower end of the first protector 3200 by a hinge; And
At least one first intermediate plate portion 3430 connected between the first moving block portion 3410 and the first engaging plate portion 3420 so as to be movable along the longitudinal direction of the main plate portion 1400; Including,
The second sliding portion 3500 includes:
A second moving block portion 3510 installed to be slidable along the longitudinal direction of the main plate portion 1400 by a guide rail 1410 formed on an upper surface of the main plate portion 1400;
A second engaging plate portion 3520 connected to the lower end of the second protector 3300 by hinge coupling; And
At least one second intermediate plate portion 3530 connected between the second moving block portion 3510 and the second engaging plate portion 3520 so as to be movable along the longitudinal direction of the main plate portion 1400; Wherein the tube module comprises a tubular watertight module. 10. The method of claim 9,
The first intermediate plate portion 3430 is installed on the upper portion of the first coupling plate portion 3420,
And the second intermediate plate portion (3530) is installed on the upper portion of the second coupling plate portion (3520).

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