KR20200120027A - Water quality improvement type dam - Google Patents

Abstract

Disclosed is a water quality improvement type weir. The water quality improvement type weir of the present invention includes: a first inclined part installed in a transverse direction across a river and installed to be inclined upward toward a downstream floor on an upstream floor; a second inclined part continuously installed on the first inclined part and installed to be inclined downward toward the downstream floor; a plate-shaped floor foundation part which is positioned on lower sides of the first inclined part and the second inclined part and of which one side is installed in a position facing the upstream floor and the other side is installed in a position facing the downstream floor; and a support part extended from both sides of the first inclined part to the lower side to be fixed to the river floor. Therefore, the water quality improvement type weir can store water with an improved water quality.

Description

Water quality improvement type beam {WATER QUALITY IMPROVEMENT TYPE DAM}

The present invention relates to a water quality improvement type beam, and more particularly, to a water quality improvement type beam capable of storing water having improved water quality since pollutants such as foreign matter easily flow downstream.

In general, a beam is a structure built across a river to attract or raise the water level.

Beams are made by blocking some or all of the streams to raise the water level and to secure the required amount of water, and these beams are usually called blown beams. Most of the traditional traditional beams in Korea are piled horizontally at appropriate intervals in rivers, and long logs are placed across the pool of water. In addition, it is a structure that raises the depth of water while leaning against the logs, placing stones and covering them with soil to allow water to flow.

In recent years, beams are made of concrete structures, and since the upstream side of the beam is installed in a vertical direction, contaminants including foreign substances accumulate on the lower side of the freshwater on the upstream side of the beam, causing it to rot, causing water pollution. Therefore, there is a need to improve this.

The background technology of the present invention is published in Korean Patent Application Publication No. 2018-0135293 (published on Dec. 20, 2018, title of invention: a water quality improvement device of a river with a beam bypass structure and a water quality improvement structure of a river using the same).

The present invention was created to improve the above problems, and an object of the present invention is to provide a water quality improvement beam capable of storing water having improved water quality since pollutants such as foreign matter easily flow downstream.

The water quality improvement type beam according to the present invention: a first inclined part installed in a transverse direction across a river and installed in an upward inclination from an upstream floor to a downstream, and a first inclined part successively installed in the first inclined part and installed in a downward inclination toward the downstream The second slope and the first slope and the second slope are located below, and one side is installed at a position facing the upstream floor, and the other side is a plate-shaped bottom base and first installed at a position facing the downstream floor. It characterized in that it includes a support portion that extends downward from both sides of the slope and is fixed to the river floor.

In addition, the present invention further includes a sluice gate that penetrates the first slope and the second slope and is installed in a shape to block the discharge passageway and the discharge passageway connecting the upstream and downstream floors, and to control the flow of water by the moving operation. Characterized in that.

In addition, the first inclined portion is characterized in that it comprises an outer member having a set thickness and installed inclined upward from the upstream floor toward the downstream, and an inner member installed between the outer member and the bottom base portion and supporting the lower side of the outer member.

In addition, the support part extends downward from the end of the outer member facing the upstream floor and is fixed vertically to the river floor, and the first fixing wall extends from the upper side to the lower side of the outer member facing the second slope. It characterized in that it comprises a second fixing wall fixed vertically, and a fixing base portion extending in the horizontal direction from the lower side of the second fixing wall.

In addition, the present invention is characterized in that it further comprises a reinforcing portion protruding outward of the second fixing wall and positioned inside the second inclined portion, and a reinforcing base portion extending downward of the reinforcing portion and fixed to the river floor.

In addition, the first slope and the second slope are inclined based on the base of the floor, and the installed angle is the same.

In addition, it is located below the outer member, characterized in that it further comprises a fluid injection unit for transporting foreign substances along the outer member by spraying the fluid in a direction inclined upward along the inclined surface of the outer member.

Since the water quality improvement type beam according to the present invention gradually increases from the upstream floor toward the downstream and forms a slope, contaminants such as foreign substances contained in the freshwater can easily move downstream, the first Water with improved water quality can be stored upstream of the slope.

1 is a side view schematically showing the structure of a water quality improvement beam according to an embodiment of the present invention.
2 is a side view showing a state in which water flows upward of a water quality improvement type beam according to an embodiment of the present invention.
3 is a plan view showing a state in which a sluice gate is installed in a water quality improvement beam according to an embodiment of the present invention.
4 is a perspective view showing a state in which a sluice gate is installed in a water quality improvement beam according to an embodiment of the present invention.
5 is a side view showing a state in which a fluid injection unit is installed under a first inclined unit according to an embodiment of the present invention.

Hereinafter, a water quality improvement type beam according to an embodiment of the present invention will be described with reference to the accompanying drawings. In this process, the thickness of the lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of description.

In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of users or operators. Therefore, definitions of these terms should be made based on the contents throughout the present specification.

1 is a side view schematically showing the structure of a water quality improvement type beam according to an embodiment of the present invention, and FIG. 2 is a view showing a state in which water flows upward of the water quality improvement type beam according to an embodiment of the present invention. It is a side view, and FIG. 3 is a plan view showing a state in which a sluice gate is installed in a water quality improved beam according to an embodiment of the present invention, and FIG. 4 is a state in which a sluice gate is installed in a water quality improved beam according to an embodiment of the present invention. 5 is a side view showing a state in which a fluid injection unit is installed under a first inclined unit according to an embodiment of the present invention.

As shown in Figures 1 to 4, the water quality improvement type beam 1 according to an embodiment of the present invention is installed in a transverse direction (W) across the river 10 and downstream from the upstream floor 22 A first inclined portion 40 that is installed inclined upward toward 35, a second inclined portion 50 that is continuously installed to the first inclined portion 40 and installed inclined downward toward the downstream floor 24, and It is located at the lower side of the 1st inclined part 40 and the 2nd inclined part 50, and one side is installed in the position facing the upstream floor 22, and the other side is plate-shaped installed in the position facing the downstream floor 24. It includes a support portion 70 that extends downward from both sides of the bottom base portion 60 and the first inclined portion 40 and is fixed to the river bottom 20.

In addition, the water quality improvement beam 1 according to an embodiment of the present invention includes a discharge passage part 80, a sluice gate 82, a reinforcement part 90, a reinforcement base part 92, and a fluid injection part 100. Include. The water quality improvement type beam 1 installed along the transverse direction W of the river 10 is installed in contact with the upstream bottom 22 and the downstream bottom 24.

The river bottom 20 is divided into an upstream bottom 22 and a downstream bottom 24 around the water quality improvement beam 1. The upstream bottom 22 is located on the upstream 30 side of the water quality improved beam 1, and the downstream bottom 24 is located on the downstream 35 side of the water quality improved beam 1.

The first inclined portion 40 is installed in a transverse direction (W) across the river 10, and can be transformed into various shapes within the technical idea that it is installed inclined upward from the upstream floor 22 to the downstream 35 . The first inclined portion 40 according to an embodiment includes an outer member 42 and an inner member 44.

The outer member 42 has a set thickness and has a plate shape that is installed inclined upward from the upstream floor 22 toward the downstream 35. Reinforcing bars are installed inside the outer member 42 to increase structural rigidity.

The outer member 42 is a concrete structure, has a thickness of about 10 cm and may be installed inclined. It goes without saying that the thickness of the outer member 42 can be increased or decreased depending on the installation environment. The lower side of the outer member 42 is installed at a position facing the upstream floor 22, and the upper side of the outer member 42 is in contact with the second inclined portion 50 and is installed in a state submerged in the river 10.

The inner member 44 is installed between the outer member 42 and the bottom base portion 60, and can be transformed into various shapes within the technical idea of supporting the lower side of the outer member 42. The inner member 44 according to an embodiment is soil such as soil or mixed soil, and a member for structural rigidity including gravel may be added as needed.

With the installation of the first inclined portion 40, since the natural soil formation process of the conventional vertical beam can be intentionally formed, the freshwater capacity can be increased, foreign matter insolubilization is eliminated, and water pollution can be prevented.

The second inclined portion 50 is installed on the downstream side 35 in succession to the first inclined portion 40, and can be transformed into various shapes within the technical idea of being installed inclined downward toward the downstream floor 24. The second inclined part 50 according to an embodiment is made of soil.

In addition, the first inclined portion 40 and the second inclined portion 50 are inclined with respect to the floor base portion 60, and the installed angles are the same. Accordingly, contaminants including foreign matters that are moved along the upwardly inclined first inclined portion 40 are moved to an upper side of the second inclined portion 50 through the upper side of the first inclined portion 40. Then, it moves in a downwardly inclined direction along the second inclined part 50 and moves to the downstream 35.

After planting willows on the upper side of the second inclined portion 50, if the stem or branch is cut annually, only the willow roots are formed in the second inclined portion 50, thereby enhancing the structural rigidity of the second inclined portion 50. I can. These first inclined portion 40 and second inclined portion 50 extend in the width direction of the river 10.

The plate-shaped bottom base portion 60 is located under the first inclined portion 40 and the second inclined portion 50, and one side of the bottom base portion 60 is in a position facing the upstream floor 22. It is installed, and the other side of the floor base part 60 can be transformed into various shapes within the technical idea of being installed at a position facing the downstream floor 24. The floor base part 60 according to an embodiment is a large concrete structure, starting from the upstream floor 22 facing the first slope 40 and the downstream floor 24 facing the second slope 50 It is a concrete structure that extends to.

The first inclined portion 40, which is greatly affected by the water flowing through the river 10, is formed of a concrete structure, but the second inclined portion 50 receiving less force than the first inclined portion 40 is soil or soil. Consists of

The support 70 extends downward from both sides of the first inclined portion 40 and can be transformed into various shapes within the technical idea of being fixed to the river bottom 20. The support part 70 according to an embodiment includes a first fixing wall 72 extending downward from an end of the outer member 42 facing the upstream floor 22 and fixed vertically to the river floor 20, A second fixing wall 74 extending from the upper side to the lower side of the outer member 42 facing the second inclined portion 50 and fixed vertically to the river floor 20, and the lower side of the second fixing wall 74 It includes a fixed base portion 76 extending in the horizontal direction.

The first fixing wall 72 extends downward from the lower end of the first inclined portion 40 and is installed in a vertical direction under the upstream floor 22. The second fixing wall 74 also extends downward from the top of the first slope 40 and is installed in a vertical direction below the river floor 20.

The first fixing wall 72 and the second fixing wall 74 are made of the same concrete structure as the first inclined portion 40, and a reinforcing bar is disposed inside to enhance structural rigidity. In addition, the fixed base portion 76 extends in a horizontal direction from the lower side of the river floor 20, and the lower side of the second fixed wall 74 is connected to the second fixed wall 74 and the first inclined portion 40. It can strengthen structural rigidity.

The water quality improvement type beam 1 may further include a discharge passage part 80 and a sluice gate 82 for discharging fresh water. The discharge passage portion 80 passes through the first inclined portion 40 and the second inclined portion 50 and forms a passage connecting the upstream bottom 22 and the downstream bottom 24.

A discharge passage portion 80 having a flat surface is formed on the first slope portion 40 and the second slope portion 50, respectively, and a sluice gate 82 is installed in a shape to block the discharge passage portion 80. It is possible to control the flow of water moving along the discharge passage 80 by the operation of the sluice door 82.

The sluice gate 82 may be moved in a vertical direction, and various modifications may be implemented, such as being able to lie down and then erect. The configuration related to the movement of the sluice gate 82 is a known technique that is obvious to a person skilled in the art, so a detailed description thereof will be omitted.

The number of sluice gates 82 may be determined according to the length of the river 10 in the transverse direction (W), which is the length of the water quality improved beam 1. The width of the sluice gate 82 is also determined in consideration of the width of the water quality improvement type beam 1, the width of the river 10, and the environment of use.

The height of the sluice gate 82 may be the same as the height of the water quality improvement beam 1. In addition, the sluice gate 82 may be installed in a vertical direction, and various modifications may be performed, such as the sluice gate 82 may be installed in an inclined direction like the first slope.

In addition, the water quality improvement type beam 1 is protruding outward from the second fixing wall 74 and extending to the lower side of the reinforcing portion 90 and the reinforcing portion 90 positioned inside the second inclined portion 50. It further includes a reinforcement base portion 92 fixed to the river bottom 20.

If the height of the water quality improving beam 1 is high, the installation of the reinforcing part 90 and the reinforcing base part 92 for reinforcing structural rigidity is essential. The length of the reinforcing part 90 in the transverse direction (W) increases or decreases in proportion to the height of the water quality improvement beam 1.

In addition, the water quality improvement type beam 1 according to an embodiment is located under the outer member 42, and sprays the fluid in an upwardly inclined direction along the inclined surface of the outer member 42 to prevent the outer member 42. Accordingly, it further includes a fluid injection unit 100 for transporting foreign substances.

The fluid injection unit 100 according to an embodiment is installed on the upstream floor 22 facing the lower side of the first inclined portion 40 and sprays air in an upward inclined direction along the first inclined portion 40 do. Accordingly, the foreign matter in the water of the river 10 moves upwardly inclined along the water flow formed by the fluid spraying unit 100 and then moves to the downstream 35 through the second inclined unit 50.

Hereinafter, the operation state of the water quality improvement beam 1 according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

When looking at the bottom of the river 10 freshwatered by the water quality improvement beam 1, it forms a shape of a natural circulation beam in which the bottom gradually rises from the depth of the freshwater toward the downstream (35).

The water moving from the upstream 30 to the downstream 35 is stored at a certain depth by the water quality improving beam 1. At this time, foreign substances and contaminants in the water are moved upwardly inclined along the first inclined portion 40 and then fall down inclined downwardly along the second inclined portion 50 and then flow to the downstream 35.

And, if necessary, the fluid injection unit 100 is operated to inject high-pressure air to the first inclined portion 40, so that foreign matter and contaminants in the water follow the first inclined portion 40 and the second inclined portion 50 ) Can be moved to more easily. In addition, since the contact area between air bubbles and pollutants increases, the pollutants are easily removed. Therefore, the water quality of freshwater is improved by the water quality improvement type beam (1).

As described above, according to the present invention, contaminants such as foreign matter contained in freshwater by the first slope 40 gradually increasing from the upstream bottom 22 toward the downstream 35 and forming a slope are downstream Since it can be easily moved to 35, water with improved water quality can be stored in the upstream 30 of the first inclined portion 40. In addition, the higher the height of the water quality improvement beam (1), the less polluted the freshwater quality is, and the construction cost can be reduced compared to the existing construction. In addition, since the water quality improvement beam 1 according to the present invention is circulating in nature and is not loaded in a state where foreign matter and muddy water are mixed in a fresh water, water pollution due to insolubilization is reduced.

The present invention has been described with reference to the embodiments shown in the drawings, but these are only exemplary, and those of ordinary skill in the art will understand that various modifications and equivalent other embodiments are possible therefrom. will be. Therefore, the true technical protection scope of the present invention should be determined by the following claims.

1: water quality improvement type beam 10: river
20: river bottom 22: upstream bottom
24: downstream bottom 30: upstream
35: downstream 40: first slope
42: outer member 44: inner member
50: second inclined portion 60: bottom base portion
70: support 72: first fixing wall
74: second fixing wall 76: fixing base portion
80: discharge passage 82: sluice
90: reinforcement part 92: reinforcement base part
100: fluid injection part W: transverse direction

Claims (7)

A first inclined part installed in a transverse direction across the river and installed in an upward inclined direction from an upstream bottom to a downstream side;
A second inclined portion which is continuously installed on the first inclined portion and is installed to be inclined downward toward the downstream floor;
A plate-shaped bottom base portion disposed below the first and second inclined portions, one side installed at a position facing the upstream floor and the other side installed at a position facing the downstream floor; And
And a support portion extending downward from both sides of the first inclined portion and fixed to the bottom of the river.
The method of claim 1,
A discharge passage part penetrating the first inclined part and the second inclined part and connecting the upstream floor and the downstream floor; And
A sluice gate installed in a shape blocking the discharge passage and controlling the flow of water by a moving operation; water quality improvement type beam, characterized in that it further comprises.
The method of claim 2, wherein the first slope,
An outer member having a set thickness and installed to be inclined upward from the upstream floor toward the downstream; And
And an inner member installed between the outer member and the bottom base portion and supporting a lower side of the outer member.
The method of claim 3, wherein the support,
A first fixing wall extending downward from the end of the outer member facing the upstream floor and fixed vertically to the river floor;
A second fixing wall extending from an upper side to a lower side of the outer member facing the second inclined part and fixed vertically to the river floor;
And a fixed base portion extending in a horizontal direction from a lower side of the second fixing wall.
The method of claim 4,
A reinforcing portion protruding outward from the second fixing wall and positioned inside the second inclined portion; And
A water quality improvement type beam, characterized in that it further comprises a; reinforcement base portion extended to the lower side of the reinforcement portion and fixed to the river floor.
The method of claim 5,
The water quality improvement type beam, characterized in that the first slope and the second slope are inclined and installed at the same angle based on the base of the floor.
The method of claim 5,
A fluid spraying unit positioned under the outer member and inclined upwardly along the inclined surface of the outer member to transfer foreign matters along the outer member; .

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