KR101473922B1 - Eco-friendly fish way block structure and construction method thereof - Google Patents

Abstract

The present invention relates to an airblock block provided on the downstream side of a beam (A) and having an upper surface sloped downward toward the downstream side, wherein a plurality of water reservoirs (20) storing water on the upper surface of the airblock (B) And a fish which is formed so as to be spaced apart from the upper surface of the block B and can move back up along the upper surface of the block B can take a rest in the lower portion 20, Block.
The fishbone block according to the present invention has a plurality of reservoir portions 20 formed on the upper surface thereof so that the fish that have moved upstream along the upper surface of the block B can be moved up and down the respective reservoir portions 20 step by step However, since it is possible to take a break in the inside of the water reservoir 20, there is an advantage that a small fish can easily ascend upstream from the block B without any difficulty.

Description

TECHNICAL FIELD [0001] The present invention relates to an ECO-FRIENDLY FISH WAY BLOCK STRUCTURE AND CONSTRUCTION METHOD THEREOF,

The present invention relates to an eco-friendly waterproof block structure and a method of constructing the eco-friendly waterproof structure, which enable a small fish to easily move upstream.

Generally, as shown in Fig. 1, the water installed in the river is adjusted to flood control by storing water at the upper part of the location where the beam (A) is installed, and at the same time, .

However, these beams (A) obstruct the rivers, so that the fishes in the rivers can not go up and down the river. Therefore, there was a problem that the ecosystem of the river was disconnected and the environmental ecosystem was disturbed.

In order to solve such a problem, the fishbone A is provided with a conventional fishbone block B which allows the fish to ascend from the fishbone A. However, such a conventional waterproofing block B is made of a concrete material, and its upper surface is configured to be inclined downward to the downstream side of the river, so that the water stored in the waterproofing material A flows downward along the upper surface. Therefore, the fish can move up the water flowing along the upper surface of the block B to the upstream of the river.

However, since the upper surface of the block B becomes a relatively steep slope, the water flows at a higher rate than the flow rate of a general steel. Therefore, there is a problem that it is very difficult for a fish or a young fish having a small size to ascend along the upper surface of the block B to the upstream of the river.

Therefore, there is a growing need for eco-friendly blocks that can solve these problems.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an eco-friendly waterproofing block and a method of constructing the eco-friendly waterproofing structure.

According to an aspect of the present invention, there is provided an airblock block provided on a downstream side of a beam (A) and having an upper surface inclined downward toward the downstream side, wherein a plurality of bottom portions 20 are spaced apart from each other in the upstream and downstream directions so that the fish which move up along the upper surface of the block B can take a rest in the water reservoir 20. [

According to another aspect of the present invention, the upstream side surface and the downstream side surface of the reservoir portion 20 are inclined toward the upstream side and the downstream side, respectively, and a plurality of vortexes Wherein the projections (21) are formed so as to protrude so as to be laterally spaced apart from each other.

According to another aspect of the present invention, a flow path 30 through which water flows upstream of the beam A is formed in the interior of the artificial block B, So that water upstream of the beam A is supplied to the inside of each of the reservoir portions 20 through the flow path 30.

According to another aspect of the present invention, the flow path 30 is formed by embedding a pipe 31 inside the block B, and an upper end of the pipe 31 is inserted through the beam A And a branch tube 31a connected to the lower side of the reservoir 20 is provided at an intermediate portion of the pipe 31. The lower end of the pipe 31 is connected to a block B And a diaphragm 22 having a plurality of the through holes 22a formed therein is provided in the bottom of the bottom portion 20. In this case,

According to another aspect of the present invention, the upper end of the artificial block (B) corresponds to the lower end of the drainage section (10) formed concavely at the upper end of the beam (A) And the inlet port 31c is formed to be positioned below the drainage section 10. [0034] FIG. According to still another aspect of the present invention, there is provided a waterproofing block characterized in that charcoal powder is mixed in the waterproofing block (B).

According to the present invention, there is provided a method of constructing an eco-friendly waterproof block structure, comprising the steps of: disposing a ground on the downstream side of the beam (A); forming a predetermined angle in the direction from the upstream side to the downstream side The branch pipe 31 is connected to the lower end of the reservoir 20 formed in the block B so as to be connected to the branch pipe 31a at a predetermined interval. (31b) at the lower end of the pipe so that water is drained to the downstream side. When the piping (31) forming the channel (30) is completed, the piping (B) is placed on the upper part of the foundation concrete step so as to be inclined to the downstream side from the upstream side so as to expose the upper part of the reservoir part (20) to the outside, And a step of fixing the base concrete and the artificial block (B) by applying finishing concrete so that the artificial block (B) arranged in the stepwise shape is not collapsed by the flow velocity, / RTI >

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. Like reference numerals are used for like elements in describing each drawing.

The terms used in the present application are used merely to illustrate specific embodiments and are not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the term "comprises" or "having ", etc. is intended to specify the presence of stated features, integers, steps, operations, elements, parts, or combinations thereof, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

The fishbone block according to the present invention has a plurality of reservoir portions 20 formed on the upper surface thereof so that the fish that have moved upstream along the upper surface of the block B can be moved up and down the respective reservoir portions 20 step by step However, since it is possible to take a break in the inside of the water reservoir 20, there is an advantage that a small fish can easily ascend upstream from the block B without any difficulty.

1 is a block diagram illustrating a general block diagram;
Fig. 2 is a cross-sectional side view showing the island block according to the present invention. Fig.
3 is an enlarged view showing a main portion of an eudo block according to the present invention.
4 and 5 are views for explaining the operation of the eudo block according to the present invention.

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

2 and 3 illustrate a fishing line block according to the present invention. The fishing line is provided on the downstream side of the beam A and has an upper surface inclined downward to the downstream side, It is the same as in the prior art that the flowing water can be backflowed to the upstream of the beam (A). At this time, the island block (B) is made of a concrete material.

The upper portion of the beam A is formed with a drain portion 10 through which water is drained and the upper portion of the block A is formed so as to correspond to a lower end of the drain portion 10 , The water stored in the beam (A) is supplied to the upper surface of the block (B) through the drainage section (10).

According to the present invention, the upper surface of the island block (B) is formed with a plurality of water storage portions (20) for storing water and spaced apart from each other in the upstream and downstream directions, and a fish And is configured to be able to take a break in the storage unit 20.

To be more specific, the upstream side surface and the downstream side surface of the reservoir portion 20 are inclined toward the upstream and downstream sides, respectively. Each reservoir portion 20 is formed in a reverse rhombic shape And a plurality of protrusions 21, which form a vortex, protrude from the upstream end of the water storage portion 20 so as to be spaced apart from each other.

A flow path 30 through which water flows upstream of the beam A is formed in the inner side of the block A and the flow path 30 is connected to the inside of each of the bottom portions 20, ) Is supplied to the inside of each reservoir 20 through the flow path 30.

To this end, the flow path 30 is formed by embedding the pipe 31 in the block B. The pipe 31 is formed of a circular pipe and has an upper end extending to the upstream side of the beam A through the beam A and a branch pipe 20 connected to the lower side of the lower portion 20 31a.

The area of the inlet 31c formed at the upper end of the pipe 31 is much smaller than the area of the drainage unit 10 formed in the beam A so that water discharged through the drainage unit 10 And the inlet 31c of the pipe 31 is positioned below the drainage unit 10 so that the water is supplied to the drainage unit 20 through the pipe 31. [ do.

The lower end of the pipe 31 extends toward the downstream side of the block B and a drain port 31b is formed at the end of the pipe 31 to open downstream. The drain port 31b of the pipe 31 is smaller in diameter than the inlet port 31c of the pipe 31 so that most of the water flowing into the pipe 31 is supplied to the inlet through the branch pipe 31a , And only a very small amount of water is discharged to the downstream side through the drain hole 31b.

In addition, a partition plate 22 having a plurality of through holes 22a passing through the upper and lower surfaces is provided in the bottom of the storage unit 20. [ The diaphragm 22 is spaced upward from the bottom surface of the water reservoir 20 so that the water supplied into the reservoir 20 through the branch pipe 31a is spread on the lower side of the diaphragm 22 And is then supplied to the upper side of the reservoir portion 20 through the through hole 22a.

2, when water is filled in the beam A, water flows to the upper surface of the block B through the drainage section 10, and at the same time, The water is supplied to the inside of the water storage portion 20 through the water supply portion.

4, when the water level upstream of the beam A is positioned between the lower side of the drainage section 10 and the inlet port 31c of the pipe 31, the drainage section 10 The flow of water supplied to the upper surface of the block B is stopped and water upstream of the beam A is supplied to the reservoir 20 through the pipe 31. [

5, when the water upstream of the beam A is lower than the upper end of the pipe 31, the upper portion of the block B and the lower portion 20 of the pipe 31 are connected to each other through the pipe 31, The water flowing into the water storage portion 20 flows backward through the through hole 22a and the branch pipe 31a and is drained to the downstream side through the lower end of the pipe 31, Do not leave any water inside. The mortar and the charcoal powder are mixed in the concrete constituting the above-mentioned block (B).

In the block B constructed as described above, a plurality of water storage portions 20 are formed on the upper surface so that the fish that have moved upstream along the upper surface of the block B can move up the water storage portions 20 step by step In addition, since it is possible to take a break in the inside of the water reservoir 20, it is advantageous that the small fish can easily ascend upstream of the block B as well.

Particularly, the reservoir 20 is formed in an inverted rhomboid shape that widens in the fore and aft direction as it goes upward. A plurality of protrusions 21 forming a vortex are formed on the upstream side of the reservoir 20, And is formed so as to protrude upward.

3, when water flowing along the upper surface of the block B flows into the water reservoir 20, the water flows through the protrusions 21, causing water to flow into the reservoir 20 And flows along the inner surface of the reservoir portion 20 without lifting from the inner surface of the reservoir portion 20. Therefore, there is an advantage that water flowing into the water storage portion 20 can be prevented from swirling or generating bubbles.

That is, when the water flowing along the block B flows into the water storage portion 20, when the upstream surface of the water storage portion 20 is vertical, the water falls downward, It collides with the water and generates swirls and bubbles like the lower part of the waterfall. In such a case, the fish inside the water storage portion 20 may be hindered from being hit by water or being swimmed by the air bubbles.

However, in the water storage portion 20 of the present invention, not only the upstream side surface is inclined but also the projection 21 is formed on the upstream side circumferential portion so that the water flows vertically through the projection 21 , The water flows smoothly along the upstream side surface of the water storage portion 20, and bubbles are not generated.

Therefore, by preventing the water flowing into the water storage portion 20 from colliding with the water inside the water storage portion 20 to cause vortex or bubbles, the fish in the water storage portion 20 can be shocked or swim Thereby preventing the fish from being disturbed and allowing the fish to more easily ascend along the block B upstream.

2, a flow path 30 through which the water upstream of the beam A flows is formed in the inside of the island block B, Water is supplied from the circumference to the inside. Therefore, there is an advantage that water inside the water storage portion 20 having a deep depth can be prevented from being rotten, and moss can be prevented from being stuck inside the water storage portion 20.

3, the water flowing along the upper surface of the block B does not mix with the water below the water reservoir 20, but flows into the reservoir 20 ). ≪ / RTI > Therefore, the water below the water storage portion 20 does not flow and the amount of dissolved oxygen drops, so that the water below the water storage portion 20 rotates and moss can be trapped inside the water storage portion 20.

However, according to the present invention, water on the upstream side of the beam A directly flows into the bottom of the bottom of the bottom 20 through the through hole 22a, so that the water on the bottom of the bottom 20 is continuously circulated There is an advantage that the water below the water storage part 20 can be prevented from being rotten and the moss from being caught inside the water storage part 20. [

Particularly, the flow path 30 is formed by embedding a pipe 31 inside the block B, and the pipe 31 is provided with a branch pipe 31a connected to the reservoir portion 20, Since the diaphragm 22 having a plurality of the through holes 22a is provided in the reservoir 20 so that the flow path 30 can be easily formed and the water can be easily discharged from the inside of the reservoir 20 It is possible to effectively prevent the water stored in the water storage portion 20 from being replaced evenly and to prevent the water from being rotten because the water flow is generated over the entire bottom surface of the water storage portion 20 by spreading.

A drain port 31b is formed at the lower end of the pipe 31 so that the water level of the upstream water stored in the beam A is lowered to the reservoir 20 through the pipe 31 as shown in Fig. When no more water is supplied, the water remaining in the water storage portion 20 is drained to the downstream side through the pipe 31. Therefore, there is an advantage that water is not left in the water storage portion 20, and water remaining in the water storage portion 20 in the watery season can be prevented from being decayed.

Since the inlet of the flow path 30 is positioned below the drainage section 10, the water level in the upper part of the beam A becomes low due to the water supply, so that even if the water does not flow along the upper surface of the block B, Water upstream of the flow path (30) is supplied to the reservoir (20).

Therefore, even when the water is falling, there is an advantage that the fish can move to the upstream of the beam A in which water is stored along the block (B).

Particularly, since the diameter of the pipe 31 forming the flow path 30 is very small, water stored upstream of the beam A does not excessively flow toward the downstream side, and the water level upstream of the beam A flows into the pipe 31 The water level upstream of the beam A can be prevented from being excessively lowered by the pipe 31 because the water is not discharged to the downstream side.

In addition, since the charcoal powder is mixed in the island block (B), it is advantageous in that water is purified to protect fish in the reservoir (20) and to prevent water from decaying more effectively.

In this embodiment, the pipe 31 is opened, but a separate stopper is provided at the upper end of the pipe 31 so that the manager can selectively open and close the pipe 31.

In the method of constructing the eco-friendly waterproofing block structure as described above, first, a trenching step is performed so that the island block B can be positioned at a downstream point of the beam A. Through the above-mentioned groundwater disposal step, the waterproof block B is more firmly fixed from the water discharged downstream.

Next, the piping 31 constituting the flow path 30 is embedded after the completion of the tearing step. At this time, the pipe 31 is arranged so as to be inclined at a predetermined angle so that water is discharged from the upstream to the downstream, and the lower end of the pipe is formed with a drainage part 31b to drain the water. A branch pipe 31a is formed at a predetermined interval in the pipe 31 so as to be connected to a lower end of the water storage part 20 formed in the waterproof block B.

When the foundation work of the pipe 31 is completed as described above, the foundation concrete is installed and installed so that the pipe 31 can be firmly fixed to the drainage of water.

Next, when the foundation concrete filling step is completed, the block B is disposed on the foundation concrete. At this time, the upper part of the reservoir formed in the block B is exposed so as to be exposed to the outside, .

The finished concrete is installed so that the block (B) arranged in the stepwise shape is not collapsed by the flow velocity, and the initial concrete and the artificial block (B) are fixed to complete the construction.

A: Beam B:
10: drainage part 20:
21: projection 22: diaphragm
30: flow path 31: piping

Claims (7)

In a block provided on the downstream side of the beam A and whose upper surface is inclined downward toward the downstream side,
A plurality of water storage portions 20 for storing water are formed on the upper surface of the waterproofing block B so as to be spaced apart from each other in the upstream and downstream directions. So that you can take a break from it,
A flow path 30 through which water flows upstream of the beam A is formed in the inner block B so that the flow path 30 is connected to the inside of each of the reservoir portions 20, Is supplied to the inside of each reservoir (20) through the flow path (30). ≪ RTI ID = 0.0 > [3] The apparatus according to claim 1, wherein the upstream side surface and the downstream side surface of the water storage portion (20) are inclined toward the upstream side and the downstream side, respectively, and a plurality of projections (21) are protruded so as to be spaced apart from each other laterally. The method according to claim 1,
The flow path 30 is formed by embedding a pipe 31 inside the block B,
The upper end of the pipe 31 is connected to the upstream of the beam A through the beam A,
A branch tube 31a connected to the lower side of the reservoir 20 is provided at an intermediate portion of the pipe 31,
A drain port 31b, which is open to the downstream side of the block B, is formed at the lower end of the pipe 31,
And a partition plate (22) having a plurality of through holes (22a) formed therein is installed inside the reservoir part (20). The eco - The method of claim 3,
The upper end of the embroidery block B corresponds to the lower end of the drainage unit 10 formed concavely at the upper end of the beam A,
Wherein an inlet port (31c) at an upper end of the flow path (30) is positioned below the drainage section (10) The eco-friendly block structure according to claim 1, wherein the block (B) is mixed with charcoal powder delete delete

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