KR100627032B1 - Automated hydrologic main body, which facilitates the removal of suspended solids and discharges the influent without opening the main body by the role of the siphon passage. - Google Patents

Abstract

According to the present invention, the cylinder 22 for opening and closing the water main body 1 is installed in the sealed space 11 of the support structure 100, thereby greatly reducing the risk of the cylinder 22 failure caused by impurities such as plants. In addition, the conservation of natural ecosystems is facilitated by facilitating the movement of fish from downstream to upstream through the lower end of the hydrologic main body.

In addition, due to the discharge function through the siphon passage (16) configured to suck up the lower water of the hydrologic main body (1) due to being configured to discharge the influent flowing in the upstream of the stream even if the lower end of the hydrological main body is not opened It is an invention that can promote the safety of swimmers playing in the river.

Through the siphon passage 16 formed inside the hydrologic main body 1, it is possible to discharge the pollutants precipitated in the water on the reservoir side even when the hydrologic main body 1 is closed, so that the water quality improvement effect can be exerted. .

In addition, the floating material removal plate for facilitating the removal of the suspended substances on the top of the hydrologic main body is configured on the top of the hydrologic main body to easily remove the suspended substances caught on the top of the hydrologic main body.

Hydrologic main body, Edo, Cylinder, Central axis, Support member

Description

Automated hydrologic main body configured to facilitate the removal of suspended solids and to discharge influent without opening the main hydrologic body by acting as a siphon passageway

1 is a perspective view showing a state in which the automatic guard body is configured to discharge the influent without opening the body of the water by the role of the siphon passage of the present invention closed.

Figure 2 is a perspective view showing an open state of the automatic guard body is configured to discharge the influent without opening the body of the water by the role of the siphon passage of the present invention.

3 is a cross-sectional view taken along the line A-A of FIG.

4 is a cross-sectional view taken along the line B-B in FIG.

5 is a perspective view showing an open state of the sluice body constructed in accordance with the second embodiment of the present invention.

Figure 6 is a perspective view showing a state in which the hydrologic main body is configured according to a second embodiment of the present invention.

Figure 7 is an internal perspective view showing the internal structure of the sluice body constructed in accordance with a second embodiment of the present invention.

8 is a cross-sectional view of the hydrological main body "B1-B1" of FIG. 7 constructed in accordance with a second embodiment of the present invention.

9 is a plan view of a hydrological body constructed in accordance with a second embodiment of the present invention.

FIG. 10 is a cross-sectional view of a hydrograph “C-C” line of FIG. 7 constructed in accordance with a second embodiment of the present invention; FIG.

FIG. 11 is a cross-sectional view of a hydrological main body "A1-A1" constructed in accordance with a second embodiment of the present invention. FIG.

12 is an enlarged cross-sectional view of FIG. 8.

FIG. 13 is an enlarged cross-sectional view of FIG. 10.

14 is an internal perspective view of the hydrological body constructed in accordance with the fourth embodiment of the present invention.

Fig. 15 is a sectional view of the sluice body line B2-B2 constructed in accordance with the fourth embodiment of the present invention.

Figure 16 is a cross-sectional view of the hydrological body A4-A4 constructed in accordance with a fourth embodiment of the present invention.

Fig. 17 is a sectional view of the sluice main body line D-D constructed in accordance with the fourth embodiment of the present invention.

FIG. 18 is an enlarged cross-sectional view of FIG. 15 showing line B2-B2 of the hydrological body constructed in accordance with the fourth embodiment of the present invention; FIG.

19 is a front view of a hydrological body constructed in accordance with a fourth embodiment of the present invention.

20 is a rear view of the hydrological body constructed in accordance with the fourth embodiment of the present invention.

<Code Description of Main Parts of Drawing>

1. Hydrological body 11. Cylinder sealed space 16. Cypress passage 22. Hydraulic cylinder 33. Inflow inlet 34. Floating material removal plate 35. Roller 36. Cylinder rod 37. Resilient hinge 38. Cylinder (rotating member) 39 Cylinder seal 44. Inlet outlet 551. Hydraulic induction plate 552. Fish transfer guide 55. Lower skin plate of sluice body 56. Upper skin plate of sluice body 66. Barrier plate 100. Support structure

The present invention relates to a floating automatic hydrologic main body for opening and closing a channel by a hydrological main body operated by hydraulic pressure or power to adjust the low water upstream of the channel, and a cylinder for opening / closing the main hydrologic main body in a sealed space of the support structure. It greatly reduces the risk of cylinder failure due to impurities such as water plants, and easily moves small fish upstream and downstream through the lower part of the hydrologic main body, thereby conserving the natural ecosystem and lower layer of the hydrologic main body. The safety of the swimmers who play in the river is configured to discharge the amount of inflow from the upstream of the river even though the hydrologic main body is not opened by the function of discharging the influent through the siphon passage configured to suck up the water. It is an invention that can be planned.

It is configured to preferentially discharge heavy water in the lower layer on the reservoir side even when the body is closed through the siphon passage formed inside the body.

The present invention relates to a floating automatic hydrology main body configured to exert a water quality improvement effect of contaminated water by enabling the discharge of contaminants deposited in the lower layer.

In addition, suspended solids floating upstream of the river at the time of flooding are caught on the top of the hydrologic body, and there are significant problems that must be removed artificially.

The present invention relates to an automatic flood guard body configured to easily remove the suspended solids by forming a suspended solids removal plate on the top of the hydrologic body in order to easily remove the suspended solids floating in the upper stream during the flood.

The hydrologic main body of the present invention is contaminated by the action of the siphon discharge system having an esophagus function that can facilitate the movement of fish from the downstream to the upstream since the hydrologic main body is operated in a floating manner. It relates to a floating automatic floodgate body in which the waterway naturally forms as the water quality is naturally purified.

Underwater channel is installed to control the low water upstream of the channel considering the flood control function, the securing of agricultural water, or the aesthetics upstream of the channel.

There are many kinds of hydrological bodies provided in the related art and many methods of operation thereof. In most hydrological bodies, the hydrological body is formed between supporting structures such as concrete, which is constructed at predetermined intervals on both sides of the channel in the width direction. Along with the main body, the upper or lower part of the sluice body is rotatably supported on the support structure through the shaft, and the sluice body is rotated around the shaft by a motor or cylinder to discharge the influent. There were problems that caused serious problems, that is, there were serious problems that people who were sucked into the lower part of the hydrologic body could drown because they could not overcome the power of water when the hydrologic body was opened slightly.

However, most of the hydrologic main body as described above is a problem that causes frequent failures because the opening and closing of the hydrological main body is made by an electric motor vulnerable to water, in the case of the cylinder is a water, sand, a working gap of the cylinder exposed to water There is a problem that causes a failure by inflowing to impurities such as. In addition, due to gravity pressure during flooding, the sluice caused by sediment, such as sand gravel, which is pushed into the lower part of the sluice body, is unable to fully open the sluice and the sluice of the hydrologic body loses its function as a hydrologic body. There is a serious problem.

In addition, since any of the conventionally provided hydrological bodies are focused only on the function of opening and closing of waterways, consideration is required to facilitate the movement of fish or to help the natural improvement of contaminated water quality. .

The present invention has been invented in view of the above-mentioned conventional problems, and its object is to facilitate the movement of fish from the downstream to the upstream easily without forming a separate fishery in the hydrologic main body or its lower part. Promote the preservation of the ecosystem, prevent the accumulation of sand and gravel on the lower part of the hydrologic main body to facilitate the opening and closing of the hydrologic main body, and to discharge the pollutants settled in the water, and to release the cyphon that can exert the water quality improvement effect. The purpose of the present invention is to provide a floating automatic flood guard body in which the fish is naturally formed when the water main body is opened while the water quality contaminated by the passage is naturally purified.

In addition, even if the suspended solids flowing from the upper part of the river during flooding are caught unsightly at the top of the hydrologic main body, it is a major technical task to make the suspended solids float down to the lower part of the river by quickly operating the float removal plate. .

In addition, when the hydrologic main body is normally opened, a number of fish movements are induced on the upstream and downstream floors of the support structure where the hydrological main body is installed as a means to help the fish that are submerged upstream and downstream of the stream flow up and down. It is a main technical problem of the present invention to exert an effect of restoring a river ecosystem by configuring a string.

The hydrological main body provided by the present invention is a floating automatic hydrologic body which naturally forms the fish while the polluted water is naturally purified by the action of the cyphon exhaust system that exhibits the natural function of the polluted water while showing the function of the fish. It is about.

The support body of the sluice main body is constructed at regular intervals in the width direction of the channel, and the sluice main body in the shape of a hollow square plate is inclined between the support structures, and the upper part of the sluice main body is rotatable to the support structure by the central axis. In the fixed one, a sealed space portion for storing the cylinder is formed in the body portion formed on both sides of the hydrological body, and in the sealed space portion, the cylinder is disposed on a support shaft for supporting the hydrological body and a support bracket for supporting the cylinder. The upper end of the cylinder is rotatably fixed to the support bracket fixed to the upper side of the sealed space, and the lower end of the cylinder is rotatably fixed to the other end of the link connected to the central axis, and the hydrologic main body is centered by stretching the cylinder. Characterized in that it can be rotated around the fixed axis.

In the above, the siphon drain passage is formed in the lower side of the water main body through the upper portion of the water body from the lower side of the water body main body.

The present invention is to install the cylinder for opening and closing the body of the hydrology in the enclosed space of the both sides of the body of the body to greatly reduce the risk of failure of the cylinder by impurities such as a few seconds, so opening and closing of the body of the body without any problems easily It can be durable.

In addition, even if the suspended solids flowing from the upstream of the river are unsightly caught on the top of the hydrologic body during flooding, the suspended solids removal plate is quickly operated to configure the suspended solids to float through the downstream portion of the stream.

In addition, a large number of hydraulic induction plates are provided on the upstream and downstream floors of the fron, where the hydrological main body is installed as a means to help fish slaughtered upstream and downstream from the stream when the hydrological main body is normally opened. After constructing the fish-guided straps consisting of a brush-like member on the rear of the hydraulic guide plate is configured to exert the action to restore the river ecosystem.

Hereinafter, a specific first embodiment of the present invention will be described in detail with reference to the drawings.

1 is a perspective view showing a state in which an automatic flood guard body configured to discharge inflow water without opening the floodgate main body by the role of a siphon passage configured inside the floodgate main body according to the present invention is closed, and FIG. In accordance with the present invention is a perspective view showing an open state of the automatic repair door body configured to discharge the inflow water without opening the water main body by the role of the siphon passage configured in the interior of the water body, Figure 3 is a line AA of Figure 2 4 is a cross-sectional view taken along line BB of FIG. 1.

5 is a perspective view illustrating an open state of a sluice main body constructed in accordance with a second embodiment of the present invention, and FIG. 6 is a perspective view illustrating a closed sluice main body constructed in accordance with a second embodiment of the present invention. Figure 7 is an internal perspective view showing the internal structure of the hydrological main body constructed in accordance with the second embodiment of the present invention, Figure 8 is a hydrological body "B1-B1" line of Figure 7 constructed in accordance with the second embodiment of the present invention. It is a cross section. FIG. 9 is a plan view of a hydrologic main body constructed in accordance with a second embodiment of the present invention, and FIG. 10 is a cross-sectional view illustrating a hydrologic main body “C-C” line in FIG. 7 constructed in accordance with a second exemplary embodiment of the present invention. FIG. 11 is a cross-sectional view of a hydrological main body "A1-A1" line constructed in accordance with a second embodiment of the present invention, FIG. 12 is an enlarged cross-sectional view of FIG. 8, FIG. 13 is an enlarged cross-sectional view of FIG. FIG. 15 is a cross-sectional view of the hydrological main body main body constructed in accordance with the fourth embodiment, and FIG. 15 is a cross-sectional view of the hydrological main body B2-B2 constructed in accordance with the fourth exemplary embodiment of the present invention, and FIG. 17 is a cross-sectional view of a hydrological main body A4-A4, and FIG. 17 is a cross-sectional view of a hydrological main body DD constructed according to a fourth embodiment of the present invention, and FIG. 18 is a B2 of a hydrological main body constructed in accordance with a fourth exemplary embodiment of the present invention. 15 is an enlarged cross-sectional view of FIG. 15 showing a line B2, and FIG. 19 is a front view of a hydrological body constructed in accordance with a fourth embodiment of the present invention, and FIG. 20 is a hydrological body constructed in accordance with a fourth embodiment of the present invention. Is the rear view of.

The automatic floodgate body AW of the present invention is disposed inclined between the supporting structures 100 of the concrete structure constructed at regular intervals in the width direction of the waterway as in the prior art.

The sluice body (1) is in the shape of a square plate and the central axis 55 is formed on the upper portion of the sluice body (1), the central shaft (55) is a support structure composed of both sides of the sluice body (1) It is hinged to the support shaft 24 comprised in the inside of 100. By the above structure, the hydrologic main body 1 can be rotated about the central axis 55.

An elongated sealed space 11 is formed from the support shaft 24 supporting the hydrological body 1, and the cylinder 22 is disposed up and down by a hinge in the sealed space 11.

The upper end of the cylinder 22 is fixed to the support shaft 24 of the sluice main body 1 fixed to the upper side of the sealed space 11 so as to be rotatable by the link 99, and the lower end of the cylinder 22 is one end of the cylinder It is rotatably fixed by the pin 72 fixedly connected to the fixed shaft 71.

When the cylinder 22 is stretched and contracted as described above, as shown in FIGS. 1 and 2, the hydrologic main body 1 may rotate about the central axis 55 to open and close the waterway, and in this operation, Since the cylinder 22 is accommodated in both side sealed spaces 11 of the sluice body 1, foreign matters do not flow into the cylinder sealed spaces 11 and there is no fear of failure due to foreign matters.

In the above operation, the water body 1 is closed in the closed state as shown in FIG. 1.

In the present invention, the siphon passage 16 is formed in the lower side of the water main body 1 through the upper portion of the water body 1 at the lower side of the water body 1, and the siphon passage 16 is formed. The hinge plate is configured to automatically shut off the cyphon passage 16 when the water main body 1 is opened by the blocking plate 66. At this time, when the sluice body 1 is closed as shown in FIG. 3, the blocking plate 66 is opened by an external operation, and when the sluice body 1 is opened as shown in FIG. 4, the blocking plate is opened. By 66, the influent inlet 33 is automatically closed.

In order to artificially manipulate the blocking plate 66, the coupling of the blocking plate 66 with the rotating member is also possible, so that those skilled in the art can easily change the design, it is natural to fall within the scope of the present invention.

In addition, even if the position of the blocking plate 66 is configured to arbitrarily change the amount of inflow flowing in the upstream of the stream when passing through the siphon passage 16 to achieve the effects of the present invention Even if the position is different, it is natural that it belongs to the scope of the present invention.

As the siphon passage 16 is formed in the hydrologic main body 1 as described above, when the hydrologic main body 1 is closed, the low water level is increased due to the pressure action of the hydraulic pressure generated when the water level is increased. When reaching the upper end of the main body of 1), the water in the lower layer stored by the natural pressure of water is stored in the rear side of the reservoir through the inflow outlet 44 of the siphon passage 16 formed in the hydrologic main body 1. Due to discharged to the rear portion of the sluice body (1) on the influent inlet 33 is configured to prevent the phenomenon of stagnation (腐敗) while stagnating in the lower water side. Here, when the water main body 1 is in an open state, the cyphon passage 16 is kept closed by the blocking plate 66, so that there is no fear of being blocked by the cyphon passage 16.

Referring to a second embodiment of the present invention, a method for configuring a cypress passageway is as follows.

FIG. 5 shows an open state of a sluice main body constructed in accordance with a second embodiment of the present invention, and FIG. 6 shows a closed state of a sluice main body constructed in accordance with a second embodiment of the present invention. Is an internal perspective view showing the internal structure of the hydrological main body constructed in accordance with the second embodiment of the present invention, and FIG. 8 is a cross-sectional view of the hydrological main body "B1-B1" in FIG. 7 constructed in accordance with the second exemplary embodiment of the present invention. 9 illustrates a plan view of a hydrologic main body constructed in accordance with a second embodiment of the present invention, and FIG. 10 illustrates a hydrologic main body "CC" line of FIG. 7 constructed in accordance with a second exemplary embodiment of the present invention. 11 is a cross-sectional view of the hydrological main body "A1-A1" line constructed in accordance with the second embodiment of the present invention.

12 is an enlarged cross-sectional view of FIG. 8, and FIG. 13 is an enlarged cross-sectional view of FIG. 10.

Referring to each code shown in accordance with the second embodiment is as follows.

Reference numeral 1 denotes the hydrologic body, reference numeral 22 denotes the hydraulic cylinder, reference numeral 24 denotes the support shaft of the hydrologic body, reference numeral 16 denotes the cyphon passageway, reference numeral 33 denotes the influent inlet, and reference numeral 44 denotes the influent outlet. 21 indicates the hinge of the hydrological body, 25 indicates the cylinder support shaft, 26 indicates the cylinder rod hinge shaft, 27 indicates the index packing, and 51 indicates the circular pipe formed at the bottom of the hydro body. , Reference numeral 52 is the c-beam, indication 53 is the H-beam, indication 54 is the cische corridor, indication 55 is the lower skin plate of the sluice body, and 56 is the upper skin plate of the sluice body. The reference numeral 59 denotes a circular pipe of the hydrological main body, the reference numeral 58 denotes a bolt for tightening the exponential packing, the reference numeral 65 denotes a siphon passage divider, and the reference numeral 100 denotes a support structure for supporting the hydrological main body. .

Referring to the structure of the hydrological body of the second embodiment according to the present invention is as follows.

The second embodiment is a modification of the method for constructing the cyphon passage 16 constituted according to the first embodiment of the present invention more simply than the first embodiment.

As the structure of the hydrological main body 1 fixed to the hinge 21 on the support shaft 24 formed on the other side of the support structure 100, the upper end of the support shaft 24 is configured with a cylinder support shaft 25, the hydrological body ( The lower end of one side and the other end face is hinged to the hydrologic main body 1 by a cylinder rod hinge shaft 26 hinged to the cylinder 22 and generated by a hydraulic cylinder operating device configured at the top of the embankment. A hydraulic piping line (not shown) is coupled to allow the hydraulic pressure to be transferred to the cylinder 22, and the hydraulic cylinder operating device (not shown) is a structure that is automatically operated by an instruction of an automatic control system (not shown).

Since the structure of the axial body and the cylinder of the hydrologic main body and the automatic control system connected to the hydraulic piping line can be used using a known member, it is not described and not shown.

The second embodiment is configured as follows.

형강(52)을

이러한 형태로 뒤집어서 원형파이프(51)와 수평이 되도록 접합한 다음,

형태로 원형 파이프와 접합된 ㄷ형강(52)의 후면 중앙부분에 평판으로 구성되는 싸이폰 통로 분리판(65)을 접합 구성함과 함께 싸이폰통로(16)의 역할을 하도록 구성되는 각관(54)이 상,하로 겹치도록 안치 한 다음 각관(54)이 겹치는 중간부분에 싸이폰 통로 분리판(65) 상단을 접합시킴과 동시에 겹치도록 구성되는 각관(54)의 상단부분 60%∼70% 정도의 위치에 싸이폰 통로(16)의 역할을 하도록 "□"자 형태로 싸이폰 통로(16)를 구성시켜 줌과 함께 각관(54)의 상단은 H빔(53)과 접합시킨 다음, H빔(53)은 수문본체(1)의 주축을 구성하는 원형파이프(59)를 접합시킨다.
이러한 방식으로 수문본체(1)의 내부에 구성되는 수문본체(1)의 골격과 싸이폰 통로(16)는 다수의 각관(54)과 원형 파이프(51)(59)와 ㄷ형강(52)과 H빔(53)에 의해 세로의 수문본체(1) 골격 구조를 구성함과 함께 수문본체(1)의 가로 골격 프레임(86) 구성은 횡으로 구성되는 다수의 각관(54) 사이 사이에 다수의 가로 골격프레임(86)을 일정한 길이로 절단하여 ㄷ형강(52)의 후면부와 가로로 구성되는 H빔(53)의 사이에 세로로 세워 삽입한 다음, 수문본체(1)의 하단에 구성되는 ㄷ형강(52)의 후면부에 세로로 구성되는 가로 골격프레임(86)의 하단을 접합시킨 다음, 세로로 구성되는 횡형 프레임(79)의 상단은 H빔(53)과 접합시키는 방법에 의해 수문본체(1)의 내부 골격이 구성된다. 이렇게 구성되는 수문본체(1)의 골격 상단에는 상단 스킨 플레이트(56)과 하단 스킨 플레이트(55)를 수문본체의 내부 골격과 접합하여 주면 수문본체(1)의 상,하 표면이 완성되는 것이며, 수문본체(1)의 상단 스킨 플레이트(56)와 하단 스킨 플레이트(55)의 하단부에 싸이폰 통로(16)의 역할을 하도록 유입수 배출구(44)와 유입수 유입구(33)를 장방형의 직사각형태로 타공시켜 싸이폰 통로(16)를 구성시켜주는 구조이다.On the circular pipe 51 formed at the lower end surface of the upper skin plate 56, which is the main component of the sluice body 1,

Section steel (52)

Inverted in this form and bonded to the horizontal pipe 51 to be horizontal,

Square pipe (54) is configured to serve as a siphon passage (16) together with the configuration of the siphon passage separation plate 65 consisting of a flat plate in the rear center portion of the c-section (52) joined to the circular pipe in the form ) And the upper and lower parts of the upper part of the tube 54, which is configured to overlap and at the same time joining the upper part of the siphon passage separation plate 65 to the middle part where the tube 54 overlaps. The chief passage 16 is configured in a "@" shape to serve as the cyphon passage 16 at the position of, and the upper end of the tube 54 is joined to the H beam 53, and then the H beam is formed. Reference numeral 53 joins the circular pipe 59 constituting the main axis of the hydrological body 1.
In this manner, the skeleton and the siphon passage 16 of the sluice main body 1 constituted inside the sluice main body 1 are provided with a number of square tubes 54, circular pipes 51, 59, and c-beams 52, The H frame 53 constitutes the vertical hydrologic body 1 skeleton structure, while the horizontal skeletal frame 86 configuration of the hydrological body 1 has a large number of spaces between a plurality of square tubes 54 formed laterally. The horizontal frame frame 86 is cut to a predetermined length and inserted vertically between the rear portion of the c-beams 52 and the H beams 53 constituted horizontally, and then the c is formed at the bottom of the sluice body 1. After joining the lower end of the horizontal frame (86) vertically formed on the rear portion of the steel (52), the upper end of the horizontal frame (79) configured vertically is joined to the H-beams 53 by a method of joining the hydrological body ( The internal skeleton of 1) is constructed. When the upper skin plate 56 and the lower skin plate 55 are joined to the inner skeleton of the hydrologic main body at the upper end of the skeleton of the hydrologic main body 1, the upper and lower surfaces of the hydrological main body 1 are completed. The inlet outlet 44 and the inlet inlet 33 are perforated in a rectangular shape to serve as a siphon passage 16 at the lower part of the upper skin plate 56 and the lower skin plate 55 of the sluice body 1. It is a structure that constitutes the cell phone passage (16).

The method for constructing the cyphon passage 16 constituted according to the second embodiment can be designed and changed by any means known to those skilled in the art.

As described above, the method for constructing the siphon passage according to the first and second embodiments can be variously modified.

형태로 두쌍을 절곡하여 상판의 반대 부분이 겹치도록 구성하거나 또는 두쌍의 판재를 ㄹ자 형태로 연속 절곡하여 가로로 겹치도록 접합하여 구성하거나 원형 파이프를 이용한다 해도 제1실시예와 제2실시예에 따른 싸이폰통로의 구성을 변형하여 구성할 수가 있는 것이므로 이러한 변형된 형태로 사이폰통로를 구성하는 것 또한 본 발명의 권리 범위에 속하는 것은 당연한 것이다.For example, by bending and joining a plate member in this form without using a square tube pipe, which is a constituent member of the cyphon passage configured according to the second embodiment, or

According to the first embodiment and the second embodiment, even when the two pairs are bent in a shape to form opposite parts of the upper plate, or the two pairs of plates are continuously bent in a L shape to be joined to overlap each other, or a circular pipe is used. Since it can be configured by modifying the configuration of the cyphon passage it is natural that the configuration of the siphon passage in this modified form also falls within the scope of the present invention.

이러한 형태로 남는 부분이 반대로 겹치도록

이러한 형태로 구성하여 싸이폰 역할을 구성할 수가 있는 것이다.In addition, to remove the one-way portion from the square tube portion of the K-shaped to change the length of the tube to be joined to the back portion of the c-beam or to serve as a siphon passage.

So that the parts that remain in this form overlap

By configuring in this form, you can configure the role of the cell phone.

As such, it is natural to belong to the scope of the present invention as modifications can be made by those skilled in the art.

Referring to the operation according to the first embodiment and the second embodiment configured as described above are as follows.

When the water flows up to the upper part of the hydrologic main body 1, the clean water and the sedimentary sludge stored in the lower part of the reservoir through the siphon passage 16 composed of about 60% to 70% of the internal body of the hydrologic main body After passing through the inflow water outlet 44 by the pressure of the over the siphon passage 16 is to be automatically discharged through the rear portion of the water main body 1 through the inflow water inlet 33

The reason is that clean water, which has a high specific gravity contained in the water, is deposited in the lower part of the stream, and because the clean water and sedimentary sludge are discharged first, the contaminated water is continuously raised.

In addition, by acting as a siphon passage, it is possible to promote the safety of swimmers who play in the water by releasing the amount of river water inflow without opening the body.

In the present invention, since the cyphon passageway of the present invention can be configured by modifying the position where the cyphon passageway is formed according to the situation, the method for configuring the cyphon passageway at a point of about 60% to 70% is limited. The reason is that if the inflow control plate (not shown) and the discharge control plate (not shown) are freely applied or modified by using technologies that can be developed and applied, the storage water level is freely stored in the inside of the cyphon passage. This is because not only can control the position of the siphon passage can be configured to control the amount of inflow and outflow water flowing in the upstream of the river.

Therefore, it is natural that such modified technology also falls within the scope of the present invention.

Next, a third embodiment combined with the present invention is configured as follows.

The third embodiment of the present invention relates to the configuration of the fish movement guide string 552 constituted in the hydraulic guide plate 551 in the upstream and downstream parts of the hydrologic main body, the configuration of which is as follows.

Induce fish movement in the hydraulic guide plate 551 in the form of a brush made of a flexible material, such as a rope made of a cloth or poly ethylene such as a cloth to help the fish easily move from the drain side to the reservoir side as a support medium The string 552 is a structure that is fixed in a zigzag form on the bottom of the lower portion 552 and the apron upstream portion of the sluice body (1) and the bottom of the support structure 100 of the sluice body (1).

자 형태로 브러쉬가 구성되는 구조로서, 어류 이동끈(552)을 구성시켜 사용할 수가 있는 것이다. 그러나 그 형태는 이러한 형태로 구성하거나

형태의 모양이거나 또는

이러한 형태로 다양하게 변형하여 구성할 수가 있는 것이므로 그 모양과 형태를 한정적으로 한정하는 것이 아니다.As described above, a plurality of hydraulic guide plates 551 and fish movement guide strings 552 are formed upstream of the support structure and the upstream portion of the hydrologic main body 1 to move upstream in the open state of the hydrological main body 1. In spite of the strong hydraulic pressure of the fish, the fish fins can be easily moved by relying on the fish moving string 552 configured in the form of a brush to enable the preservation of the natural ecosystem. The shape of the fish migration string 552 is configured to form a chimney cleaning brush on the rope or

As a structure in which a brush is formed in the shape of a child, the fish moving string 552 can be configured and used. However, the form may consist of these forms

Is a shape

Since the present invention can be configured in various forms, the shape and shape thereof are not limited thereto.

Next will be described the structure according to the fourth embodiment of the present invention.

Referring to the structure of the foreign material remover coupled to the hydrologic main body according to the present invention.

3 and 4 show a cross section of the siphon passage and a cross section of the foreign matter remover according to the first embodiment.

The reason why the detailed view is not shown but only in the cross section is that it can be deformed depending on the length of the body.

Floating materials introduced from the upstream of the river during the flood is caught on the upper end of the hydrologic body (1), the floating material removing plate 34 is provided to the elastic hinge (37) to remove these floating materials easily By the combination of the semi-circular U-shaped form on the top of the sluice body (1).
A cylinder chamber 39 is formed at the center of the sluice main body 1, and a cylinder 38 and a cylinder rod 36 are formed at the cylinder chamber 39, and a roller is formed at the end of the cylinder rod 36. 35 is configured, and the rear portion of the cylinder 38 is hinged to the cylinder chamber 39, and the cylinder 38 is connected to the pipe line.
At this time, since the number of the hinge 37 having elasticity coupled with the floating material removing plate 34 can increase or decrease the number, the number is not limited.

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The cylinder 38 configured to operate the suspended solids removing plate 34 is coupled by a hinge 60 configured at the rear portion of the cylinder 38 and actuated to remove suspended solids caught by the hydrologic main body 1. The reverse operation of the suspended solids removing plate 34 is operated by the cylinder rod 36 coupled with the cylinder 38 constituted at the upper center of the sluice body 1, and the cylinder 38 and the cylinder rod 36. The floating material removing plate 34, which has been retracted by the force of, is configured to repeat the floating material removing plate 34 to be intimately contacted with the hydrologic main body 1 by the elastic force of the hinge 37 having elasticity.
Referring to the operation state of the suspended solids removing plate 34, the cylinder rod 36 is extended by the operation of the cylinder 38 coupled by the hinge 60 to the rear portion as shown in Figs. , The floating material removing plate 34 formed in a semicircular U-shaped shape is opened around the hinge 37 (see FIG. 3).
Accordingly, the suspended substances suspended in the suspended substance removing plate 34 will be floated to the downstream part of the river.

The cylinder rod 36 coupled with the cylinder 38 configured to operate the suspended solids removing plate 34 is configured to reciprocate only, and the inner surface of the suspended solids removing plate 34 is formed at the end of the cylinder rod 36. It is a structure in which the rotary roller 35 is configured to be in close contact with the part to enable the rolling.

The hydraulic or pneumatic piping line and the automatic control system for operating the suspended solids removing plate 34 configured as described above are not shown because they can be used as many as possible by using various well-known or application-developable machines. Not explained. In addition, since the member that can be configured to rotate the floating material removing plate 34 can be configured in thousands of variations, it is natural that even if the configuration is wrong, it belongs to the scope of the present invention.

Referring to the structure of the hydrological body according to the fourth embodiment of the present invention is as follows.

The fourth embodiment is a slight modification of the method of constructing the hydrological body 1 according to the first and second embodiments.

FIG. 14 is an internal perspective view of a hydrologic main body constructed in accordance with a fourth embodiment of the present invention. FIG. 15 is a cross-sectional view of a hydrologic main body B2-B2 constructed in accordance with a fourth exemplary embodiment of the present invention. 18 is a cross-sectional view of a hydrological main body A4-A4 constructed in accordance with a fourth embodiment, and FIG. 17 is a cross-sectional view of a hydrological main body DD constructed in accordance with a fourth exemplary embodiment of the present invention. 15 is an enlarged cross-sectional view of the hydrological main body B2-B2 of FIG. 15, FIG. 19 is a front view of the hydrological main body according to the fourth exemplary embodiment of the present invention, and FIG. 20 is a fourth exemplary embodiment of the present invention. The rear view of the hydrologic body constituted by

자형태로 원형파이프(51)와 ㄷ형강(52)이 수평이 되도록 접합한 후, 상단 스킨 플레이트(56) 중간 상부 부분에 H빔과 같은 강재로 구성되는 중간 프레임(77)을 상단 스킨 플레이트(56)와 접합함과 함께 H빔과 같은 강재로 구성되는 중간 프레임(77)의 중간 중간에는 싸이폰 통로(16)의 역할을 하도록 직사각 형태로 장방형 타공시킴과 함께 직사각 형태로 타공 되어진 싸이폰 통로(16)의 중간 중간에는 편철과 같은 부재로 구성되는 보강판(78)을 삼각형 형태로 중간 프레임(77)과 접합시킴과 함께 상단 스킨 플레이트판(56)의 상단 끝단에는 또 다른 H빔(53)으로 구성되는 상단프레임을 상단 스킨 플레이트(56)에 접합함과 함께 H빔(53)의 후면 상단에는 원형 파이프(59)로 구성되는 가로 프레임을 H빔(53)과 접합 구성시킴과 함께 가로로 구성되는 ㄷ형강(52)의 후면부와 중간 프레임(77)의 공간 사이 그리고 H빔(53)의 사이 사이에는 세로로 구성되는 H빔으로 이루어진 다수의 횡형 프레임(79)을 삽입함과 함께, ㄷ형강(52)의 후면부와 중간 프레임(77)의 공간 사이와 H빔(53) 사이에 삽입되어진 H빔을 연속 접합하여 횡형 프레임(79)을 구성한 후, H빔과 같은 부재로 구성되는 다수의 횡형 프레임(79)을 상단 스킨 플레이트(56)와 또다시 접합하여 줌과 함께 ㄷ형강(52)과 중간 프레임(77) 그리고 H빔(53)과 횡형 프레임(79)의 상단에는 강재로 구성되는 하단 스킨 플레이트(55)를 접합구성한 후, 하단 스킨 플레이트(55)의 하단부에는 싸이폰 통로(16)와 연결되는 유입수 유입구(33)를 장방형의 직사각형태로 타공 구성함과 함께 수문본체(1)의 배면부를 구성하고 있는 상단 스킨 플레이트(56)의 중간 상부60~70% 부분에 유입수 배출구(44)를 장방형의 직사각 형태로 타공시킨 구조이다.In the fourth embodiment, the method of constructing the siphon passage 16 constructed in accordance with the first embodiment of the present invention is modified more simply than in the first and second embodiments, and the upper part of the upper plate of the sluice body 1 is constructed. Join the round pipe 51 to the bottom end of the skin plate 56, and then turn the c-section upside down to join the c-section 52 to the round pipe 51.

After the circular pipe 51 and the c-beam 52 are horizontally bonded in a shape of a child, an intermediate frame 77 made of steel such as an H beam is attached to the upper portion of the upper skin plate 56, and the upper skin plate ( 56) and in the middle of the intermediate frame (77) made of steel such as H-beams, the rectangular siphon and the perforated rectangular in the rectangular shape to serve as the siphon passage (16) In the middle of the (16) in the middle of the reinforcing plate 78 consisting of a member such as sewn in a triangular form and bonded to the intermediate frame 77, while at the top end of the upper skin plate plate 56 another H beam (53) The upper frame consisting of a) is bonded to the upper skin plate 56, and the horizontal frame composed of a circular pipe 59 is bonded to the H beam 53 at the upper end of the rear surface of the H beam 53, The back and middle of the steel beam 52 consisting of Between the space of the frame 77 and between the H beam 53, a plurality of horizontal frames 79 made of vertically formed H beams are inserted, and the rear portion of the c-beams 52 and the intermediate frame 77 After the H-beams inserted between the spaces of the H beams 53 and the H-beams 53 are continuously joined to form a horizontal frame 79, a plurality of horizontal frames 79 made of a member such as the H-beam are attached to the upper skin plate 56. After joining again and then to the upper portion of the c-beam (52), the intermediate frame (77) and the H-beam (53) and the transverse frame (79) is bonded to the lower skin plate (55) made of steel, At the lower end of the lower skin plate 55, the inlet inlet 33 connected to the cyphon passage 16 is perforated in a rectangular shape, and the upper skin plate 56 constituting the rear part of the hydrologic main body 1 is formed. The inlet outlet 44 in the middle upper 60-70% A perforated structure in which a rectangular shape.

The method for constructing the cyphon passage according to the fourth embodiment configured as described above is a structure in which only the first embodiment and the second embodiment are modified in yet another form.

The structure of the body according to the first, second, and fourth embodiments enumerated as above can be modified in various ways.

For example, even if the member of the c-beam 52 and the intermediate frame 77 which are the main structural members used to construct the interior of the sluice main body 1 are changed to the b-beam or c-beam, the effects of the present invention will be exhibited. It is natural that the number belongs to the scope of the present invention.

In addition, the structure of the present invention can be completed even if the configuration of the cyphon constituent member is changed to H-shaped steel or the configuration of the cyphon passage using the braided member. It is natural.

The configurations enumerated as described above have described the configurations according to the embodiments of the present invention and do not limit the technical scope of the present invention. That is, the present invention can be variously modified within the technical scope and it is natural that such variations belong to the scope of the present invention. In addition, it is very easy to change the structure according to the present invention by those skilled in the art using the various known members of the constituent members of the cell phone configured in the invention. Therefore, since the configuration of the present invention can be completed through a slight design change, it is natural that the configuration and structure of the siphon passage are slightly modified by incorporating the conductive hydrologic method, and also belong to the scope of the present invention.

In addition, the arc-shaped index member and the packing member constituted in the sealed space portion formed on both side portions of the sluice body can be configured using any known member. It is natural to fall within the scope of rights. In the construction of the siphon drainage passage configured in the present invention, the person skilled in the art can apply and manufacture the cyphon configuration method of the present invention even if the method of opening / closing the hydrology main body is any other way. It is a matter of course that the combination with the main body also belongs to the scope of the present invention.

In addition, the shape and shape of the hydraulic guide plate configured in the present invention and the fish migration guide string is configured so that the fish moving upstream of the river can rely on the fins to guide the fish migration guide, even if the material is different Since it is possible to change the configuration so that different materials or different shapes and shapes, it is natural to belong to the scope of the present invention.

Hydrogen body fabrication techniques deformed and configured so as to exhibit the functions suggested by the present invention can be exhibited even if the shape and shape are not the same, it is natural that the functions proposed by the present invention fall within the scope of the present invention. . In addition, it is natural that civil engineering works related to the present invention also fall within the scope of the present invention.

According to the present invention, since a cylinder for opening and closing the water main body is provided with a sealed space at both sides of the body of the water body, greatly reducing the risk of failure of the cylinder due to impurities such as a few seconds, the opening and closing of the water body without any problems. It can be performed easily and durable.

In addition, through the siphon drainage passage formed in the hydrologic main body, it is configured to discharge as much as the inflow water from the upstream of the stream. Therefore, it is possible to discharge the pollutants deposited in the water on the reservoir side even when the hydrologic main body is closed. Can work.

In addition, when the hydrologic main body is opened, fish to move upstream can easily move upstream of the river by relying on the fins on the hydraulic guide plate and the fish moving guide string formed at the lower part of the hydrological main body, the upstream part of the apron and the downstream support structure. There is a significant working effect to restore the river ecosystem by the existing work.

In addition, there is a significant working effect that can keep the top of the hydrologic body always clean by easily removing the floating substances floating upstream of the river during the flood.

Claims (4)

delete delete In the rain or flood, the floating material removing plate 34 is provided to remove the suspended substances flowing from the upstream of the stream at the upper end of the hydrologic main body 1 by the hinge 37 having elasticity. The upper part of the main body 1 is composed of a semicircular U-shaped coupling, A cylinder chamber 39 is formed at the center of the sluice main body 1, and a cylinder 38 and a cylinder rod 36 are formed at the cylinder chamber 39, and a roller is formed at the end of the cylinder rod 36. 35), The rear portion of the cylinder 38 is hinged to the cylinder chamber 39, and the cylinder 38 is connected to the pipe line to facilitate the removal of suspended solids, and by the role of the siphon passage Automated hydrologic main body configured to discharge influent without opening the main hydrologic body. In the hydrologic main body 1 comprised between the both side walls of a river, A circular pipe 59 is joined to the lower end of the upper skin plate 56 constituting the upper plate of the sluice main body 1, and the circular pipe 59 is horizontal to the circular pipe 59 in a reverse direction. To be bonded, In the middle of the upper skin plate 56, an intermediate frame 77 made of an H beam is joined to the upper skin plate 56, In the middle of the intermediate frame 77, the siphon passage 16 is perforated in a rectangular shape, and in the middle of the siphon passage 16, a reinforcing plate 58 is triangularly bonded to the intermediate frame 77. Become, The H beam 53 is bonded to the upper end of the upper skin plate 55, A horizontal frame made of a circular pipe 59 is joined to an upper end of the rear surface of the H beam 53, between the rear portion of the c-beam 53 and the space of the intermediate frame 77 and between the H beam 52. Between the horizontal frame 79 made of a plurality of H-beams in the longitudinal direction is inserted and bonded, The lower skin plate 55 made of steel is joined to the upper end of the c-shaped steel 53, the intermediate frame 77, and the H beam 52 and the horizontal frame 79. In the lower portion of the lower skin plate 55, the inlet water inlet 33 connected to the siphon passage 16 is perforated in a rectangular shape, and the upper skin plate constituting the rear portion of the hydrological main body 1. The inlet water outlet 44 is formed in a rectangular rectangular shape on the middle of the upper part to facilitate the removal of suspended solids, and the inlet water is discharged without opening the water main body by the role of the siphon passageway. Automated floodgate body configured to

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