KR101395667B1 - Apparatus for reducing debris flow - Google Patents

Abstract

The present invention relates to a device for reducing debris flow. In accordance with an embodiment of the present invention, the device for reducing debris flow includes a debris flow blocking unit including a first position which is parallel to the ground and a second position which crosses the ground, and a driving unit changing the position of the debris flow blocking unit due to a flow of water. When the debris flow blocking unit is at the first position, the driving unit includes a first plate which is inclined from the ground, and a second plate which is parallel to the ground.

Description

{APPARATUS FOR REDUCING DEBRIS FLOW}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a de-stones flow reduction apparatus, and more particularly, to a de-stones flow reduction apparatus having a simple structure.

When the flow rate suddenly flowed in the valleys due to heavy rainfall, it was mixed with water and the soil rocks were generated, and the driftwoods and landslides were moved to the residential areas, causing severe damage to people and property damage.

In order to prevent this, a square dam, a slit, an elastic wiper net and the like can be installed in the area where the earth stone can be generated. However, squatting dam, slit, and elastic wiper net can be exposed to the outside, which can hinder the landscape. In addition, it takes a great deal of time to install the dam, and once it is installed, demolition, replacement, and repair are not easy.

The present invention provides a soil erosion reduction apparatus that can minimize damage to human life and property that may occur when the flow rate is increased without harming the landscape.

The present invention provides a de-stone flow reduction apparatus comprising: a de-stoker flow blocking section capable of changing its position to a first position parallel to the ground or to a second position crossing the ground; And
A driving unit for changing the position of the above-mentioned undulation block by the flow of water;
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The driving unit includes:
And a second plate positioned parallel to the ground when the unstock flow blocking portion is in the first position, the first plate being inclined with respect to the ground.

Wherein the second plate is positioned obliquely to the ground and the second plate is lifted up by the flow of water when the first plate is lifted up by the flow of water in the first position, Location.

When the soil block interceptor is in the second position, the first plate may be inclined with the ground, and the second plate may be perpendicular to the ground.

Further comprising a body portion including a first portion fixed to the ground and a second portion rotatably fixed on one side of the first portion and opened or closed on the other side of the first portion, The driving unit can be fixed.

The first plate may be located on one side of the second portion adjacent to the first portion and the second plate may be on the other side of the second portion.

The first plate may be inclined so that the distance from the first portion to the fixed portion of the second portion becomes larger as the distance from the second portion becomes closer to the fixed portion of the first portion and the second portion.

The angle formed between the first plate and the second portion may be between 1 and 89 degrees.

The fixed position of the first plate and the second portion may be located farther from the fixed portion of the first portion and the second portion than the fixed position of the second plate and the second portion.

And a first opening angle control member that connects the first portion and the second portion and controls an opening angle between the first portion and the second portion when the second portion is in the second position. The first opening angle control member may be formed of a wire.

And a second open angle control member for controlling an open angle between the first portion and the second portion when the second portion is in the second position may be formed in the first portion. The second open angle control member may have a shape that receives the second portion.

A floating member driven by buoyancy may be located in the second portion.

A long path portion is formed on a side surface of the second portion, and the floating member can be movably positioned in the path portion.

And a closing buffer member located between the first portion and the second portion and mitigating an impact when the soil erosion reducing portion moves from the second position to the first position. The closing buffer member may include an elastic member or a hydraulic member.

And a concrete member having a protrusion protruding upwardly to the ground. A through hole is formed in the first portion, and the first portion can be detachably fixed on the ground by inserting the protrusion into the through hole.

Each of the first plate and the second plate may have a plurality of guide holes through which the water flows.

The above-mentioned undulation block may have a lattice shape.

The soil erosion reducing apparatus according to the present embodiment is automatically closed when the amount of water increases (for example, heavy rain) and is contained in water when the water does not flow or the amount of water is small, It is possible to automatically shut off the floating debris. Thus, damage that may occur in increasing the flow rate can be minimized. And it is opened only when necessary, and is closed in the normal state, so that it is possible to prevent the landscape from being hindered by the depressurization device during normal operation. In addition, it can be manufactured at low cost and can be installed simply as compared with a concrete square dam or other blocking structure. And can be manufactured by adjusting the size in consideration of the site conditions such as the installation place. Further, when the flow rate is small as in winter, other structures of the soil erosion reducing apparatus can be separated and stored from the concrete member, and can be reinstalled only when the flow rate is large as in the summer.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view of a de-stone flow reduction apparatus according to an embodiment of the present invention, showing a case where the de-stalk flow blocking section is located at a first position; Fig.
Fig. 2 is a perspective view of the de-stones flow reduction apparatus of Fig. 1, showing a case where the de-stalk flow blocking section is located at the second position. Fig.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, it is needless to say that the present invention is not limited to these embodiments and can be modified into various forms.

In the drawings, the same reference numerals are used for the same or similar parts throughout the specification. In the drawings, the thickness, the width, and the like are enlarged or reduced in order to make the description more clear, and the thickness, width, etc. of the present invention are not limited to those shown in the drawings.

Wherever certain parts of the specification are referred to as "comprising ", the description does not exclude other parts and may include other parts, unless specifically stated otherwise. Also, when a portion of a layer, film, region, plate, or the like is referred to as being "on" another portion, it also includes the case where another portion is located in the middle as well as the other portion. When a portion of a layer, film, region, plate, or the like is referred to as being "directly on" another portion, it means that no other portion is located in the middle.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view of a de-stone flow reduction apparatus according to an embodiment of the present invention, showing a case where the de-stalk flow blocking section is located at a first position; Fig. And Fig. 2 is a perspective view of the de-stones flow reduction apparatus of Fig. 1, showing a case where the de-stalk flow blocking section is located at the second position.

Referring to Figs. 1 and 2, a debris removal apparatus 100 includes a debris flow blocking section 10 having a first position parallel to the paper surface and a second position intersecting with the paper surface (for example, orthogonal to the paper surface) And a driving unit 20 for changing the position of the debris blocking unit 10 by the flow of water. The main body 30 is fixed to the floor and the debris flow blocking portion 10 and the driving portion 20 are fixed to the main body 30. A concrete member 30 for fixing the main body 30 to the ground 40). In addition, the first and second opening angle control members 30c and 30f, the closing buffer member 50, and the floating member 60 may be further included. This will be explained in more detail.

The concrete member 40 is fixed to the ground so that the main body portion 30 can be detachably fixed to the ground. More specifically, the concrete member 40 may include a proximal portion 40a, a portion of which is located below the ground and is firmly fixed to the ground, and a protrusion 40b that protrudes upward from the proximal portion 40a. The protruding portion 40b is a portion for fastening and fixing with the body portion 30 and is a portion for maintaining the parallelism between the first portion 30a and the second portion 30b at the first position. The concrete structure of the concrete member 40 and the main body 30 will be described in detail after the main body 30 is described.

When the concrete member 40 is provided as described above, the main body 30 can be detachably fixed on the ground, and when there is no need for a large amount as in winter, the soil erosion reducing apparatus 100 except for the concrete member 40 is removed . In addition, replacement or reassembly can be easily performed when a failure occurs in some parts.

The main body portion 30 includes a first portion 30a fixed to the ground surface (more precisely, the concrete member 40) and a first portion 30a fixed to the first portion 30a so as to be rotatable on one side thereof, And a second portion 30b, which may be substantially rectangular. The open angle between the first portion 30a and the second portion 30b can be changed by lifting the other side of the second portion 30b while the first portion 30a is fixed .

In the second portion 30b, the unintentional blocking portion 10 and the driving portion 20 are fixed. The debris flow block 10 blocks the flow of debris and the drive part 20 lifts the other part of the second part 30b when the flow of water changes the position of the flow blocker 10. This will be described in detail after explaining the undistorted blocking portion 10 and the driving portion 20.

The first portion 30a may include two side portions 301a constituting both sides and a connecting portion 302a connecting them. As described above, the first portion 30a is formed to have an integral structure by the two side portions 301a and the connecting portion 302a, thereby reducing the number of parts and simplifying the manufacturing process.

The side portion 301a of the first portion 30a may be provided with a fixing portion 30c on which the fixing portion 30d for rotatably fixing the second portion 30b is located. The fixing portion 30c can function as a first opening angle control member for controlling the opening angle between the first portion 30a and the second portion 30b in a state in which the second portion 30b is lifted. This will be described in more detail later. In this way, the fixing portion 30c functions as the first opening angle control member, thereby simplifying the structure, and also allowing the second portion 30b to have a constant opening angle in the lifted state.

At this time, the fixing portion 30c may have a shape to receive the second portion 30b in a state in which the second portion 30b is lifted. For example, when the side portion 301b constituting the second portion 30b has a bar shape having a rectangular cross section, the flat shape of the fixing portion 30c may have a "C" shape. This allows the second portion 30b to be kept more stable in its lifted state. However, the present invention is not limited thereto, and the first opening angle control member may have various structures and shapes.

The first portion 30a is formed with a through hole 30e through which the protrusion 40b is inserted. The first portion 30a can be detachably fixed on the ground surface (more specifically, the concrete member 40 fixed to the ground) by inserting the projection portion 40b into the through hole 30e. The first portion 30a can be detachably fixed on the ground by a simple structure in which the through hole 30e is formed in the first portion 30a. Although the structure using the protrusion 40b and the through hole 30e is applied in the present embodiment, the present invention is not limited thereto. Accordingly, various structures, methods, and the like can be applied to fix the main body 30 and the concrete member 40. [

The second portion 30b may include two side portions 301b constituting both sides. The side portions 301b of the second portion 30b may be rotatably fixed to the side portions 301a of the first portion 30a, respectively. And a connecting portion 302b connecting the two side portions 301b of the second portion 30b. At this time, the connecting portion 302b of the second portion 30b may be formed of a metal material having a rod shape. However, the present invention is not limited thereto, and the side portion 301b and the connecting portion 302b of the second portion 30b may have various shapes.

The second portion 30b moves from the second position to the first position between the connecting portion 302a of the first portion 30a and the connecting portion 302b of the second portion 30b while the first portion 30a A closing buffering member 50 may be located to mitigate the impact when it comes close. The closing buffer member 50 may be connected to the connection portions 302a and 302b to apply various configurations to mitigate the impact. For example, as the closing buffer member 50, an elastic member such as a spring or a hydraulic member such as a cylinder may be used. The use of the elastic member as the closing buffer member 50 can simplify the structure, and the use of the hydraulic member can continuously maintain the effect of the shock reduction even in repeated use. Other various structures and methods of the closing buffer member 50 may be used. In the drawing, for example, five closing damping members 50 are illustrated. However, the present invention is not limited thereto, and the number of the closing buffer members 50 and the like can be variously modified.

The first portion 30a and the second portion 30b are connected to the side portion 301a of the first portion 30a and the side portion 301b of the second portion 30b to connect the second portion 30b with the second portion 30b, And a second opening angle control member 30f for controlling the opening angle between the first portion 30a and the second portion 30b when the first portion 30a is at the second position. The second opening angle control member 30f may be formed of a wire. That is, the second opening angle control member 30f has a length that can be pulled out when the second portion 30b and the unintentional elimination portion 10 are in the second position, and the second portion 30b has a predetermined opening angle or more Can be prevented.

As described above, the main body 30 including the first portion 30a and the second portion 30b stably fixes the debris flow reduction apparatus 100 on the ground, 10 and the driving unit 20 are stably fixed, the position of the soil blocker 10 can be changed by the flow of water. That is, various portions of the soil erosion reducing apparatus 100 may be coupled together and fixed to the ground, so that desired operation can be performed by the flow of water.

The debris flow blocking portion 10 fixed between the two side portions 301b of the second portion 30b is formed in a lattice shape so as to allow water to flow into the inside of the debris flow passage and to prevent the flow of debris such as debris Various substances). However, the present invention is not limited thereto and may have various shapes.

The driving part 20 fixed to the second part 30b and changing the position of the screen blocking part 10 may include a first plate 20a and a second plate 20b.

The first plate 20a is positioned adjacent to the first portion 30a in the second portion 30b, and water reaches first when the water flows. The first plate 20a may be provided with a plurality of guide holes 201a which are sloped in the second portion 30b and through which water can flow.

More specifically, one side (i.e., upper side) of the first plate 20a away from the fixed portion 30c of the first portion 30a and the second portion 30b is fixed to the second portion 30b The first plate 20a can be inclined to be away from the second portion 30b as the first plate 30a and the fixing portion of the second portion 30b are closer to each other. At this time, the fixing position of the first plate 20a and the second portion 30b (i.e., the upper position of the second plate 20b) is shifted from the fixed position of the second plate 20b and the second portion 30b 1 portion 30a and the fixed portion 30c of the second portion 30b. And the vertical length of the first plate 20a may be longer than the vertical length of the second plate 20b. This is to allow the first plate 20a, in which water first arrives, to effectively receive the force of water and to be easily pushed up. For example, the angle A between the first plate 20a and the second portion 30b may be between 1 and 89 degrees. The angle A may be between 10 degrees and 70 degrees (e.g., between 15 degrees and 45 degrees) in order to more effectively transmit the force by water.

The guide hole 201a may have various structures in which water can flow. In the drawing, for example, the guide holes 201a are arranged to have a plurality of rows and columns with a circular shape, but the present invention is not limited thereto. It goes without saying that various modifications are possible.

Since the first plate 20a and the second portion 30b are inclined as described above, the first plate 20a is positioned at an oblique position with respect to the ground when the debris blocking portion 10 is in the first position. At this time, the angle formed between the first plate 20a and the paper corresponds to the angle A between the first plate 20a and the second portion 30b. As a result, the angle formed by the first plate 20a and the paper surface when the water flows over the paper surface has the same or similar value as the angle A. At this time, when water flows into the portion that can be opened in the first portion 30a and the second portion 30b, water flows through the guide hole 201a of the first plate 20a. Then, in the portion where the guide hole 201a is not formed, the force of the water pushing up the first plate 20a is provided to the first plate 20a.

At this time, since the first plate 20a is inclined with respect to water, a force for pushing up the first plate 20a can be effectively provided to the first plate 20a. If the angle A formed by the first plate 20a and the second portion 30b is less than 1 degree, the angle between the water and the first plate 20a is reduced to push up the first plate 20a It may be difficult to provide power effectively with water. When the angle A formed by the first plate 20a and the second portion 30b exceeds 89 degrees, the thickness or the volume of the undecorated soil reducing apparatus 100 becomes large when the undecorated soil reducing apparatus 100 does not operate . More specifically, when the angle A is in the range of 10 degrees to 70 degrees (for example, 15 degrees to 45 degrees), the force by water can be transmitted more effectively.

And the first plate 20a may be positioned at an oblique position with respect to the ground when the soil block interceptor 10 is in the second position. At this time, the angle between the first plate 20a and the paper surface may be a value obtained by subtracting the angle A from 90 degrees.

The second plate 20b located on the other side of the second portion 30b is positioned parallel to the second portion 30b and the second plate 20b is provided with a plurality of guide holes 201b through which water can flow Can be located. The guide hole 201b may have various structures in which water can flow. In the drawing, for example, the guide hole 201b has a circular shape and is arranged to have a plurality of rows and columns, but the present invention is not limited thereto. It goes without saying that various modifications are possible.

The second plate 20b may be positioned parallel to the ground at the first position and the second plate 20b may be positioned at an angle to the ground between the first position and the second position. In the second position, the second plate 20b can be positioned perpendicular to the paper surface. As described above, when the first plate 20a begins to be pushed up by the water, the second portion 30b is pushed up and the second plate 20b parallel to the second portion 30b is positioned obliquely with the water . Then, the water pushes up the second portion 30b as well as the first plate 20a as well as the second plate 20b together. Finally, when the second portion 30b reaches the limit of the first and second opening angle control members 30c and 30f, the second portion 30b is fixed at the second position. As an example, in this embodiment, the second portion 30b and the second location of the unstick block portion 10 fixed thereto may be positioned perpendicular to the ground. At this position, the debris blocking portion 10 can effectively block the blocking portion and the damage of the debris blocking portion 10 can be minimized. Whereby the second plate 20b, in which the second portion 30b is parallel, can be perpendicular to the ground at the second position.

The second portion 30b may be provided with a floating member 60 driven by buoyancy. Thus, even when a small amount of water reaches the first plate 20a and pushes up the first plate 20b, the second portion 30b can be easily lifted up. The floating member 60 may be a member of a variety of structures and systems of low density (for example, a ball in which air is located). As described above, in this embodiment, the force for lifting the second portion 30b by the floating member 60 can be effectively provided to the second portion 30b.

At this time, a long path portion 20c is formed in the side portion 301b of the second portion 30b, and the floating member 60 can be movably positioned in the path portion 20c. Then, the floating member 60 moves along the path portion 20c according to the flow rate, so that the force for lifting the second portion 30b can be more effectively provided to the second portion 30b.

The operation of the devastator reduction apparatus 100 of the above-described structure will be described in more detail with reference to FIGS. 1 and 2. FIG.

In the case where water does not flow or a small amount of water flows, the first portion 30a and the second portion 30b are kept closed as shown in Fig. That is, the second portion 30b is positioned on the projection 40b and is in parallel with the ground and the first portion 30a. Then, the first plate 20a is positioned at an angle (A) with the ground and the second plate 20b is positioned parallel to the ground.

When the amount of water is increased by concentrated rain or the like, water first reaches the first plate 20a and pushes the first plate 20a while passing through the guide hole 201a of the first plate 20a. At this time, the buoyant force of the floating member 60 causes the second portion 30b to be lifted up more easily. The second plate 20b is inclined with respect to the ground so that the water reaches the second plate 20b and pushes the second plate 20b while passing through the guide hole 201 of the second plate 20b. As a result, the second portion 30b is completely lifted up by the upward force of the second plate 20b.

Then, as shown in Fig. 2, the second portion 30b stably maintains the state of being perpendicular to the paper surface by the first and second opening angle control members 30c and 30f. At this time, the first plate 20a is positioned obliquely to the ground and the second plate 20b is positioned perpendicular to the ground. In this state, the earth-and-stone blocking portion 10 blocks the earth rocks such as driftwood, earth and stone, which are mixed with water while passing water. As a result, the debris flow is blocked in the debris flow blocking portion 10.

When the heavy rocks and the like are removed and the amount of water is reduced again, the soil stone suspended in the soil stone blocking portion 10 is removed. Then, the weight of the second portion 30b and the soil stone blocking portion 10 and the driving portion 20 The second portion 30b is gradually lowered toward the first portion 30a. At this time, the second portion 30b is gradually lowered and stably stood on the protruding portion 40b by the closing buffering member 50 located between the first portion 30a and the second portion 30b.

According to the soil erosion-reducing apparatus 100 according to the present embodiment, when the water does not flow or the amount of water is small, it is closed, and when the amount of water increases to such an extent that the soil is generated It can be automatically shut off when it is opened and contained in the water and the floating stone, the nomad, and the garbage. Thus, damage that may occur in increasing the flow rate can be minimized. Since it is opened only when necessary and closed in the normal state, it is possible to prevent the landslide from being hindered by the devitrification system 100 during normal operation. In addition, it can be manufactured at low cost and can be installed simply as compared with a concrete square dam or other blocking structure. And can be manufactured by adjusting the size in consideration of the site conditions such as the installation place. When the flow rate is small as in the winter season, the other components of the soil erosion reducing apparatus 100 are separated and stored from the concrete member 40, and can be reinstalled only when the flow rate is large as in the summer.

Features, structures, effects and the like according to the above-described embodiments are included in at least one embodiment of the present invention, and the present invention is not limited to only one embodiment. Further, the features, structures, effects, and the like illustrated in the embodiments may be combined or modified in other embodiments by those skilled in the art to which the embodiments belong. Therefore, it should be understood that the present invention is not limited to these combinations and modifications.

100: Debris removal system
10:
20:
30:

Claims (10)

A landing block capable of changing its position to a first position parallel to the ground or to a second position intersecting with the ground; And
A driving unit for changing the position of the above-mentioned undulation block by the flow of water;
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The driving unit includes:
And a second plate positioned in parallel with the ground when the unsticky flow blocking portion is in the first position, the first plate being inclined with respect to the ground. The method according to claim 1,
Wherein the second plate is positioned obliquely to the ground and the second plate is lifted up by the flow of water when the first plate is lifted up by the flow of water in the first position, A landing stone abatement device moving to a location. 3. The method of claim 2,
Wherein the first plate is inclined with respect to the ground and the second plate is perpendicular to the ground when the undecomposed block portion is in the second position. The method of claim 3,
Further comprising a main body portion including a first portion fixed to the ground and a second portion rotatably fixed on one side of the first portion and opened or closed on the other side,
And the debris flow blocking portion and the driving portion are fixed to the second portion. 5. The method of claim 4,
Wherein the first plate is located on one side of the second portion adjacent to the first portion,
And the second plate is located on the other surface of the second portion. 5. The method of claim 4,
Wherein the first plate is inclined so that a distance between the first portion and the second portion becomes greater as the first portion and the second portion become closer to each other. 5. The method of claim 4,
And a floating member driven by buoyancy is located in the second portion. 8. The method of claim 7,
A long path portion is formed on a side surface of the second portion,
Wherein the floating member is movably positioned in the path portion. 9. The method of claim 8,
Further comprising a closing buffer member located between the first portion and the second portion and mitigating the impact when the soil erosion reducing portion moves from the second position to the first position. 10. The method of claim 9,
Further comprising: a concrete member having a projection protruding upward,
Wherein a through hole is formed in the first portion and the first portion is detachably fixed on the ground by inserting the protrusion into the through hole.

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