KR101814386B1 - Fishway apparatus for a water reservoir dam in river - Google Patents

Abstract

The present invention relates to a fish ladder device installed on a dam in a river. The fish ladder device forms a fish ladder by forming a waterway on the dam in the river. The fish ladder device comprises: a fish ladder body formed with a corresponding length to be mounted on the waterway and partitioned by a plurality of spaced outer walls, wherein the fish ladder passes through the outer wall in a zigzag form; a first deceleration plate and a second deceleration plate spaced apart from each other at the rear and front sides of the fish ladder to reduce the flow velocity before and after passing through the fish ladder; and an angle adjustment unit installed in front of the second deceleration plate to adjust the angle of the second deceleration plate while converting a rotary motion into a linear reciprocating motion. The first deceleration plate has a plurality of through holes formed therethrough, and the second deceleration plate is formed in a cone shape divided vertically or horizontally. According to the present invention, by effectively reducing the flow velocity of water passing through the waterway of the dam formed in the river, a fish can easily move to the upstream or downstream side, thereby protecting the fish ecosystem of the river, and the flow velocity can be selectively adjusted for each position, thereby preventing green algae.

Description

[0001] The present invention relates to a waterway apparatus for a water reservoir,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fish-friendly device installed in a river beam, and more particularly, to a fish-friendly device for reducing the flow velocity of a small fish including a fish or the like to move upstream or downstream, .

In order to store water in a river and use it as agricultural water or industrial water, a variety of transversal structures crossing the bank and the bank of the river are usually installed.

The most common of the transverse structures is concrete, and the concrete view stores the water so that the water level of the water to be stored is always within a certain range, and the water gate is formed to control the water level at the time of flood or drought.

However, in the case of forming the beam with concrete, the downstream and upstream of the river are disconnected, making it difficult for the fishermen to ascend or descend to the upstream of the river, thus changing the habitat environment of various fisheries inhabiting the river.

Particularly, formation of a beam makes it impossible to move the fish returning for scattering from the downstream to the upstream, and in particular, the fishes including the fishes can not move on the steep slopes so that the fish ecosystem is destroyed have.

Due to the disadvantages described above, at least one water channel is formed in the beam during the process of forming the concrete beam, so that the fish can be moved by using the water.

However, when a water channel is formed in the river beam as described above, the flow rate of the water passing through the water channel is very fast, so that the small fish including the fish can not easily move to the upstream of the river, It still can not cope efficiently.

Korea Registered Utility Model No. 0427588 (Registered on September 22, 2006)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a fishing boat capable of basically reducing the flow rate of water passing through a water channel formed in a river beam, 2 is a perspective view showing a flow velocity reduction unit according to an embodiment of the present invention;

In order to achieve the above object, the present invention provides a waterproofing device for forming a waterway by forming a channel in a stream beam, the waterproofing device being formed to have a length corresponding to the waterway, A body formed in a zigzag form through the outer wall, A first reduction plate and a second reduction plate spaced apart from each other at the rear side and the front side so as to reduce the flow velocity before and after passage of the airflow; And an angle adjusting unit installed in front of the second reduction plate to adjust the angle between the second reduction plate while converting the rotational motion into a linear reciprocating motion, wherein the first reduction plate has a plurality of through holes formed therein And the second reduction plate may be formed in a cone shape that is divided into upper and lower parts or left and right parts.

The angle regulating unit may include: a rotation bracket rotatably extending on a front surface of each of the second reduction plates; First and second helical shafts which are helically fastened to the respective rotating brackets and whose both sides are formed in opposite directions; And second and third helical axes, wherein the first helical axis and the second helical axis are helically connected to each other, and when the helical direction is opposite to the first and second helical axes, And at the same time, a rotating member moving in the inward or outward direction.

An auxiliary reduction plate is rotatably connected to an edge of the second reduction plate, and an elastic member may be provided at a rotation portion so that the auxiliary reduction plate is constantly rotated in the opposite direction of the flow velocity.

According to the present invention, it is possible to effectively protect the fish ecosystem of the river by allowing the fish to easily move upstream or downstream by effectively reducing the flow rate of water passing through the water channel of the river formed in the river, Thereby contributing to prevention of algae.

Fig. 1 is a plan view showing a state in which a fishing device installed in a stream beam according to the present invention is installed in a water channel of a beam.
Fig. 2 is a side view of a fishing boat device installed in a stream beam according to the present invention.
FIG. 3 is an enlarged view showing a flow velocity reduction unit in a waterfall apparatus installed in a stream beam according to the present invention.
FIG. 4 is a front view showing a flow velocity reducing part and an angle adjusting part in a waterproofing device installed in a stream beam according to the present invention. FIG.
5 is an enlarged view showing an operating state of a flow velocity reduction unit in a waterproofing apparatus installed in a stream beam according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Like parts are designated with like reference numerals throughout the specification.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings in which: FIG. 1 is a plan view showing a state in which a water- FIG. 3 is an enlarged view showing a flow rate reduction unit in a waterfall apparatus installed in a river beam according to the present invention, and FIG. 4 is a cross- And FIG. 5 is an enlarged view showing an operation state of the flow velocity reduction unit in the waterproofing apparatus installed in the stream beam according to the present invention.

According to the drawings, the apparatus 100 installed in a stream beam according to the present invention includes a body 110, a flow rate reduction unit 120, and an angle adjustment unit 130, 1, which reduces the flow rate of water passing through the water channel 11.

The body 110 is formed in a corresponding length so as to be mounted on the water channel 11 and is divided through a plurality of spaced outer walls, and a plurality of outer walls are connected to each other through the side plates 112 at both ends And an insertion protrusion 114 protruding outwardly from the side plate 112 are formed, and a plurality of IDTs 116 are formed in a zigzag form through each outer wall.

The insertion protrusions 114 are inserted into the guide grooves 12 formed in both side walls of the water channel 11 so that the insertion protrusions 114 formed in the side plate 112 of the body 110 are inserted into the water channel 11, The body 110 is mounted.

At this time, the island 116 is formed to have a zigzag shape, which is intended to more effectively reduce the flow rate of water. That is, since the first water passes through the island 116 formed on the outer wall of the body 110 and then passes through the island 116 formed on the second outer wall, the residence time is long and the flow velocity is effectively reduced.

Further, it is preferable that at least two outer walls of the body 110 are formed so as to more effectively decelerate the flow rate of water, and the number of the outer walls can be appropriately adjusted as needed.

The insertion protrusions 114 are inserted into the guide grooves 12 formed inside the both side walls of the water channel 11 so that the waterproof device 100 of the present invention can be detachably fixed to the water channel 11, The replacement and installation work of the battery 100 is facilitated.

Further, the beam 1 is installed in a river in order to store water, and at least one water channel 11 is formed. The width and depth of the water channel 11 can be appropriately adjusted as needed.

And the fish 116 can be moved upstream by the water, which allows the small fish, including the fish, to move upstream or downstream.

Particularly, when the water level of the water is high due to the formation of the water bodies 116 on the body 110, the fish can move through the water bodies 116 formed on the upper and lower portions. When the water level is low, So that the fish can be moved through the water level to provide a floating water level 116 to the water level change.

The flow rate reduction unit 120 is spaced apart from the rear side and the front side of each of the air valves 116 of the body 110 to reduce the flow velocity before and after the air flow passes through the first reduction plate 121, A connecting member 124 and a second reduction plate 125.

The first reduction plate 121 is arranged at the rear of the island 116 and collides with the water descending from the upstream to primarily reduce the flow velocity. The water hit by the first reduction plate 121 is distributed to the outside And the flow velocity is reduced.

Meanwhile, since the first reduction plate 121 may be damaged if the first reduction plate 121 receives too large a resistance thereof, it is preferable to form a plurality of through holes 122 for the purpose of reducing the resistance applied to the first reduction plate 121 . In particular, it is further preferred that the through-hole 122 narrows the width of the inlet and increases the width of the outlet so that the flow rate of water passing through the through-hole 122 can be reduced.

The support plate 123 is disposed in front of the island 116 and water that has passed through the island 116 through the through hole 123a formed in the surface thereof is supplied in the direction of the island 116 in front.

The connecting member 124 is configured to connect the spaced-apart opposed surfaces of the first reduction plate 121 and the support plate 123. In this embodiment, a rivet or the like may be applied thereto.

The second reduction plate 125 is vertically or horizontally divided at the vertex of the support plate 123 and is connected to the front end by a hinge so as to be rotatable about the hinge.

At this time, the second reduction plate 125 is formed in a cone shape or the like when assembled.

The second reduction plate 125 is formed to secondarily reduce the flow rate of water that has passed through the first reduction plate 121 and the island 116. The water that has passed through the island 116 again reaches the second reduction rate And is distributed to the outside so that the flow velocity is decelerated.

At this time, in order to more effectively reduce the flow velocity of water hitting the second reduction plate 125, the shape of the second reduction plate 125 has an inner center protruded outward. When the shape of the second reduction plate 125 has a shape in which the inner center protrudes outward, if the water impinges on the second reduction plate 125, the flow can be more effectively reduced as it is refracted to the outside.

An auxiliary reduction plate 125a is rotatably connected to an edge of the second reduction plate 125 and a torsion spring elasticity is applied to the auxiliary reduction plate 125a so that the auxiliary reduction plate 125a always rotates in the opposite direction of the flow velocity. A member S is provided.

Here, one end of the elastic member S is supported by the second reduction plate 125, and the other end is supported by the auxiliary reduction plate 125a. In this way, the auxiliary reduction plate 125a is rotated toward the moving direction of the water by the water, and the flow of the auxiliary flow rate is supplementarily delayed.

In addition, the auxiliary reduction plate 125a may be partially padded to the second reduction plate 125, or may be provided to be padded on a plurality of areas.

In addition, the second reduction plate 125 is rotatably provided with a rotation bracket 125b at the top end thereof. At this time, when the nut N is coupled to the second reduction plate 125 (not shown) so that the rotation bracket 125b is spirally engaged with the outer end of the first spiral shaft 131 and the second spiral shaft 132 of the angle adjusting unit 130 As shown in Fig.

Here, the nut N is fixed to both inner walls of the square hole of the second reduction plate 125 through the hinge so that the nut N is rotated at an angle corresponding to the angle of the second reduction plate 125.

The angle adjusting unit 130 is disposed in front of the second reduction plate 125 to adjust the angle of the second reduction plate 125 while converting the rotational motion into a linear reciprocating motion, A second helical axis 132 and a rotatable member 133.

The first spiral shaft 131 is fixed to the rotation bracket 125b of the one second side reduction plate 125 whose outer end is divided and the inner end of the first spiral shaft 131 is screwed into one side of the rotary member 133.

The second spiral shaft 132 is fixed to the rotation bracket 125b of the other second reduction plate 125 whose outer end is divided and the inner end of the second spiral shaft 132 is screwed into the other side of the rotation member 133.

Here, the spiral direction of the first spiral shaft 131 and the second spiral shaft 132 are opposite to each other, and when the rotary member 133 is rotated in one direction, the first spiral shaft 131 and the second spiral shaft 132 simultaneously move inward or outward .

In this way, when the first spiral shaft 131 and the second spiral shaft 132 move inward, the angles of the divided second reduction plates 125 are increased. On the other hand, when the first spiral shaft 131 and the second spiral shaft 132 move in the outward direction, 2 reduction plate 125 becomes smaller.

As a result, since the angle between the first and second helical splines 131 and 132 is adjusted by increasing the angle, the flow velocity is increased or the angle is decreased The flow rate can be made slower.

The rotary member 133 is coupled to the adjacent ends of the first spiral shaft 131 and the second spiral shaft 132 so that the spiral direction on both ends of the inner peripheral surface thereof is connected to the first spiral shaft 131 and the second spiral shaft 132 The first spiral shaft 131 and the second spiral shaft 132 are simultaneously moved in the inward direction or the outward direction.

In this way, the rotary member 133 converts the rotational motion into linear motion of the first spiral shaft 131 and the second spiral shaft 132 to adjust the angle between the divided two side reduction plates 125 .

Therefore, even if the water coming down from the upstream side of the fishing boat 100 installed on the river beam according to the present invention collides with the first reduction plate 121 of the flow velocity reduction part 120 formed on the first outer wall of the body 110, A part of the water that is hit in this process enters the air intake 116 through the through hole 122 formed in the first reduction plate 121 and part of the water enters the air intake 116 through the outside of the first reduction plate 121, The water that has passed through the water reducing valve 116 collides with the second reduction plate 125 and is distributed to the outside, so that the flow velocity is decelerated secondarily.

The above-mentioned operation occurs repeatedly in correspondence with the number of outer walls of the body 110, so that the flow rate of the water discharged downstream is effectively reduced. At this time, the water that has passed through the island 116 on the first outer wall of the body 110 moves to the opposite side as shown in FIG. 1 and then flows through the island 116 on the second outer wall, so that the flow velocity is reduced.

The first screw shaft 131 and the second screw shaft 132 which are threadedly coupled to the rotary member 133 can be rotated in the same direction as the first screw shaft 131 and the second screw shaft 132 when the rotational member 133 is rotated in any one direction, The angle of both the second reduction plate 125 is adjusted by the rotation bracket 125b fixed to the first spiral shaft 131 and the second spiral shaft 132 while being rotated in either one of the inside or outside direction uniformly .

On the other hand, the small fish including the fry may enter the fish body 116 through the outside of the second reduction plate 125 of the fish body 116 on the first outer wall of the body 110, The fingers again pass through the outside of the first reduction plate 121, and this process is repeated several times to move upstream in the downstream direction. At this time, the flow rate of the water is very slow, so that the fish can be effectively moved upstream or downstream.

Particularly, in the apparatus 100 installed in the river beam according to the present invention, a plurality of fishes 116 are formed in the longitudinal direction of one side of the body 110. Accordingly, when the water level is high, 116, and when the water level is low, the fish can move through the lower island 116, so that fishes can select and move the fish 116 according to the water level change.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. This is possible.

Therefore, the scope of the present invention should not be limited by the described embodiments, but should be determined by the equivalents of the appended claims, as well as the appended claims.

1: beam 11: channel
12: guide groove 100:
110: body 112: side plate
114: insertion protrusion 116:
120: flow rate reduction unit 121: first reduction plate
122: through hole 123:
124: connecting member 125: second reduction plate
130: angle adjusting unit 131, 132: first and second helical shafts
133: Rotating member

Claims (3)

In a fishing device for constructing an island by forming a channel in a river beam,
A body formed by a plurality of spaced outer walls formed in corresponding lengths so as to be mounted on the water channel, the outer walls being formed in a staggered shape in a zigzag manner;
A first reduction plate and a second reduction plate spaced apart from each other at the rear side and the front side so as to reduce the flow velocity before and after passage of the airflow; And
And an angle adjusting unit installed at the front of the second reduction plate to adjust the angle of the second reduction plate while converting the rotational motion into a linear reciprocating motion,
Wherein the first reduction plate has a plurality of through holes formed therethrough,
The second reduction plate is formed in a cone shape divided into upper and lower parts or left and right parts,
Wherein the angle adjusting portion includes: a rotation bracket rotatably extending on a front surface of each of the second reduction plates; First and second helical shafts which are helically fastened to the respective rotating brackets and whose both sides are formed in opposite directions; And second and third helical axes, wherein the first helical axis and the second helical axis are helically connected to each other, and when the helical direction is opposite to the first and second helical axes, And a rotary member that moves in the inner direction or the outer direction at the same time.
delete The method according to claim 1,
Wherein the second decelerator plate is rotatably connected to an edge of the auxiliary decelerator plate so that the auxiliary decelerator plate is rotatably rotated in the direction opposite to the flow velocity.

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