KR200465849Y1 - Generator apparatus using discharge water - Google Patents

Abstract

The present invention is to solve the above problems, it is an object of the present invention to provide a power generation device using the discharge water to prevent the adverse effects on the surrounding facilities by allowing the discharged water to be discharged to another place.
In order to achieve the above object, the generator using the discharged water of the present invention includes a waterproof passage structure provided with a flow path through which the discharged water flows; A rotating body rotatably mounted to the waterproof path structure, the lower end of which is inserted into the flow path and rotated by a flow of discharge water passing through the flow path; A rotating shaft for mounting the rotating body to the waterproof path structure and rotating together with the rotating body; Is mounted to the waterproof path structure, and comprises a power generation unit for producing electricity by using the rotational force of the rotary shaft, the waterproof path structure, the front and rear and the upward direction is provided with the flow passage through which the discharge water flows inside A structure; A second structure formed at a side of the first structure, the power generation unit mounted at an upper portion thereof, a front structure of the first structure being closed, and a free passage open to the rear of the first structure; It is made, including the first structure is formed in the front of the rotating body and the through portion is formed in the open side in the direction of the second structure on the side, the second structure is opened in the upward direction the through portion and the free passage An opening is formed which communicates with.

Description

Power generator using discharged water {Generator apparatus using discharge water}

The present invention relates to a generator using discharged water, and more particularly to a generator using discharged water to produce electricity by using a force rotating by the flow of discharged water.

The effluents of seawater farms that raise seawater to land are naturally discharged through open-type concrete-type open waterways with a constant gradient.

Recently, various hydrophobic power generation apparatuses capable of producing electricity by using the discharged water that is naturally discharged have been developed.

As shown in FIG. 1, the hydrophobic power generation apparatus using effluent water includes concrete beams 30 installed in a waterway in a direction of suppressing flowing effluent water 10, and embedded in the concrete beams 30 to be discharged water 10. Induction pipe line 100 is installed to pass through, the induction pipe line 100 is coupled to penetrate through the duct flange protruding from both sides and embedded in the concrete beam 30, the interior divided through the plate 210 A protective housing 200 having a space and a duct 330 which is installed under the diaphragm of the protective housing 200 and couples a duct flange to the induction pipe 100 so that the discharge water 10 can be introduced and discharged. Rotation of the aberration 310 in the interior of the hydrophobic power generator 300 having a power generation proportional to the flow rate of the discharge water 10 flowing from the induction pipe 100 is made.

However, in the conventional hydrophobic power generator as described above, when the hydrophobic power generator 300 is stopped due to a failure, the induction pipe 100 is partially blocked, so that the flow of the flowing water is not smooth, and the discharge water overflows from the concrete beam. There is a problem that adversely affects seawater farm facilities.

The present invention is to solve the above problems, it is an object of the present invention to provide a power generation device using the discharge water to prevent the adverse effects on the surrounding facilities by allowing the discharged water to be discharged to another place.

In order to achieve the above object, the generator using the discharged water of the present invention includes a waterproof passage structure provided with a flow path through which the discharged water flows; A rotating body rotatably mounted to the waterproof path structure, the lower end of which is inserted into the flow path and rotates by a flow of discharge water passing through the flow path; A rotating shaft for mounting the rotating body to the waterproof path structure and rotating together with the rotating body; It is mounted to the waterproof path structure, and comprises a power generation unit for producing electricity by using the rotational force of the rotary shaft, the waterproof path structure, the front and rear and the upward direction is provided with the flow passage through which the discharge water flows inside A structure; A second structure formed at a side of the first structure, the power generation unit mounted at an upper portion thereof, a front structure of the first structure being closed, and a free passage open to the rear of the first structure; It is made, including the first structure is formed in the front of the rotating body and the through portion is formed in the open side in the direction of the second structure on the side, the second structure is opened in the upward direction the through portion and the free passage An opening is formed which communicates with.

The height of the penetrating portion is lower than the height of the rotating shaft and disposed higher than the lower end of the rotating body.

The first structure may include a first bottom surface forming a bottom of the flow path; A first side surface protruding upwardly at both ends of the first bottom surface to form the flow path, and having the through portion formed therein; And a second bottom surface protruding from the lower end of the first side surface in a direction opposite to the flow path to form a bottom of the channel; A second upper surface disposed on an upper portion of the second bottom surface, protruding from the first side in the opposite direction to the flow path to form an upper portion of the channel, and having the opening formed thereon; A second side surface protruding upward from one end of the second bottom surface opposite to the first side surface to connect the second bottom surface and the second top surface, and to form the channel; It is made, including, the height of the second bottom is lower than the height of the first bottom.

The power generation unit is mounted on an upper portion of the second upper surface, and the height of the first side surface is higher than the height of the second upper surface.

The second upper surface is formed with a drain hole communicating with the channel.

The first bottom surface is formed with a flow guide jaw disposed in front of the rotor to guide the flow direction of the discharge water in the circumferential direction of the rotor.

The rotating body is fixed to the rotating shaft and the central portion to rotate with the rotating shaft; Support plates respectively formed on both sides of the central portion; Wing portions protruded outwardly along the outer circumferential surface of the central portion between the support plates; It comprises, but the wing portion is formed convex in the rotational direction of the center, the flow guide jaw is formed concave to correspond to the shape of the outer circumferential surface of the support plate adjacent to one surface located in the rotating body direction, Adjacent other surfaces are formed convexly.

A lift mounted to an upper portion of the second upper surface to vertically flow the power generation unit; It further comprises.

A fixed frame mounted on the lift to flow up and down; It further comprises, the rotating shaft and the power generation portion is disposed on the upper portion of the fixing frame flows up and down together.

A water channel disposed in a front upper portion of the rotating body to drop discharged water toward the rotating body; It further comprises a, the water pipe is disposed on the upper surface of the flow guide chin.

As described above, the power generation apparatus using the discharged water of the present invention has the following effects.

By forming a penetrating portion in the direction of the second structure in the first structure, and forming the opening in the upward direction in the second structure, the surface of the discharge water flowing along the flow path so that the water level does not rise above a certain level of the rotating body Is stably rotated, the discharge of the effluent is made smoothly can be prevented from adversely affecting the facilities of the seawater farm.

The height of the first side surface is disposed higher than the height of the second upper surface, thereby minimizing the discharge water flowing in the flow path to the second upper surface to damage the power generation unit and the lift mounted on the second upper surface. prevent.

By forming a drain hole in communication with the channel in the second upper surface, the water accumulated in the second upper surface is discharged to the channel to prevent damage to the power generation unit and the lift mounted on the second upper surface.

The flow guide jaw is formed in the lower portion in front of the rotating body to guide the flow direction of the discharge water in the circumferential direction of the rotating body, thereby widening the contact area between the discharge water and the rotating body to increase the rotational force of the rotating body. have.

By arranging the height of the second bottom lower than the height of the first bottom, the depth of the channel is deeper than the depth of the flow path to prevent the discharged water flowing into the flow path to flow back to the flow path, The discharge water is effective to smoothly move in the direction of the free passage through the through part.

Since one surface of the flow guide jaw is formed in a concave arc shape corresponding to the shape of the outer circumferential surface of the support plate adjacent thereto, there is an effect of increasing the rotational force of the wing.

By mounting a lift to vertically flow the power generation unit on the upper portion of the second upper surface, the height of the power generation unit can be easily adjusted according to the level of the discharge water.

By combining the rotary shaft and the power generating unit on the upper portion of the fixing frame which is mounted to the lift and flows up and down, the rotary shaft and the power generating unit can be simultaneously moved up and down together, thereby making it easy to use and facilitating assembly.

By providing the water pipe in the rear upper part of the rotating body, there is an effect of further improving the rotational force of the rotating body by the drop of discharged water.

1 is a structural diagram of a hydroelectric generator according to the prior art,
2 is a plan view of a power generation apparatus using discharged water according to an embodiment of the present invention,
3 is a perspective view of the waterproof structure according to an embodiment of the present invention,
4 is a cross-sectional structural view as seen from AA of FIG.
5 is a cross-sectional structural view as seen from BB of FIG.
6 is a cross-sectional structural view as seen from CC of FIG.
7 is a cross-sectional structural view according to another embodiment of the present invention,

2 is a plan view of the power generation apparatus using the discharge water according to an embodiment of the present invention, Figure 3 is a perspective view of the waterproof structure according to an embodiment of the present invention, Figure 4 is a cross-sectional structural view as seen from AA of Figure 2, Figure 5 2 is a cross-sectional structural view as seen from BB, FIG. 6 is a cross-sectional structural view as seen from CC of FIG. 2, and FIG. 7 is a cross-sectional structural view according to another embodiment of the present invention.

2 to 6, the generator using the discharge water in accordance with an embodiment of the present invention is a waterproof path structure 100, the rotating body 200, the rotating shaft 300, the power generating unit 400, the lift 500 And a fixing frame 600.

The waterproof passage structure 100 is made of concrete, it is installed in the waterway discharged water (W).

The water channel is a place where the discharged water (W) flows back to the sea used in the seawater farm.

The waterproof passage structure 100 is provided with a flow passage 113 through which the discharge water W flows.

Specifically, the waterproof structure 100 is composed of a first structure 110 and a second structure (120).

The first structure 110 is formed in a rectangular shape and consists of a first bottom surface 111, a first side surface 112, and a flow passage 113.

The first bottom surface 111 is formed in a long rectangular shape in a moving direction of the discharge water W, ie, forward and backward, and forms a bottom of the flow passage 113.

The first bottom surface 111 is formed in front of the rotating body 200 to be described later to form a flow induction jaw (111a) to guide the flow of the discharge water (W) in the circumferential direction of the rotating body 200 do.

As shown in FIG. 5, the flow guide jaw 111a is formed in the first structure 110 constituting the bottom surface of the first bottom surface 111, that is, the flow passage 113, and protrudes upward. do.

In addition, as illustrated in FIG. 6, the flow guide jaw 111a is formed to be concave to correspond to the shape of the outer circumferential surface of the support plate 220 of the rotating body 200 in which one surface located in the direction of the rotating body 200 is adjacent. .

That is, one surface of the flow guide jaw 111a is mutually concentric with the wing 230 of the rotor 200 formed convexly in the rotational direction of the central portion 210 of the rotor 200 disposed adjacent to the upper portion of the flow guide jaw 111a. It is formed in an arc shape concave in the direction away.

In addition, the flow guide jaw 111a is formed such that one surface and the other surface adjacent to each other are convex upward.

In other words, the flow guide jaw 111a is formed in a concave arc shape as one surface is gradually lowered from the front to the rear of the flow passage 113, and the other surface is gradually increased toward the rear from the front of the flow passage 113. It is formed in convex arc shape.

The flow guide jaw 111a flows in the lower circumferential direction of the discharge water W when the discharge water W moves in the direction of the rotor 200 along the flow path 113. Induce.

As described above, the first structure 110 protrudes to surround the front lower end of the rotating body 200 to guide the flow direction of the discharge water W in the circumferential direction of the rotating body 200, thereby discharging the discharge water W ) Is concentrated in the tangential direction of the outer circumference of the wing portion 230 of the rotor 200, thereby increasing the rotational force of the rotor 200.

Further, by forming one surface of the flow guide jaw 111a into a concave arc shape and forming the other surface into a convex arc shape, preventing the discharge water W from flowing backward and smoothing the flow of the discharge water W. It works.

Meanwhile, the first side surface 112 is formed in a long rectangular shape in front and rear, and protrudes upward at both ends of the first bottom surface 111 to form the flow passage 113.

In addition, the first side 112 is formed with a through portion 112a opened in the direction of the second structure 120 to be described later.

The through part 112a is formed in a rectangular long hole shape as illustrated in FIGS. 4 and 5, and penetrates left and right so as to communicate with the flow passage 113 and the free passage 124 to be described later.

The through part 112a is disposed at the rear of the rotor 200, that is, at the front of the flow passage 113 with respect to the rotor 200.

In addition, the height of the through part (112a) is lower than the height of the rotating shaft 300 to be described later, it is disposed higher than the lower end of the rotating body (200).

The through part 112a discharges a surplus of the effluent water W to a free passage 124 to be described later when the water level of the effluent water flowing along the flow passage 113 becomes higher than a predetermined level, so that the water surface is constant. Do not exceed the water level.

That is, the penetrating part 112a discharges the discharge water W into the channel 124 when the water level of the discharge water W flowing in the flow passage 113 becomes higher than the height of the rotation shaft 300.

In some cases, the through part 112a may be formed to be stepped concave downward from the upper side of the first side surface 112.

That is, the through part 112a may penetrate in the right and left directions and the discharge water W may move beyond the through part 112a in the direction of the free passage 124.

The flow passage 113 is a passage formed between the first bottom surface 111 and the first side surface 112 and is formed in a quadrangular shape.

The flow passage 113 penetrates back and forth to pass through the discharge water W flowing along the water channel.

The lower end of the rotating body 200 is inserted into the flow path 113, as will be described later.

On the other hand, the second structure 120 is formed on both sides of the first structure 110, the front is closed and the rear channel 124 is formed open in the rear.

More specifically, the second structure 120 has a quadrangular shape, and includes a second bottom surface 121, a second top surface 122, a second side surface 123, and the free passage 124.

The second bottom surface 121 is formed in a long rectangular shape in the front and rear, protruding from the lower end of the first side surface 112 in the opposite direction of the flow path 113 to form the bottom of the channel 124. .

The height of the second bottom surface 121 is lower than the height of the first bottom surface 111.

That is, the bottom height of the channel 124 is lower than the bottom height of the flow passage 113.

As such, by placing the bottom height of the channel 124 lower than the floor height of the channel 113, the discharge water W flowing in the channel 124 is prevented from flowing back to the channel 113 to discharge the discharged water. The flow of (W) is smooth, and the excess discharge water (W) is effectively discharged from the flow passage 113 to the free passage (124).

The second upper surface 122 is formed in a long rectangular shape in front and rear, is spaced apart from the upper portion of the second bottom surface 121, and protruded in a direction away from each other from the first side surface 112, respectively.

In addition, the second upper surface 122 is formed with a drain hole 122b penetrating in the direction of the free passage 124.

The drain hole 122b may be discharged to the outside quickly when the water accumulated on the second upper surface 122 to minimize the damage to the power generation unit 400 and the lift 500 by water. .

Of course, in some cases, the second upper surface 122 may be formed to be inclined downward to allow water to be naturally drained to the water channel.

The height of the second upper surface 122 is lower than the height of the first side surface 112.

That is, the top height of the first side surface 112 is disposed higher than the top height of the second upper surface 122.

The power generating unit 400 and the lift 500 are mounted on the second upper surface 122 as described later.

As such, the height of the first side surface 112 is formed higher than the height of the second upper surface 122, thereby minimizing the discharge water W flowing through the flow path 113 to the second upper surface 122. Damage to the power generation unit 400 or the lift 500 mounted on the second upper surface 122 may be minimized.

In addition, an opening 122a is formed on the second upper surface 122 of the second structure 120 to communicate with the through part 112a and the channel 124.

The opening portion 122a is disposed at one end of the second upper surface 122 positioned in an upstream direction of the channel 124, and is opened upwardly to communicate with the through portion 112a.

The open part 122a is moved to the free passage 124 when the discharge water W is discharged to the outside through the through part 112a.

The second side surface 123 has a quadrangular shape, and protrudes upward from one end of the second bottom surface 121 positioned opposite to the first side surface 112.

In addition, the second side surface 123 is connected to one end of the second upper surface 122 positioned opposite to the first side surface 112, respectively, so that the second bottom surface 121 and the second upper surface 122 are mutually connected. Connect.

The height of the second side 123 is higher than the height of the rotating body 200 to be described later, the cover 140 is mounted on the upper side of the second side 123.

The cover 140 closes an upper portion between the second side surfaces 123 to protect the rotating body 200 and the power generation unit 400 when it rains.

The channel 124 is formed in a rectangular shape, the rear is closed and the front is open.

That is, the channel 124 is formed to be open in the downstream direction of the channel.

The channel 124 moves to the downstream of the channel to the discharged water (W) introduced through the opening (122a).

As such, the through part 112a is formed in the first structure 110 in the direction of the second structure 120, and the opening part 122a is formed in the second structure 120 in the upward direction. The surface of the discharge water (W) flowing along the flow path 113 is not raised to a certain level or more to ensure that the rotating body 200 is rotated stably, the discharge of the discharge water (W) is made smoothly seawater farm equipment It is possible to prevent adverse effects on.

On the other hand, the rotor 200 is rotatably mounted on the waterproof passage structure 100 and rotates by the flow of the discharge water W passing through the flow passage 113.

Specifically, the rotating body 200 is composed of a central portion 210, the support plate 220 and the wing 230.

The central portion 210 has a cylindrical shape and is elongated in a direction orthogonal to the moving direction of the discharge water W.

The central portion 210 is fixedly coupled to the rotating shaft 300 to be described later and rotates together with the rotating shaft 300.

And the support plate 220 of the disc shape is formed at both ends of the central portion (210).

The support plate 220 is disposed to face each other at both ends of the central portion 210, the diameter is larger than the diameter of the central portion (210).

The wings 230 are formed in plural and are spaced apart from each other along the outer circumferential surface of the central portion 210, protrude in an outward direction of the central portion 210, and are disposed between the support plates 220.

The wing 230 is formed convexly in the rotational direction of the central portion 210.

That is, the wing 230 is formed in an arc shape convex in the rotational direction of the central portion (210).

And the wing 230 is disposed in the lower portion of the center portion 210 of the wing 230 is inserted into the flow passage 113 is immersed in the discharge water (W).

In this case, the shape of the wing portion 230 inserted into the flow passage 113 and disposed adjacent to the flow guide jaw 111a and convex in the rotational direction of the central portion 210 is defined by the flow guide jaw 111a. It is concave on one side and opposite to each other.

As described above, the wing 230 is convex in the rotational direction of the central portion 210, thereby preventing the rotational body 200 from rotating in the reverse direction and improving the rotational force.

The rotating shaft 300 is formed in an elongated shaft shape in a direction orthogonal to the moving direction of the discharge water W, and connects the rotating body 200 to the waterproof path structure 100 to be rotated.

Specifically, both ends of the rotation shaft 300 are coupled to the bearing 640 fixed to the upper portion of the first side 112, respectively.

In addition, the rotation shaft 300 is fixedly coupled to rotate with the central portion 210 through the central portion 210.

The rotation shaft 300 rotates together with the central portion 210 when the central portion 210 rotates by the wing portion 230.

In addition, both ends of the rotation shaft 300 is coupled to the power generation unit 400 to rotate the drive shaft of the power generation unit 400.

The power generation unit 400 is mounted on an upper portion of the second upper surface 122 and generates electricity by using the rotational force of the rotation shaft 300.

The power generation unit 400 is the same as the structure of a general generator, detailed description thereof will be omitted.

The lift 500 is mounted on an upper portion of the second upper surface 122 to vertically flow the power generation unit 400.

In detail, the lift 500 includes a fixing part fixedly mounted to the second upper surface 122 and a movable part mounted on the upper part of the fixing part so as to move upward and downward, and the power generating part 400 coupled to the upper part.

Meanwhile, the fixing frame 600 is mounted on an upper portion of the lift 500, and is connected to the rotary shaft 300 and the power generator 400, respectively, so that the rotary shaft 300 and the power generator 400 flow vertically together. To be.

In detail, the fixing frame 600 includes a rotation shaft support frame 610, a power generation unit support frame 620, and a connection frame 630.

The rotary shaft support frame 610 is formed in a cross-section '' 'shape, consisting of two are respectively disposed on both sides of the rotating body 200, is fixedly mounted on the upper side of the first side (112).

The bearing 640 is coupled to the rotary shaft support frame 610 to fix the rotary shaft 300 to the upper portion of the first structure 110.

The power generation unit support frame 620 is mounted on the upper portion of the second upper surface 122, specifically, the lower frame 610, the support plate 622 and the upper frame 623.

The lower frame 610 has a 'c' shape in cross section and is disposed on each of both sides of the lift 500 to be seated on the second upper surface 122.

The base plate 622 is mounted on the lower frame 610.

The support plate 622 is formed of a rectangular flat plate, and is fixedly mounted on the lift 500.

The power generation unit 400 is mounted on an upper portion of the support plate 622.

In addition, the upper frame 623 is mounted on both sides of the power generation unit 400 on the upper portion of the support plate 622.

The upper frame 623 is a cross-section '' 'shape, it is mounted corresponding to the lower frame 610, respectively.

In addition, the connection frame 630 is mounted on the upper portion of the upper frame 623.

The connecting frame 630 is mounted on one end and the other end of the rotary shaft support frame 610 and the power generation unit support frame 620 in the movement direction of the discharge water (W), respectively, the rotary shaft support frame 610 and the power generation The supporting frame 620 is interconnected.

The fixing frame 600 moves up and down by the lift 500 to allow both the rotating body 200, the rotating shaft 300, and the power generating unit 400 to flow up and down together.

As described above, the rotary shaft 300 and the power generator 400 are coupled to the upper part of the fixing frame 600 mounted on the lift 500 to vertically flow. At the same time, it can be flowed up and down together, which is convenient to use, and has an effect of facilitating assembly.

On the other hand, in some cases, the generator using the discharge water according to the embodiment of the present invention may be rotated by a drop falling from the top of the rotating body 200 to the discharge water (W).

That is, as shown in FIG. 7, the water pipe 700 is installed at the rear upper portion of the rotating body 200.

The water pipe 700 drops the discharge water W to the rear of the rotor 200 to rotate the rotor 200.

In addition, the water pipe 700 is disposed above one surface of the flow guide jaw 111a to induce the dropped discharge water W to flow in the circumferential direction of the rotor 200 along the flow guide jaw 111a. .

Thus, by installing the water pipe 700 in the upper upper portion of the rotary body 200, there is an effect of further improving the rotational force of the rotary body 200 by the fall of the discharge water (W).

The generator using the discharge water of the present invention is not limited to the above-described embodiment, it can be carried out in a variety of modifications within the allowable technical spirit of the present invention.

W: discharge water, 100: waterproof structure, 110: first structure, 111: first bottom, 111a: flow guide jaw, 112: first side, 112a: through part, 113: flow path, 120: second structure, 121: 2nd bottom surface, 122: 2nd top surface, 122a: opening part, 122b: drain hole, 123: 2nd side surface, 124: Yeosu channel, 140: cover, 200: rotating body, 210: center part, 220: support plate, 221: wing Part 300: rotating shaft, 400: power generating part, 500: lift, 600: fixed frame, 610: rotating shaft support frame, 620: power generating part supporting frame, 621: lower frame, 622: support plate, 623: upper frame, 630: connecting frame

Claims (10)

A waterproof passage structure having a flow path through which the discharge water flows;
A rotating body rotatably mounted to the waterproof path structure, the lower end of which is inserted into the flow path and rotates by a flow of discharge water passing through the flow path;
A rotating shaft for mounting the rotating body to the waterproof path structure and rotating together with the rotating body;
Mounted to the waterproof path structure, including a power generation unit for producing electricity using the rotational force of the rotating shaft,
The waterproof passage structure,
A first structure provided with the flow passage through which the discharge water flows through the front and rear and upward directions;
A second structure formed at a side of the first structure, the power generation unit mounted at an upper portion thereof, a front structure of the first structure being closed, and a free passage open to the rear of the first structure; , ≪ / RTI >
The first structure has a through portion disposed in front of the rotating body and opened in the direction of the second structure on the side,
The second structure is a power generation apparatus using the discharge water, characterized in that the opening is opened in the upward direction to communicate the through portion and the channel. The method of claim 1,
The height of the penetrating portion is lower than the height of the rotary shaft and the generator using the discharge water, characterized in that disposed higher than the lower end of the rotating body. 3. The method according to claim 1 or 2,
The first structure,
A first bottom surface forming a bottom of the flow path;
A first side surface protruding upwardly at both ends of the first bottom surface to form the flow path, and having the through portion formed therein; , ≪ / RTI >
The second structure,
A second bottom surface protruding from the lower end of the first side in the opposite direction to the flow path to form a bottom of the channel;
A second upper surface disposed on an upper portion of the second bottom surface, protruding from the first side in the opposite direction to the flow path to form an upper portion of the channel, and having the opening formed thereon;
A second side surface protruding upward from one end of the second bottom surface opposite to the first side surface to connect the second bottom surface and the second top surface, and to form the channel; Including but not limited to,
The height of the second bottom is a power generation device using the discharge water, characterized in that lower than the height of the first bottom. The method of claim 3, wherein
The power generation unit is mounted on an upper portion of the second upper surface,
The height of the first side surface is a power generation device using the discharge water, characterized in that higher than the height of the second upper surface. The method of claim 3, wherein
The second upper surface of the power generation apparatus using the discharge water, characterized in that the drain hole is formed in communication with the channel. The method of claim 3, wherein
The first power generation apparatus using the discharge water, characterized in that the flow induction jaw is disposed in front of the rotating body to guide the flow direction of the discharge water in the circumferential direction of the rotating body. The method according to claim 6,
The rotating body includes:
A central portion fixedly coupled to the rotating shaft to rotate together with the rotating shaft;
Support plates respectively formed on both sides of the central portion;
Wing portions protruded outwardly along the outer circumferential surface of the central portion between the support plates; , ≪ / RTI >
The wing portion is formed convexly in the rotational direction of the central portion,
The flow guide jaw is formed in a concave shape corresponding to the shape of the outer circumferential surface of the support plate adjacent to one surface located in the direction of the rotating body, the power generation device using a discharge water, characterized in that the other surface adjacent to one surface is formed convex. The method of claim 3, wherein
A lift mounted to an upper portion of the second upper surface to vertically flow the power generation unit; Power generation apparatus using a effluent, characterized in that further comprises a. The method of claim 8,
A fixed frame mounted on the lift to flow up and down; Further comprising:
The rotation shaft and the power generating unit using the discharge water, characterized in that arranged in the upper portion of the fixing frame flows up and down together. The method according to claim 6,
A water channel disposed in a front upper portion of the rotating body to drop discharged water toward the rotating body; Further comprising:
The water pipe is a power generation device using a discharge water, characterized in that disposed on the upper surface of the flow guide jaw.

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