KR20080031764A - One-way rotation power generator using flow velocity - Google Patents

Abstract

A one-way rotating power generator is provided to transmit power to a rotating body regardless of the direction of flow velocity and generate power from water, wind or tide. A one-way rotating power generator includes a rotating shaft(1), a frame(3) mounted on the rotating shaft, a swirling shaft(6) mounted on the frame, a swirling plate(5) which swirls about the swirling shaft, and a support(4) mounted on the frame so as to support the swirling plate. A blade is constituted by the frame, the support and the swirling plate. At least three blades are arranged radially on the rotating shaft. The frame is formed into a blade type frame(13) fixed at both ends of the support and both ends of the swirling shaft, a truss type frame in which frames are connected through plates, or an integrated type disk.

Description

One-way rotation power generator using flow velocity

BRIEF DESCRIPTION OF THE DRAWINGS The figure for demonstrating the rotating body 10 in which the vane frame 13 was formed.

2 is a view for explaining the rotor 10 formed a plurality of wings as the wing-shaped frame (13).

3 is a view for explaining a rotating body 10 in which a truss-shaped frame 23 is formed.

4 is a view for explaining a rotating body 10 in which an integral disc 33 is formed.

FIG. 5 is a view for explaining a pivoting shaft equipped with a pivoting plate and a spring pivoting about a pivoting shaft; FIG.

Figure 6 is a view for explaining the blade frame 13, the rotating body 100 and the rotation axis.

7 is a view of the windshield 50 formed on the outer circumference of the rotating body 10.

8 is a view for explaining the rotating body 10 in which the truss-shaped frame 23 is formed.

9 is a view for explaining the rotating body 10 in which the integral disc 33 is formed.

10 is an enlarged view of the rotating body 10.

11 is an explanatory view of the rotating body 10 that rotates in one direction even with a flow velocity in an opposite direction.

FIG. 12 is a diagram for explaining the configuration of the rotating body 10 to the truss 100. FIG.

13 is a view for explaining the type of frame of the rotating body 10;

14 is a view for explaining the rotating device 200 configured in the shape of a butterfly.

15 is a view for explaining a rotating device 200 configured in the shape of a fish.

Fig. 16 is a view for explaining the erected rotating device 200 constructed in the truss structure.

FIG. 17 is a view for explaining a lying down rotary device 200 constructed in a truss structure. FIG.

18 is a view for explaining the whale-type rotating device 200 configured in the truss structure.

The present invention relates to a rotational power generator using flow velocity, in other words, flow of water flow, wind, tidal flow, and the like.

Conventional power generation devices using natural forces such as wind power, hydraulic power, etc. have been shown, but these structures are very complicated, the efficiency is not so excellent, and most of the structure that costs a lot of maintenance.

In order to improve this, there is a prior application filed by Utility Model Registration No. 20-0417376 under the name "rotational power generating device using the flow rate" as a prior application by the present applicant.

The present invention relates to a power generator of a new structure different from the conventional apparatus.

The present invention has a simple structure, low facility costs, low maintenance costs, and to provide a power generator of a highly efficient new structure capable of generating power regardless of the flow direction of the flow rate.

The main constitution of the present invention for achieving the above object of the present invention, the rotating shaft 1, the frame 3 provided on the rotating shaft 1, the pivot shaft 6 provided on the frame 3, A pivot plate 5 rotatably installed about the pivot shaft 6 and a support 4 installed on the frame 3 so as to prevent the pivot plate 5 from falling backward, wherein In the one frame 3, the support 4 and the swivel plate 5 consisting of one assembly,

At least three wings 2, which are an assembly composed of a frame 3, a support 4, and a swinging plate 5 formed radially from the rotation shaft 1, constitute the above-described frame 3 ) Is a plate shape, which is fixed to both ends of the support 4 and both ends of the pivot shaft 6 and is formed of a wing frame 13 formed in a predetermined thickness and width, or a truss frame 23 in which the wing frame is connected by a plate. ) Can be formed, it is also characterized by forming one rotary body 10 by forming as an integral disc 33 formed of one disc.

Other features and configurations other than those described above will be further described below based on the accompanying drawings.

2 is a view for explaining the configuration of the apparatus according to the present invention.

As shown in the present invention, a plurality of blades 2 having a plate shape are installed around the rotating shaft 1, and the flow velocity between the frames 3 formed on both sides as shown in " B " The turning plate 5 which receives and pivots can be composed of several turning plates 15, 25 and 35, and the wing 2 in the position shown by "a" is the outer edge of the rotor 10. An end 12 of the turning plate 15 on the outer circumferential surface of the turning shaft 26 of another turning plate 25 formed inside by turning the turning plate 15 configured to receive the flow velocity and pivoting about the turning shaft 16. The rear part 11 is brought into close contact, and the pivot plate 25 also receives a flow velocity and pivots in the same manner to form the rear part 11 toward the end 12 of the pivot plate 25 on the outer circumferential surface of the support 4 formed therein. ) Rotates the rotor 10 around the axis of rotation 1 by the turning plates 15 and 25 receiving the flow rate so as to be supported by Let's do it.

Then, another pivoting plate 35 formed near the rotational shaft 1 at the position of the blade 2 in the position shown by “b” is swiveled by the flow rate and supported by the support 4. The effective area receiving the flow velocity is pushed to cover the end of the rotating shaft, and when it is rotated to the position indicated by “d”, the pivot axis that supports the turning plate 15 on the back 11 of the turning plate 15 subjected to the flow velocity ( 26 is no longer able to support the turning plate 15 in the direction of the flow rate from right to left, so that the turning plate 15 away from the supported turning shaft 26 is flipped over to the flow of the flow rate. Will then turn clockwise. However, the inner swivel plate 25 to be rotated in the same direction is pressed by the rear portion 11 of another swivel plate 35 and stagnated so that it does not interfere with the swivel plate 15 turning as described above. .

In the position shown by "e", the turning plate 35 is directly opposed to the flow rate flowing from the right side to the left side, so that the turning plate 35 turns away from the support 4 and swings away from the turning plate 35. 35 is rotated counterclockwise to be seated on the outer circumferential surface of another pivot shaft 36 located on the outer periphery of the rotary shaft 1, where the stagnant pivot plate 25 is unwrapped and shown as "d". At the same time as the turning plate 15 that has already been turned in advance in the flow direction of the flow velocity to allow the fluid having a flow rate between the frame 3 and the turning plate (15, 25, 35).

Swiveling plates (15, 25, 35) rotated as described above is rotated with the rotating body 10 to come back to the position shown by "a", it is operated again and again in the same order as above, The rotating rotor 10 rotates according to inertia.

In other words, in the positions "a", "b", and "c", the turning plates 15 and 25 pivoting about the pivot axes 16.26 and 36 constituted between the frames 3 of the rotating body 10 described above. (35) is rotated by receiving the flow rate flowing from the right side to the left side and is supported by the inner pivot shaft (26) serving as the support (4) and the support portion on the back portion (11) of the turning plates (15, 25, 35) The turning plates 15, 25, and 35, which receive the force directly against the flow rate by not turning, push the frame 3 to which the support 4 is connected, so that the rotating body 10 is centered on the rotating shaft 1 Will rotate.

On the contrary, in the "d" position, the rear part 11 of the turning plate 15, which is placed on the opposite side of the support 4 by the rotation of the rotating body 10, receives the flow velocity, and the rotating body 10 easily rotates. Done.

In addition, in the positions "e", "f", and "g", the rear portion 11 of the turning plates 15 and 25 formed outside and the front portion of the turning plate 35 arranged inside the direction of the flow velocity in the opposite direction of the support stand. It is opposed to the front and is turned in the flow direction of the flow velocity around the pivot axis (16, 26, 36).

In addition, in the "h" position, the rear portion 11 of the turning plates 15 and 25 which are pivoted in accordance with the flow of the flow rate is seated on the outer circumferential surfaces of the support 4 and the inner pivot 26. 15 and 25 rotate in the rotational direction of the rotating body 10 and simultaneously rotate in the flow direction of the flow velocity, and also contact the outer circumferential surfaces of the support 4 and the turning shaft 26 like the rotational speed of the rotating body. It closes without impact.

As a result, since the rotating body 10 passes the fluid between the frame 3 and the swing plates 15, 25, and 35 at positions "e", "f", and "g", resistance to rotation is not generated. Rotation force is generated by the magnitude of the force received at the "," b "," c "position and the rotor 10 is rotated.

At least three wings 2, which is an assembly composed of a frame 3, a support 4, and a swinging plate 5 formed in a curved shape on the rotating shaft 1, have at least three flow rates. When the direction flows, the wing portion protruding in the direction of the flow receives the resistance of the flow rate and causes the rotor 10 to rotate in one direction according to the turning direction by the configuration of the turning plate 5.

1, 2, 6, 7, and 11, the frame 3 is plate-shaped and is fixed to both ends of the support 4 and both ends of the pivot shaft 6 to a predetermined thickness and width. It can be formed by the formed wing-shaped frame 13 to form a light weight of the rotating body 10, the fluid can be quickly escaped to the frame 3 between the wings (2), Figures 3 and 8 By connecting the wing-shaped frame with a plate that receives less resistance of the flow rate, a truss type frame can be formed to form the truss-type frame 23 safely, and as one disc as shown in FIGS. 4 and 9. It is preferable to obtain a lot of driving force by forming the integral disc 33 formed therein and increasing the rotation of the rotor 10 by collecting as much fluid as possible without receiving resistance through the frame 3.

Although not shown among the frames 13, 23, and 33 among the frames 3 as illustrated in "B" of FIG. 2, one or more cylinders are formed by connecting the frames 3. The length of the rotating body 10 can be lengthened as needed. This is preferable because a large capacity rotor can be made by receiving a lot of fluid.

In addition, one or more swing plates 5 may be configured between the frames 3 around the rotation shaft 1, and the support 4 may also connect one or more swing plates to the frame as needed. This strong flow rate and a lot of fluid can be received, and can also be formed to obtain a large rotor 10 as described above.

In addition, the edge surface of the turning plate 5 is bent to form the collection plate 5a, and the inner surface 9 is formed into a curved surface to form a deep dish-shaped turning plate 5 to receive a lot of fluid. The rotational force of the rotating body 10 can be enlarged. Therefore, the capacity of the rotating body 10 can be increased by adjusting the depth of the dish-shaped swing plate 5, which is preferable.

As shown in FIG. 2, the pivoting plate 5 has another inner pivoting shaft contacting the rear portion 11 of the pivoting plate 15 pivoting about the pivoting shaft 16 when the rotor 10 rotates. At least one bumper (8b) to prevent shock when contacting the outer peripheral surface of the 26) to prevent damage by buffering, to minimize the contact surface during the sliding and sliding each other, and to reduce the resistance when rotating to increase the rotational force It is preferable to be able. The bumper 8c may also be formed at the end portion 12 of the turning plate 5, and the bumper 8c may be configured at both edges of the turning plate for cushioning, and may also be configured to be in contact with the rotating plate. In addition, the bumper is preferably configured to reduce the frictional resistance upon contact if the wheel bumper is configured to rotate.

In addition, the support 4 connected between the frames 3 and supporting the rear portion 11 of the turning plate 5 to rotate the rotating body 10 is the rear portion 11 of the turning plate 5. At least one bumper 8a is configured to cushion the contact with the bumper, and the bumper may be configured to reduce the frictional resistance during contact as much as possible.

As shown in FIG. 12, the vertical stand V and the horizontal stand H, which are individual supports of the truss 100 formed by connecting the rotating body 10 with the vertical stand V and the horizontal stand H, are formed. ) Can be configured by connecting one or more rotors 10 in series to obtain a greater rotational force, and can also be configured separately.

Then, the trusses 100 are preferably secured to each other so as to be able to configure a large number of the rotating body 10 in a small space.

In addition, when the rotating body 10 is movable up and down and left and right in the vertical stand (V) and the horizontal stand (H) of the truss 100, for example, the vertical stand (V) and horizontal If it is formed to be able to move up, down, left, and right in the stage (H), the rotor is placed in the water to generate power using the flow rate, and then lifted out of the water to obtain the power by the wind, and it is easy to move for maintenance. And, if an abnormality in the water surface and obstacles caused by the obstacle is necessary, it is preferable to protect the rotating body 10 from the obstacle.

When the rotor 10 is installed on the supports V and H of the truss 100, the rotor 10 changes the position of the pivot shaft 6 of the rotor plate 5 for each rotor 10, The direction of rotation can be reversed. When the adjacent rotating body is rotated in different directions, a problem caused by eccentricity is caused by the rotational force biased to one side by one rotation, which is preferable because it can maintain the balance of the truss.

As shown in FIG. 6 to FIG. 10 and FIG. 11B, the rotating shaft 1 is formed in a cylindrical shape so that the end portion 12 of the pivoting plate 5 which pivots is directly in contact with the outer circumferential surface of the cylinder. The lower surface support 4 does not need to be configured separately, and the outer circumferential surface of the rotational shaft 1 confines the fluid to increase the rotational force.

As shown in FIG. 5, the pivot shaft 6 has a spring built therein, but the rotor 10 includes a shock absorber having a spring built therein, and the shock absorber includes a swing plate 5. ) Rotates within 180 degrees (d1 ° + d2 °) of the center line connecting the rotation axis (1) and the pivot axis (6), it is strongly suppressed to lean over 90 degrees (d2 °),

The end portion 12 of the turning plate 5 that is rotated by the rotation of the rotor 10 is supported on the support 4 or the outer circumferential surface of the turning shaft 26 and the rotating shaft 1 of the inner turning plate 25. When it arrives, it delays (Delay action) for buffering and closes slowly. Then it is preferable.

As another embodiment of the present invention as shown in "B" of FIG. 7 constitutes a windshield 50 on the outer circumference of the rotating body 10, the windshield is a pivot shaft when receiving the flow velocity ( 60 and the turning plate (51, 52) pivoting on both sides of the center and is connected with the pivot axis 60 to open the swinging plate (51, 52) to a defined position, and also has a folding arm One hinge portion 70 is configured to rotate about the rotational axis 1, and the turning plates 51 and 52 are folded in the direction of receiving the flow rate so as to receive less resistance, and the turning plate 51 when rotating in the opposite direction of the flow rate. 52 is expanded to receive a lot of fluid to increase the rotational force, and includes a bent portion 120 to facilitate the flow of flow. And it is preferable to provide the bumper which buffers when the turning boards 51 and 52 are folded.

The rotary device 200 according to another embodiment of the present invention forms a rotary device 200 formed in the shape of a butterfly on the circumference of the rotating body as shown in FIG. One or more rotating bodies having the rotating device 200 formed in the longitudinal direction of the rotating shaft 1 may be installed, and the rotating device 200 may be folded in a direction in which the blade receives the flow velocity about the rotating shaft 1. When the rotor is rotated in the opposite direction of the flow rate, the wings are stretched to receive a lot of fluid, so as to receive a large rotational force. As shown in FIG. A film that is folded and spread between the wing and the wing may be formed in the upper part 51 and the lower part 52 of the wing to increase the rotational force.

In addition, as shown in FIGS. 15 to 18, the rotary device 200 formed in the shape of fish on the circumference of the rotating body is formed to rotate around the rotation axis 1 and the vinyl on both sides in the direction of receiving the flow velocity. , The fins and gills are folded, the inside of the body is reduced to receive less resistance, and when rotating in the opposite direction of the flow rate, the vinyl, fins and gills are expanded to receive a lot of fluid to form a large rotation force The tail is preferably formed in a streamlined shape for the rotational force of the rotating body.

In addition, the rotatable device 200 may be formed in the shape of a whale, as well as the rotatable device 200 using fish and plants.

In addition, the rotating device 200 is connected to the horizontal and vertical support (H, V) of the truss 10, it can be configured in combination.

Although the device description of the present invention has been illustrated as a flow rate flowing from right to left, the same operation as above occurs even if the flow rate flows from left to right as shown in " B " Therefore, the power in one direction can be transmitted to the rotating body rotating around the rotating shaft 1 regardless of the front and rear flow of the flow rate.

Therefore, when installed in the sea, it is possible to generate power using tidal power. It can also be applied to other flow rates. For example, if installed in a windy place can be used for wind power generation of course.

In particular, the turbulent flow rate is rotated only in one direction without being affected by the direction to obtain acceleration due to inertia, and the rotational force can be obtained at all times regardless of the strength of the flow rate.

According to the present invention as described above, it is made of a simple structure, it is a very useful device that can produce a device for generating power using water, wind, tidal and the like. In addition, since the device can generate power irrespective of the front and rear direction of the fluid, its power generation efficiency is high. In addition, the device according to the present invention has the advantage that the structure is simple, so that the failure is small and the maintenance cost is not expensive.

Claims (16)

The rotating shaft 1, the frame 3 installed on the rotating shaft 1, the turning shaft 6 provided on the frame 3, and the turning plate 5 rotatably provided around the turning shaft 6 ) And a support (4) installed on the frame (3) to prevent the turning plate (5) from falling to the rear, wherein the frame (3), the support (4) and the turning plate (5) In consisting of one assembly, At least three wings 2, which are an assembly composed of a frame 3, a support 4, and a swinging plate 5 formed radially from the rotation shaft 1, constitute the above-described frame 3 ) Is fixed to both ends of the support (4) and both ends of the pivot shaft (6) is formed of a wing-shaped frame 13 formed in a predetermined thickness and width, or the truss-shaped frame 23 is connected to the wing-shaped frame by a plate One-way rotational power generating apparatus using the flow rate, it can be formed, it is also formed as an integral disc 33 formed of one disc to form a rotating body (10). The method of claim 1, The rotating body 10 is installed by combining at least two frames 13, 23, 33 in the longitudinal direction of the rotary shaft 1, between the frame 3 of the assembly connected to the rotary shaft 1 At least one pivoting plate 5 is configured, and the pivoting plate 5 is bent the edge surface to form a collection plate (5a), the back surface is formed by a curved surface to form a deep inside of the inner surface (9) One-way rotational power generating device using the flow rate. The method of claim 1, The pivoting plate 5 is formed on the outer circumferential surface of another inner pivoting shaft 26 in contact with the rear portion 11 of the pivoting plate 15 pivoting about the pivoting shaft 16 when the rotor 10 rotates. At least one bumper may be configured to cushion the contact, and the bumper may be formed at the end 12 of the turning plate 5, and the bumper may be configured at both edges of the turning plate, and the bumper may rotate. One-way rotational power generating device using the flow rate, characterized in that it can be formed as a wheel bumper. The method of claim 1, The end 12 of the inner pivot plate 35 of the rotating body 10 is pressed against the end 12 of another pivoting plate 25 which is supported by the support 4 and rotates. The end 12 of the turning plate 25 is prevented from being separated before the turning plate 25 reaches a predetermined position by rotation, and the turning shaft 36 of the inner turning plate 35 is rotated in the direction of the rotation axis 1. One-way rotational power generating device using the flow rate, characterized in that configured in the position. The method of claim 1, The support 4 is connected between the frame (3) and constitutes at least one bumper to cushion the contact with the back portion 11 of the swinging plate (5), the bumper is also composed of a rotating wheel bumper One-way rotational power generating device using the flow rate, characterized in that. The method of claim 1, The rotating body 10 is characterized in that it can be configured to connect or separate one or more in succession to each individual support (V, H) of the truss 100 connected by the vertical (V) and horizontal (H). One-way rotational power generating device using the flow rate. The method according to any one of claims 1 to 6, The rotating body 10 is a one-way rotational power generating device using a flow rate, characterized in that the vertical movement (V) and the horizontal (H) of the truss (100) can move up and down. The method according to any one of claims 1 to 6, When the rotor 10 is installed on the supports V and H of the truss 100, the rotor 10 changes the position of the pivot shaft 6 of the rotor plate 5 for each rotor, thereby changing the rotation direction of each rotor 10. One-way rotational power generating device using the flow rate, characterized in that formed opposite to each other. The method according to any one of claims 1 to 6, The rotation shaft (1) is a one-way rotational power generating apparatus using a flow rate, characterized in that the end 12 of the rotating plate (5) to form a cylindrical shape to be in direct contact with the outer peripheral surface of the cylinder is supported. The method according to any one of claims 1 to 4, In the above-described pivot shaft 6 in which a spring is incorporated, The rotating body 10 includes a shock absorber with a built-in spring, and the shock absorber is 180 degrees (d1 ° + d2) with respect to the center line of the pivot plate 5 connecting the rotation shaft 1 and the pivot shaft 6. To turn within 90 ° (d2 °) and to restrain it, and to retard for cushioning when approaching the support (4) or the outer circumferential surfaces of the inner pivot shaft (26) and the rotating shaft (1). One-way rotational power generating device using the flow rate, characterized in that for (Delay action). The method according to any one of claims 1 to 6,  The windshield 50 is configured on the outer circumference of the rotating body 10, and the windshield constitutes pivot plates 51 and 52 pivoting from both sides about the pivot shaft 60 and the pivot shaft 60. A hinge 70 having an arm connected to the swing plates 51 and 52 to a defined position to rotate about the rotation axis 1 and receiving a flow velocity. 52) is folded, and when rotated in the opposite direction is extended to receive the fluid to increase the rotational force, and includes a bent portion 120 to facilitate the flow of flow, using a flow rate characterized in that it comprises a bumper for cushioning One-way rotational power generator. Comprising a rotating device 200 formed in the shape of a butterfly on the circumference of the rotating body 10, one or more rotating bodies forming the rotating device 200 in the longitudinal direction of the rotating shaft 1 is installed, Rotating device 200 is a wing is folded in the direction of receiving the flow velocity around the axis of rotation (1) to receive less resistance, when rotating in the opposite direction of the flow of the blade is formed to receive a large flow rate to receive a large rotational force One-way rotational power generating device using a flow rate characterized in that. The method of claim 12, The butterfly-shaped rotating device 200 is a one-way rotational power generating device using a flow rate, characterized in that to form a film that is folded between the wings to receive a large amount of flow rate when the wing is spread. The method of claim 12, On the circumference of the rotating body is formed a rotating device (200) formed in the shape of a crucian carrotate around the rotation axis (1) and in the direction of receiving the flow rate, both sides of the vinyl, fins and gills are folded, The inside is reduced to reduce the resistance to less resistance, when rotating in the opposite direction of the flow rate, the vinyl, fins and gills are formed to receive a large flow rate to receive a large rotational force, the tail is streamlined for the rotational force of the rotor One-way rotational power generating device using the flow rate, characterized in that formed by. The method of claim 14, One-way rotational power generating apparatus using the flow rate, characterized in that can be formed in the shape of a whale on the circumference of the rotating body, as well as using the shape of fish and plants. The method according to any one of claims 12 to 15, The rotating body is connected to each support (V, H) of the truss 100, one-way rotational power generating apparatus using a flow rate, characterized in that can be configured in combination.

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