KR101717425B1 - Power Generators using currents in the Pending state - Google Patents

Abstract

Disclosed is a mooring type tidal-current power generating device. According to the present invention, the mooring type tidal-current power generating device comprises: a turbine rotated by seawater; a power generating unit connected to the turbine generating electricity; and a floating body formed around the turbine and the power generating unit to partially dip the turbine into the water and floating on water. The turbine comprises: a horizontal rotary shaft; a pair of rotary discs separately joined to both ends of the horizontal rotary shaft to be penetrated; and a plurality of blades formed of a plate wherein a flat unit and a curved unit are formed on both surfaces thereof and installed in all directions around the horizontal rotary shaft between the rotary discs. The blade plate generates a reaction to seawater with the flat units underwater and a lifting force with the curved unit underwater, thereby inducting the rotation of the turbine. According to the present invention, the mooring type tidal-current power generating device is capable of using the reaction to seawater and the lifting force with a structure of the blade plates formed of the plate wherein the flat unit and the curved unit are formed on both surfaces thereof at the same time, and improve the efficiency of the rotation of the turbine; thereby improving the efficiency of power generation.

Description

[0001] The present invention relates to a pneumatic tidal generator,

The present invention relates to a pneumatic tidal power generator, and more particularly, to a pneumatic tidal power generator that generates electricity by causing drag and lift by water to act on a turbine while a part of the turbine is submerged in water.

Tidal power generation is a power generation system that uses the natural flow of currents (ocean currents and rivers) as it is, and it refers to a power generation system that generates electricity by installing a turbine (turbine) in a fast water flow. It is a concept distinguished from tidal power generation (tidal power generation), which generates electricity by rotating water turbines (wind turbines) while flowing seawater collected through a tidal stream through a channel to the opposite side.

On the other hand, even if the same hydraulic force is used, it can be classified into gravitation aberration, impact aberration, and recoil aberration depending on its operation mode. Here, the gravitational aberration is a method of rotating the aberration (turbine) after changing the position energy of the water to kinetic energy like the dam, and the impact aberration is a method of rotating the aberration (turbine) through the high pressure water jetted from the nozzle, (Turbine) using the kinetic energy and pressure of water passing through the runner.

Conventional tidal power generation, gravity aberration, impact aberration, and recoil aberration, which utilize hydraulic power to produce electricity, require large-scale civil engineering structures or artificial large-scale equipment to produce a large difference in water height or to generate high- This is generally required. This requires investment in excessive construction costs, environmental destructive factors exist, and there is a problem in that it can only be utilized in a limited area in terms of location.

Accordingly, there is a demand for development of algae power generation that can be implemented with relatively low cost, environment friendly, and simple structure because there is no place limit, no large scale civil construction or artificial large scale device is required.

As a prior art for meeting this demand, Korean Patent Laid-Open Publication No. 10-2014-0004856 discloses a method for installing the apparatus in a simple manner at low cost, minimizing the resistance and maintaining a constant rotational force, Discloses a technique relating to a water turbine having a semi-cylindrical active wing for a hydroelectric power generation.

Specifically, the description of the prior art includes a hollow shaft having a hollow hollow shape; A rotating circular plate attached to both sides of the airstream axis and having a plurality of axial grooves concentrically at appropriate intervals; A plurality of blade shafts rotatably supported by bearings in axial grooves of the both-side rotary disk; A plurality of aberration wings formed in a semi-cylindrical shape for rotating the rotary disk by water pressure, the rotary aids being fixed to the wing shafts on both sides by bolts; And a plurality of stoppers for rotation preventing the rotation of the aberration vanes by projecting radially from the outer circumferences of both sides of the airstream axis at proper intervals.

This prior art document has a merit that a plurality of aberration wings individually rotate around a wing axis and operate independently of the direction of the water flow, but it is a complicated structure composed of a large number of parts, so that there is a problem of difficulty in manufacture, maintenance and management .

In addition, since the entire aberration is installed so as to be completely submerged in the water, the rotation of the aberration may be deteriorated by foreign matter such as a fish damage due to water pressure or a fish net or aquatic plants, There is a problem that can affect the surrounding ecosystem.

In addition, a semi-cylindrical aberration blade made by simply bending a plate has a structure in which lifting force is not generated because there is no difference in flow velocity between the convex portion and the concave portion of the semicylindrical shape, , A resistance force acting in the opposite direction to the relative velocity of the object with respect to the fluid).

Such a structure is not only difficult to rotate the aberration beyond the speed of the flowing water because only the drag is used, and it can be said that the structure can not smoothly induce the rotation of the aberration at the slow flow velocity.

Therefore, it is necessary to develop a structure that can induce the rotation of the aberration more smoothly and increase the power generation efficiency than the given flow velocity.

Korean Patent Publication No. 10-2014-0004856 (Publication date: 2014.01.14)

It is an object of the present invention to provide a turbine capable of increasing the rotation efficiency of a turbine by simultaneously using a drag force as well as a drag force due to water flow and reducing the damage of the device and facilitating maintenance and management of the device, The present invention provides a tethered bird generator.

The object of the present invention can be achieved by a turbine generator comprising a turbine rotating by flowing water, a generator connected to the turbine to generate electricity, and a sub-fluid disposed around the turbine and the generator section, Wherein the turbine comprises a horizontal rotary shaft, a pair of rotary disks penetrating the both ends of the horizontal rotary shaft at the center thereof, and a planar portion and a curved portion formed on both sides of the rotary disk, And a plurality of wing plates radially disposed about the horizontal rotation axis between the rotation discs, wherein the wing plate generates a drag force in the plane portion with respect to the water flow under the water surface, and generates lift in the curved portion, And the turbine is rotated by the rotation of the turbine.

The vane plate may include three vane plates arranged at an angle of 120 ° with respect to the horizontal rotation axis. The vane plate may include a vane plate, A vortex shedding hole in which the plates are spaced apart from each other by a predetermined distance can be formed.

The rotating disk may be formed with a convex portion that protrudes convexly at a central portion of the surfaces facing each other so as to increase the flow velocity of the flowing water passing between the pair of rotating disks.

Wherein the float includes a pair of buoyancy members symmetrically provided on both sides of the turbine and the power generation unit so that a part of the turbine is submerged in the water; A pair of connecting members symmetrically arranged on the front and rear sides of the turbine and the power generation unit to couple and fix a pair of the buoyancy members to each other; And a mooring line having one end connected to a pair of the buoyant member ends and the other end connected to the offshore structure so as to prevent the float from escaping and allow the floating body to change direction and float in accordance with the flowing water flow have.

Wherein the buoyancy member is formed in a cylindrical shape with a hollow inside and both ends closed, wherein the buoyancy member end on the mooring line side protrudes outward so as not to interfere with the flow of the water flowing from the buoyancy member end to the turbine Like shape.

The buoyancy member may further include a plurality of direction holding plates protruding downward from the lower end so that the floating body can maintain a direction parallel to the flow direction.

The power generation unit may be installed in at least one of both ends of the horizontal rotating shaft, which is penetrated, to generate electricity according to the rotation of the turbine.

The upper end of the float may be provided with a lid provided with a receiving space for accommodating the turbine and the power generation unit so that the turbine exposed above the water surface is not affected by the wind.

The lid part may further include a position indicator at an upper end thereof to prevent collision with a ship being operated.

Wherein a size of the vortex hole as a distance between the horizontal rotation axis and the vane plate is 25% to 30% when the length between the horizontal rotation axis and the vane plate is 100% 70% to 75%.

According to the present invention, not only the drag force due to the flowing water but also the lift force can be used together with the rotation of the turbine through the structure of the blade plate formed of the plate material formed on both sides of the plane portion and the curved surface portion, It is possible to improve the power generation efficiency.

In addition, since only a part of the turbine is immersed in the water through the float, damage to the parts due to high water pressure can be reduced, and damage or damages to the blade and the foreign matter can be immediately detected. And the ease of maintenance and management can be increased.

In addition, as the float line naturally changes direction according to the flow of water by the mooring line and floats on the water surface, it is possible to generate power through rotation of the turbine even in the place where the flow of water flows instantaneously. Can be used.

1 is a perspective view of a paddock type alga generator according to an embodiment of the present invention.
2 is an exploded perspective view of FIG.
3 is a view for explaining the operation of the turbine of the tethered alga generator shown in Fig.
4 is a cross-sectional view taken along line AA in Fig.
5 is a view showing a use state of the paddle type tidal power generator according to the flow direction of the flow.
6 is a cross-sectional view of a turbine cut along the line AA in FIG. 1 in another embodiment of the present invention.
7 is a perspective view of a pendent tidal generator according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, the well-known functions or constructions are not described in order to simplify the gist of the present invention.

FIG. 1 is a perspective view of a paddock type tidal power generator according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of FIG. 1, FIG. 3 is a view for explaining the operation of a turbine of the paddock tidal power generator shown in FIG. 1 FIG. 4 is a cross-sectional view taken along the line A-A in FIG. 1, FIG. 5 is a view showing a use state of the illustrated tidal-current generator according to the flow direction of water, FIG. 7 is a perspective view of a tethered alga generator according to another embodiment of the present invention. FIG.

A plow-type alga generator (100) according to the present invention is a power generation device that generates electricity by using running water (current or river flow) and includes a planar portion (116A) and a curved surface portion (116B) The lift force as well as the drag force can be used together with the rotation of the turbine 110 through the turbine 110 to which the rotor 116 is applied.

This is distinguished from the turbine 110, which conventionally used only the drag force or the lift force, so that both rotations are transmitted to the rotation of the turbine 110, so that the rotation efficiency of the turbine 110 is further increased, This contributes to improving the efficiency of algae generation using oil.

In addition, unlike conventional turbines 110 installed deep in water, the pendent tidal generator 100 according to the present invention is driven in a state where only a part of the turbine 110 is immersed in the water through the float 130, It is possible to immediately recognize the breakage of the turbine 110, the rotation state thereof, the presence of foreign matter (waste net, a few seconds), and thus the repair, maintenance, and management of the turbine 110 can be facilitated .

Further, as the float 130 naturally floats on the water surface due to the flow of the flowing water by the mooring line 136, power generation through the rotation of the turbine 110 can be performed even where the flow of the flowing water changes instantaneously And can be used universally without restriction of the installation place.

In order to implement these functions and operations, the paddle-type alga generator 100 according to the present invention includes the turbine 110, the power generator 120, the float 130, and the like.

Each of the above-described configurations will be described in more detail as follows.

First, the turbine 110 is a component that rotates by flowing water, and performs a role of converting the kinetic energy of the flowing straight line to kinetic energy of rotation.

The turbine 110 according to the present invention is configured such that its rotation axis is arranged in parallel with the horizontal direction, not the vertical direction.

The reason why the turbine 110 according to the present invention is rotated with respect to the horizontal axis is that the turbine 110 is arranged in such a manner that the portion of the turbine 110 can most effectively utilize the force due to the water .

That is, considering the principle of Ekman spiral transport, the flow of water is the fastest at the water surface in the entire water depth, and the turbine 110 is generally formed long along the rotation axis, the turbine 110 having the horizontal axis, The turbine 110 is rotated at a higher speed than the other turbines at a higher flow rate than the turbine 110 at a higher flow rate. This results in further increasing the rotation efficiency of the turbine 110.

For reference, the principle of transporting Eckman is that the wind that flows in a certain direction from above the seawater (or stream) causes the flow of seawater (or stream) through the friction with sea water (or river) The wake flow refers to the principle that the flow rate increases as it goes from the deep sea to the water surface.

The turbine 110 according to an embodiment of the present invention includes a horizontal rotary shaft 112, a rotary disk 114, a blade 116, and the like.

The horizontal rotation shaft 112 is a component that serves as a rotation center of the turbine 110 and has a rod shape. One end of the horizontal rotation shaft 112 is rotatably and tightly coupled by a float 130 and a bearing B, Tightly coupled by the power generator 120 and the bearing B. [ The center region of the horizontal rotary shaft 112 is coupled with the center of a pair of rotary circular plates 114 to be described later and rotated together.

The horizontal rotation axis 112 may be a cylindrical bar as shown in FIG. 2, but may be a bar having a polygonal cross-section.

The rotating disk 114 is a component that forms an outer appearance of the turbine 110 by supporting and fixing both sides of the blade 116, which will be described later, and is formed into a disk shape.

The center of the rotary disk 114 is coupled to the rotary disk 114 through the opposite ends of the horizontal rotary shaft 112 in a state in which the pair of the rotary disk 114 are disposed at a distance with each other facing each other.

At this time, if the thickness of the rotating disk 114 is excessively large, it may generate a vortex that obstructs the flow of the flowing water during rotation. Therefore, the thickness of the rotating disk 114 may be formed to be about the same as the thickness of the wing plate 116, So that it can be properly performed.

The vane plate 116 is made up of a plurality of vanes and generates drag as well as drag force by the flow of water to induce smooth rotation of the turbine 110. The technical core of the paddle type alga generator 100 according to the present invention It is.

The drag force in the present invention refers to the force (arrow of solid line, see Fig. 3) that causes the water to push the blade 116 to rotate the turbine 110, i.e., the drag (the resistance force acting in the opposite direction to the relative speed of the object with respect to the fluid) .

And the lifting force (mechanical force generated by the pressure difference caused by the speed difference of the fluid at the surface of the object when the fluid flows around the object) Refers to a force (refer to a dotted arrow in Fig. 3) which is generated due to a pressure difference caused when flowing water flows along both sides and induces the wing plate 116 to rotate more smoothly along the direction of the water flow.

For reference, lift can be explained by Bernoulli's equation, which is a well-known natural law of the concept, so a detailed explanation is omitted.

The blade plate 116 according to the present invention is configured such that the planar portion 116A and the curved surface portion 116B having different path lengths are formed on both sides of the blade plate 116 in order to allow the lift force and the drag force to cooperate with the rotation of the turbine 110, And a plate material. The wing plates 116 are installed radially between the rotation discs 114 about the horizontal rotation axis 112.

The curved surface portion 116B is formed of a streamlined surface in order to increase the flow path of the flowing water flowing along the surface while reducing the resistance received by the flowing water. The flat surface portion 116A is formed of a curved surface portion 116B, And to reduce the flow path of the flowing water along the flat surface. The cross section of the blade plate 116 composed of the plane portion 116A and the curved surface portion 116B is similar to the cross-sectional shape of the similar airplane blade.

The number of the wing plates 116 may be increased or decreased in consideration of environmental conditions such as the flow rate of installed water and the density of the water flowing in the water tank. At least two of the wing plates 116 may be installed radially, have.

However, the vane plate 116 according to the embodiment of the present invention has versatility that can secure a certain level of the rotational speed of the turbine 110 regardless of the environmental condition of the installed water area, Three radial directions are formed at an angle of 120 DEG with respect to the horizontal rotary shaft 112 so as to be secured.

The mounting direction of the wing plate 116 is set such that the lifting force and the drag force of the wing plate 116 by the water flow can induce the smooth rotation of the turbine 110 by the planar portion 116A of the wing plate 116 Is installed so as to face the running direction of the running water.

When a plurality of blades 116 are installed radially with respect to the horizontal rotary shaft 112 in this installation direction, a drag force is generated in the plane portion 116A with respect to the running water below the water surface, And a lift is generated in the portion 116B, so that it is possible to smoothly guide the turbine 110 without a force that interferes with the rotation of the turbine 110. [

The coupling between the wing plate 116 and the rotation disc 114 may be formed by a bolt passing through the rotation disc 114 and engaging with the wing plate 116. At this time, So as to be inserted into the groove formed inside the rotary disk 114. This can reduce the resistance to oil flow due to the bolt head when the rotary disk 114 rotates.

On the other hand, a vortex flow hole 116C may be formed between the horizontal rotation shaft 112 and the blade plate 116. [

The vortex flow holes 116C serve to reduce vortices generated due to the convergence of flowing water on the inner space formed by the vanes 116 adjacent to each other. That is, the water collected in the inner space formed by the vanes 116 adjacent to each other naturally flows backward through the vortex flow hole 116C provided so as to escape without stopping the flow, thereby reducing the generation of the vortex . As a result, the rotation of the turbine 110 can be smoothly and continuously performed without being disturbed by the vortex.

In addition, the vortex shedding hole 116C causes a force to be applied toward the rotational direction of the ongoing turbine 110 by causing the vortex flow H passing therethrough to be lifted again to the vane plate 116, which rotates at the back (rear) (See Fig. 3 (c)).

The vortex holes 116C are formed such that when the plurality of vanes 116 are installed radially around the horizontal rotation axis 112, the vanes 116 are spaced apart from the horizontal rotation axis 112 by a predetermined distance . At this time, the size of the vortex flow hole 116C (the separation distance between the vane plate 116 and the horizontal rotation axis 112) can be changed into various sizes in consideration of the flowing characteristics of the flowing water.

According to the embodiment of the present invention, when the length between the horizontal rotation shaft 112 and the end of the blade 116 (the end of the rotation track) is 100% The size of the vortex flow hole 116C, which is a distance between the wings, is 25% to 30%, and the width of the wing plate 116 is 70% to 75%. This ratio is designed so that the lift and drag force due to the flowing water can be smoothly and balancedly generated through the vane plate 116, which is maximally three times larger than the vortex shedding hole 116C, while suppressing the occurrence of the vortex as much as possible .

How the turbine 110 as viewed above receives lifting force and drag force will be described in more detail with reference to FIG. The direction and length of the dashed arrows in the drawing indicate the direction and magnitude of the lift, and the direction and length of the solid arrow indicate the direction and magnitude of the drag.

First, as shown in FIG. 3 (a), when the water flows to the right, the wing plate 116 at the position (1) is positioned in parallel with the flow velocity (the angle of attack is close to 0 degrees and the lift increases) 116B, a large lift L1 is generated substantially downward and rotates the turbine 110.

This is because the low pressure portion is formed as the flow of water flows faster toward the curved portion 116B after the water flows to both the flat portion 116A and the curved portion 116B, so that the lift is generated substantially downward (see Bernoulli's Principle). ) Here, the angle of attack refers to the angle formed by the longitudinal direction of the cross section of the blade plate 116 and the flow direction.

On the other hand, since the wing plate 116 at the position (2) is located at a position tilted close to the vertical line with respect to the flow of water, only a middle drag D2 is generated in the plane portion 116A to rotate the turbine 110 . That is, the turbine 110 shown in FIG. 3 (a) is rotated by the action of lift and drag by the water.

As shown in Fig. 3 (b), the wing plate 116 rotated at the position shown in Fig. 3 (a) is positioned at a slight angle with the flow velocity, The lift force is reduced and the turbine 110 is continuously rotated while the lift L2 smaller than that of Figure 3 (a) occurs in the curved surface portion 116B in a direction perpendicular to the end surface of the blade plate 116. [ (See Bernoulli Principle)

On the other hand, since the wing plate 116 rotated at the position shown in FIG. 3 (a) is at a position tilted close to the direction parallel to the flow of water, only the smallest drag D3 And causes the turbine 110 to rotate along the water flow direction. 3 (b), the lift and drag acts together and rotate as in the case of FIG. 3 (a).

As shown in Fig. 3 (c), the wing plate 116 rotated at the position of Fig. 3 (b) is at a position tilted close to the vertical line with respect to the water flow, Only the drag force D2 is generated to cause the turbine 110 to rotate along the water flow direction. Since the angle of attack is excessively large, the lift is hardly generated.

On the other hand, the wing plate 116 rotated at the position of FIG. 3 (b) is positioned in parallel with the flow of water H passing through the vortex flow hole 116C (the angle of attack is close to 0 degrees and the lift increases) So that the turbine 110 is rotated by the large lift L1 generated substantially upward in the curved portion 116B. That is, the turbine 110 shown in FIG. 3 (c) also rotates due to the interaction of the lift force and the drag force.

As shown in Fig. 3 (d), the wing plate 116 rotated at the position of Fig. 3 (c) is almost perpendicular to the flow velocity, Only the turbine 110 is rotated to rotate the turbine 110 along the flow direction. At this time, since the angle of attack is too large, there is almost no lift.

On the other hand, the wing plate 116 rotated at the position of FIG. 3 (c) is exposed above the water surface and comes into contact with the air according to the continuous rotation of the turbine 110, . At this time, although the wing plate 116 at the position (2) is affected by the wind, it does not greatly affect the rotation of the turbine 110 in consideration of the density of the flowing water and the rotational inertia of the turbine 110. As a result, the turbine 110 shown in FIG. 3 (d) is continuously rotated by the action of the drag force and the rotational inertia of the turbine 110.

As described above, although the description has been made with reference to the case where three blades 116 are provided in the drawing, it is needless to say that the turbine 110 including more blades 116 may be fully described.

The turbine 110 according to the present invention can effectively prevent the lift and drag force from being transmitted to the rotation of the turbine 110 through the organic coupling of the structure, the installation direction and the vortex hole 116C of the blade plate 116, It is possible to rotate the turbine 110 more than the speed of flowing water more than the turbine 110 having the structure using only the conventional drag force, thereby increasing the efficiency of the algae generation by the flowing water.

In addition, since the turbine 110 according to the present invention as described above has a simple component structure and structure unlike a complicated structure or structure such that the aberration blades individually rotate about the blade axis, The durability of the turbine 110 is improved, and maintenance and management of the turbine 110 can be facilitated.

The power generating unit 120 is connected to the turbine 110 and generates electricity. The power generating unit 120 is installed in at least one of both ends of the horizontal rotating shaft 112 passing through the rotating disk 114, Electricity is generated.

Generally, the power generating unit 120 according to the embodiment of the present invention for generating three-phase alternating current, which is generally used, can generate electricity using rotational force as shown in FIG. 4 A rotor 122 fixed to one end of the horizontal rotary shaft 112 and rotating together with the horizontal rotary shaft 112 and a rotor 122 fixed to the inner space of the generator 120 such that the rotor 122 is spaced apart from the outer peripheral surface of the rotor 122 And a stator 124.

The stator 124 is a fixed portion of the alternator wound on the field coil, and the rotating rotor 122 (the rotor 122) is a fixed portion of the alternator wound around the field coil, Is generated by the coil of the stator 124 and an electromotive force is generated in the coil.

That is, when the turbine 110 rotates according to the flowing water, the power generating unit 120 having such a structure rotates in the inner space of the stator 124 by the rotor 122 provided at the end of the horizontal rotating shaft 112, . Since the electricity generation method of the power generation unit 120 is a well-known technique, a detailed description of its structure and operation is omitted.

The float 130 is a component provided around the turbine 110 and the power generation unit 120 so that the turbine 110 according to the present invention can be rotated in a state where the turbine 110 is not completely immersed in water but only a part thereof is immersed in water , Any structure and material capable of generating buoyancy can be used.

The float 130 is connected to the sea structure such that the algae generator 100 according to the present invention does not escape from a specific water area (moored area) by the flowing water, As shown in FIG.

The reason why only the part of the turbine 110 is immersed in the water is that the part of the turbine 110 having the horizontal rotary shaft 112 according to the present invention is in the water- The rotation efficiency of the turbine 110 can be improved. This is to take advantage of the principle of Ekman spiral transport, as described above.

Secondly, if the turbine 110 according to the present invention is rotated in the state of being immersed in water, the blade plate 116 rotating at the upper portion with respect to the horizontal rotation axis 112 is rotated in the reverse direction with respect to the water flow, The rotation efficiency of the turbine 110 can be rapidly attenuated by the resistance caused by the resistance. That is, in order to prevent the resistance due to the water flow due to the reverse rotation of the vane plate 116, only a part of the turbine 110 is rotated in a state where it is locked to the water surface.

Accordingly, when only a part of the turbine 110 is rotated in a state of being locked to the water surface, the blade plate 116 fixed between the rotation discs 114 moves in the same direction as the flow of water in the water, The turbine 110 rotates in a direction opposite to the running direction of the flowing water with a density of about 800 times smaller than that of the turbine 110, .

Of course, the blade plate 116, which rotates in the direction opposite to the running direction of the water in the air above the water surface, may be influenced by the wind. However, considering the density of water and the rotational inertia, The influence of the wind can be removed by the lid portion 138 which will be described later.

 The float 130 in accordance with the present invention may comprise a buoyancy member 132, a connecting member 134, a mooring line 136, etc. to accomplish the functions and effects described above.

The buoyancy member 132 is a component provided to generate buoyancy so that only a part of the turbine 110 can be locked on the water surface and stably support the turbine 110 and the power generation unit 120 from external impact, 110 and the power generation unit 120 are symmetrical to each other and are provided as a pair.

Although the buoyancy member 132 may be made of a material such as foamed synthetic resin capable of generating buoyancy, the buoyancy member 132 according to the embodiment of the present invention may have a cylindrical shape with a hollow inside and a closed end at both ends. And the end of the buoyancy member 132 on the mooring line 136 side is formed into a semispherical shape protruding outward. The end of the hemispherical buoyancy member 132 is for preventing flow of the flowing water flowing toward the turbine 110.

In the embodiment of the present invention, one of the bumper members 132 is firmly coupled to the power generator 120, and the other bumper member 132 is supported by the bearing B such that the horizontal rotation shaft 112 can rotate Lt; / RTI >

The connecting member 134 is a component that is symmetric to both sides of the turbine 110 and the power generating unit 120 and is provided for connecting and fixing the pair of baffle members 132. The turbine 110, And front and rear (forward and backward) of the power generation unit 120, respectively, so that the buoyancy members 132 are firmly fixed to each other by fastening means such as bolts.

The mooring line 136 is a component provided to prevent the floating of the float 130 and float the float 130 in accordance with the flow of the flowing water. And the other end is connected to the offshore structure 10. The mooring line 136 according to the embodiment of the present invention is integrally fabricated together with a power line (not shown) that draws out electricity generated in the power generation unit 120 to the outside.

As shown in FIG. 5, the mooring line 136 is formed in a length having a slight margin between the offshore structure 10 and the float 130, And in the direction (2), the float 130 can move to the left side of the drawing.

At this time, since the mooring line 136 is connected to the end of the buoyancy member 132, the turbine 110 according to the present invention can naturally flow in the flow direction So that the rotation of the turbine 110 can be guided smoothly under the condition that lifting force and drag force by the water flow are applied.

Accordingly, the tidal generator 100 can smoothly flow along the mooring line 136 and the float 130 according to the present invention, and the turbine floats naturally on the surface of the water. Accordingly, even in a place where the flow of the flowing water changes instantaneously, The power generation through the rotation of the rotor 110 can be performed.

The offshore structure 10 may be connected to the submarine power line 11 to send electricity generated from the tidal power generator 100 according to the present invention to the outside.

Meanwhile, the buoyancy member 132 may further include a plurality of direction holding plates (not shown) protruding downward from the lower end thereof, so that the float 130 maintains a direction parallel to the flow direction The flow of water stably into the turbine 110 side causes a uniform and constant rotation of the turbine 110.

In addition, a belllt tank (not shown) formed of a partition (not shown) for partitioning a space may be installed in the hollow interior of the buoyancy member 132. By controlling the degree to which the turbine 110 is immersed in the water surface by adding or removing a heavy object such as water to the ballast tank through the opening formed at one side of the buoyancy member 132, the rotation efficiency of the turbine 110 can be appropriately maintained .

As shown in FIG. 6, the rotary disk 114 of the turbine 110 according to another embodiment of the present invention further includes a convex portion 114A protruding at a central portion of a surface facing each other. This makes it possible to apply the principle of continuation (the velocity of the fluid passing through the tube is small at a small cross-sectional area) to the turbine 110 according to the present invention, Thereby increasing the flow rate of the flowing water passing through the region and improving the rotation efficiency of the turbine 110.

7, the paddle type alga generator 100 according to another embodiment of the present invention includes a lid portion 138 provided with a receiving space for accommodating the turbine 110 and the power generation portion 120, (Not shown). This is to improve the rotation efficiency of the turbine 110 by preventing the turbine 110 exposed above the water surface from being affected by the wind.

The lid unit 138 may further include a position indicator 138A at the upper end thereof to prevent collision with the ship during operation.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is obvious to those who have. Accordingly, such modifications or variations should not be individually understood from the technical spirit and viewpoint of the present invention, and modified embodiments should be included in the claims of the present invention.

10: Offshore structure 100: Floating type bird generator
110: Turbine 112: Horizontal rotary shaft
114: rotating disk 114A:
116: wing plate 116A: plane portion
116B: curved portion 116C: vortex shedding hole
120: power generation section 122: rotor
124: stator 130: float
132: buoyancy member 134: connecting member
136: Mooring line 138:
138A: Locator light

Claims (10)

A power generating unit connected to the turbine and generating electricity; and a mooring unit including a turbine and a float provided on the surface of the power generation unit and moored on the water surface so that a part of the turbine is submerged in the water, As an algae generator,
The turbine,
A pair of rotary discs respectively coupled to both ends of the horizontal rotary shaft at the center, and a plurality of planar portions and curved portions formed on both sides of the rotary disc, A wing plate,
The sub-
A pair of buoyancy members symmetrically provided on both sides of the turbine and the power generation unit so that a part of the turbine is submerged in the water; A pair of connecting members symmetrically arranged on the front and rear sides of the turbine and the power generation unit to couple and fix the pair of buoyancy members to each other; And a mooring line having one end connected to the pair of the buoyancy member ends and the other end connected to the offshore structure so as to prevent the float from escaping and float the floating body in accordance with the flow of water,
Wherein the buoyancy member is formed in a cylindrical shape with a hollow inside and both ends closed, wherein the buoyancy member end on the mooring line side protrudes outward so as not to interfere with the flow of the water flowing from the buoyancy member end to the turbine Like shape,
Wherein the buoyancy member is further formed with a plurality of direction retention plates protruding downward from a lower end thereof so that the floating body can maintain a direction parallel to the flow direction. The method according to claim 1,
The wing plate
Three radial directions are formed at 120 ° around the horizontal rotation axis,
Characterized in that a vortex flow hole is formed in such a manner that the vane plate is spaced apart from the horizontal rotation axis by a predetermined distance so as to reduce vortex caused by flowing water on the inner space formed by the vanes adjacent to each other, . 3. The method of claim 2,
The rotating disk may include:
Wherein a protruding convex portion is further formed at a central portion of the surfaces facing each other so as to increase the flow rate of the flowing water passing between the pair of rotating discs. delete delete delete 4. The method according to any one of claims 1 to 3,
The power generation unit includes:
Wherein the at least one of both ends of the horizontally rotating shaft penetrates the turbine and generates electricity according to the rotation of the turbine. The method according to claim 1,
At the upper end of the float,
Further comprising a lid provided with a receiving space for receiving the turbine and the power generation unit so that the turbine exposed on the water surface is not affected by wind. 9. The method of claim 8,
The lid portion
Characterized in that a position indicator is further formed at an upper end thereof to prevent collision with a ship during operation. 3. The method of claim 2,
When the length between the horizontal rotation axis and the end of the blade is 100%
And the size of the vortex hole as a distance between the horizontal rotation axis and the vane plate is 25% to 30%.

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