KR101229932B1 - A tidal current power electronic power plant - Google Patents

Abstract

The present invention relates to a tidal current power generation device that flows according to the direction of movement of algae in the water, and can achieve continuous and effective development even when the flow of algae is weak or slow. The algae power generation device of the present invention is the algae inlet 211 for introducing the algae, the algae inlet is formed opposite the algae inlet 212, and the algae introduced through the algae inlet toward the algae outlet A housing 210 having a tidal flow passage 213 for flowing and a receiving space 214 formed at one side of the tidal flow passage; A rotating body 220 installed in the receiving space so that a part of the tide flow path is exposed, and having a plurality of rotary vanes that are rotated by the tide force flowing from the tide inlet and flowing along the tide flow path; And a generator 250 coupled to one side of the rotor to produce electricity by converting rotational kinetic energy of the rotor into electrical energy, wherein the algae inlet and the algae outlet are configured to have a wider cross-sectional area than the algae flow passage. .

Description

A tidal current power electronic power plant

The present invention relates to an algae power generation device using the flow of algae generated in the river or the sea, more specifically, flows in accordance with the direction of movement of algae in the water, and continuous and effective power generation even in the weak or slow flow of algae It relates to a tidal current power generation device that can achieve this.

Generally, the tidal power generator is a device that generates electricity by using water flow generated from the sea or river.

Algae power generation refers to generating electricity by installing a water turbine (turbine) at a high flow rate, and using natural algae flow as it is, trapping seawater in the dam and flowing it while turning a turbine using a free fall. It is distinct from tidal power generation.

And, a large number is known about the tidal current power generation device as described above, when one of them is described as shown in Figure 1, the generator 21 is buoyancy line 20 formed in the center; A fixing device that suspends the rope 24 to the bottom so that the buoyancy line 20 is stably stopped at a specific position, and a power generation wing 40 which is coupled to the shaft 41 and rotated by current flow; A wing support arm 30 formed at one end thereof with a wing support arm 30 pivotally coupled to the buoyancy line 20 at the other end thereof; A rotation gear 31 for rotating the wing support arm 30, a drive gear 33 coupled to rotate the rotation gear 31, and a drive motor for rotating the drive gear 33 forward and backward; A driving device composed of 34; The first sprocket 50 is integrally installed at the shaft end of the power generating wing 40, and the rotation shaft of the wing support arm 30 to transmit the rotational force of the power generating wing 40 to the generator 21 The second sprocket connected to the first sprocket 50 and the first chain 54 on an axis parallel to the 32), and the generator 21 to the second chain 55 while being integrally rotated on the same axis as the second sprocket. It consists of a power transmission device consisting of a third sprocket 52 and the like connected to.

However, such a conventional power generation device is fixedly installed in the sea or river, so the direction of buoyancy line does not change and the flow direction of the tidal current generated by the high tide and low tide is very difficult to use the power generation effect, There is a problem that cannot be used where the flow of algae is irregularly changed in all directions.

In addition, the conventional tidal current power generation device is a majority of the floating on the water surface part of the wing is submerged in water and part is located above the water surface to form a water wheel that rotates by the flow of water, wind or waves Slightly worse when hitting the power generation wing does not work smoothly there is a problem that the power generation efficiency falls.

In order to solve this problem, conventionally, a tidal force power generation apparatus has been disclosed to achieve power generation while flowing in a flow of algae. There is a problem of this deterioration.

Therefore, the present invention has been made to solve the problems of the prior art as described above, and always operates regardless of the flow direction or weather conditions of the algae, even when the flow of the algae is weak or slow rotational rotor of the rotor It is an object of the present invention to provide a tidal current power generation device that can achieve a continuous and smooth power generation by making it easy to rotate.

The algae power generation device of the present invention for achieving the above object, the algae inlet for introducing the algae, the algae discharge port formed to face the algae inlet and discharges the algae, algae introduced through the algae inlet A housing having a tidal flow passage flowing toward the discharge port and a receiving space formed at one side of the tidal flow passage; A rotating body installed in the receiving space so that a part of the tide flow path is exposed and having a plurality of rotary vanes which are rotated by the tide force flowing from the tide inlet and flowing along the tide flow path; And a generator coupled to one side of the rotor to produce electricity by converting rotational kinetic energy of the rotor into electrical energy, wherein the algae inlet and the algae outlet have a wider cross-sectional area than the algae flow passage.

The algae inlet of the present invention has a hopper structure in which the lateral cross-sectional area gradually decreases in a predetermined section toward the algae flow passage, and the algae outlet has a stepped structure in which the cross-sectional area of the algae flow passage increases in size. Can have

The rotating body of the present invention is a stand-alone rotating body of which a plurality of rotor blades are installed in one rotating member in the form of a spinning wheel, or two rotating members having different diameters, and connecting the two rotating members in a belt form, Rotating blades may be a plurality of rotating bodies each composed of a band rotatably installed.

The plurality of rotating bodies of the present invention may further have a rotation limiting member for limiting the rotation range of the rotary blade.

The housing of the present invention may further have a guide member which protrudes toward the tidal outlet and guides the rotor blade to be received in the receiving space in a folded state.

The accommodation space of the present invention may have a structure and size to move in a state in which the guided rotary blade is folded in the folded state to the maximum folded state to minimize the indirect and resistance to birds.

It is preferable that the plural rotary bodies of the present invention are inclined in the accommodation space of the housing.

The tidal inlet of the present invention may be further provided with a strainer made of holes of the same or smaller size than the size of the tidal flow passage.

The present invention may further include a direction control means for adjusting one side is fixed to the bottom surface and the other side is fixed to one side of the housing to adjust the direction of the algae inlet in accordance with the flow direction of the algae.

The present invention can achieve continuous operation of the rotating body even in a weak or slow flow of the bird through the structural improvement of the housing surrounding the rotating body, by allowing the direction to be actively switched according to the flow of the algae, forming the algae In almost every region wherever possible, there is always an excellent effect of achieving continuous and outstanding developments.

In addition, the present invention is configured so that the rotary blades constituting the rotating body is unfolded or folded within a predetermined angle range according to the flow direction of the bird, when the rotary wing is positioned opposite to the flow direction of the bird, the bird's nest spread out Maximize the resistance area of the rotor to increase the rotational force of the rotor, and in the case of a rotor blade that is not used to rotate the rotor can be folded in the receiving space to minimize the indirect and resistance to birds, It has the effect of maximizing the development effect.

In addition, the present invention constitutes a rotating member constituting the rotating body having a different diameter, when a large torque occurs in one of the rotating member has a large rotational speed in the other rotating member, the power generation effect through the rotating body Has the effect of improving.

1 is a view showing a conventional tidal power generation device.
Figure 2 is a view showing a separate stand-alone rotor of the tidal current generator according to the present invention.
3 is a view showing a combined state of FIG.
Figure 4 is a view showing the separation of the plural rotary bodies of the tidal current generator according to the present invention.
5 is a view showing a combined state of FIG.
6 is a view showing a cross-sectional state of FIG.
Figure 7a is an enlarged view showing the locking jaw and the stopper formed on the rotary blade and the band of the plurality of rotating bodies according to the present invention.
Figure 7b is an enlarged view showing the pedestal formed on the rotary blade of the plurality of rotating bodies according to the present invention.
8 is a view showing a use state in which the tidal current generator according to the present invention is installed on the buoyancy line.
9 is a view showing a direction adjusting means according to the present invention.
10 is a view showing a state of use of the tidal current generator according to the present invention installed on the water floor.

In the following, with reference to the accompanying drawings, a preferred embodiment of a tidal current generator according to the present invention will be described in detail.

As shown in Figures 2 to 10, the tidal current generator 200 according to this embodiment is composed of a housing 210, a rotor 220 and a generator 250 roughly.

The housing 210 is formed with an algae inlet 211 for introducing a flow of water, i.e., algae, which flows due to the high and low tide on one side thereof, and an algae outlet 212 for discharging the algae that flows to the other side of the housing 210. Is formed. In addition, the housing 210 has an algae flow passage 213 for flowing algae introduced through the algae inlet 211 toward the algae outlet 212.

Here, the algae inlet 211 and the algae discharge port 212 has a relatively large cross-sectional cross-sectional area compared to the algae flow passage 213, the algae inlet 211 and the algae outlet 212 is the same similar cross-sectional area It is configured to have. That is, the algae inlet 211 has a general hopper structure that the cross-sectional cross-sectional area gradually decreases in a predetermined section toward the algae flow passage 213, the algae outlet 212 is at the end of the algae flow passage (213) It has a stepped structure so that the size of the transverse cross-sectional area becomes large (see Fig. 6).

In the housing 210 of this embodiment, even though the algae flows into the algae inlet 211 somewhat slowly, when the algae flow passage 213 flows faster, the algae passes more strongly and the rotating body 220 is generated. Can be rotated quickly and strongly to increase the power generation effect. In addition, the housing 210 of this embodiment is the flow rate of the algae flowing along the algae flow passage 213 as the algae passing through the algae flow passage 213 is discharged faster through the algae discharge port 212 of a large cross-sectional area. In addition to maximizing and minimizing the vortex phenomena that can occur in the algae inlet 211 can maximize the power generation effect through the rotating body (220). That is, even when the flow of algae is slightly weak or slow, the rotating body 220 formed inside the housing 210 is easily rotated, so that in the water of almost all areas, such as rivers or the sea is always formed It is possible to make continuous and outstanding developments.

On the other hand, the housing 210 is configured to further have a receiving space 214 for receiving the rotating body 220 to one side of the flow path 213. Here, the accommodating space 214 receives approximately half of the rotating body 220 and has a form of exposing the remaining half toward the tidal flow passage 213. Accordingly, as the rotor blades 232 and 243 of the rotor blades 232 and 243 are exposed toward the bird flow passage 213, the rotor blades facing the direction of the flow of the birds expand the resistance area with the birds, thereby rotating the rotor 220. The rotational force of the, and the rotor blades (232, 243) accommodated in the receiving space 214 is minimized or no interference and resistance to birds. On the other hand, even if the rotor 220 is exposed toward the tidal flow path 213, the tidal flow path having a predetermined interval between the rotary blades (232, 243) of the rotor 220 and the bottom surface of the housing 210 ( 213) is formed to minimize the vortex phenomena of the algae and to maintain the power of the introduced algae. Here, the interval between the rotary blades 232, 243 and the bottom surface of the housing 210 is an element for determining the size of the strainer 211a to be described later.

By forming the receiving space 214 in the housing 210 as described above, the rotary blades (232, 243) moving in the reverse direction in the flow direction of the current flows from the rotary blades (232, 243) of the rotating body 220 It is accommodated in the receiving space 214 is made easier to rotate without being affected by the flow of algae.

Meanwhile, the algae inlet 211 has a size equal to or smaller than the cross-sectional area of the algae flow passage 213 formed between the rotary blades 232 and 243 of the rotor 220 and the bottom surface of the housing 210. A strainer 211a consisting of a (diameter) hole is provided. In this case, when the size of each hole is larger than the size of the algae flow passage 213, foreign matters such as seaweed and waste are introduced to block the algae flow passage 213 or hinder the smooth flow of algae. This can cause problems such as stopping power generation. However, when the size of each hole is smaller than the size of the cross-sectional area of the algae flow passage 213, even if foreign matter is introduced, it can be easily passed along the algae flow passage 213 and discharged through the algae discharge port 212. It is possible to maintain a smooth flow of algae.

Rotating body 220 is composed of a plurality of rotary blades 232 rotated by the flow of tidal current is a stand-alone rotary member 230 formed in one rotary member 231 in the form of a spinning wheel, or a plurality of rotary blades 243 ) Is formed in the band 242, the band 242 is composed of a plurality of rotating body 240 is connected to the two rotating members (241, 241a) to rotate.

In addition, a single generator 250 is directly coupled to the rotating member 231 of the independent rotor 230 to receive the kinetic energy obtained by the rotation of the rotary blade 232 is converted into electrical energy to produce electricity. .

In the plural rotary body 240, one side of the rotating member 241 has a large diameter, and the other side of the rotating member 241a is formed to have a smaller diameter than that of the one side of the rotating member 241. In addition, the plurality of rotating members 240 may be installed to be inclined in the housing 210, when the large diameter of the rotating member 241 is located in the front, the small diameter of the rotating member 241a is located in the rear Are arranged. In the configuration of the plural rotary bodies 240 as described above, the use of the rotating members 241 and 241a having different diameters, as the two rotating members 241 and 241a have different rotation gear ratios, This is because when a large torque is generated in the rotating member 241 or 241a, the power generating effect through the rotating body 240 can be improved by having a large rotating speed in the other rotating member 241 or 241a.

On the other hand, each of the rotary members 241 and 241a of the plurality of rotary bodies 240, the generator 250 for producing kinetic energy as electrical energy is respectively integrally coupled. Therefore, a more efficient rotational operation is performed on the flow of algae to improve the production efficiency of electricity.

Here, each of the rotating members 241 and 241a of the plurality of rotating bodies 240 is formed in the form of a roller or a sprocket, and bearings (not shown) are formed inside the rotating members 241 and 241a, and timing outwards. The band 242 is formed in a concave-convex shape such as a belt is configured to achieve a certain rotation.

On the other hand, by installing the plural rotator 240 inclined, since the rotary blade 243 is rotated faster and stronger from the flow of the bird than when installed in a horizontal state, it is possible to increase the power generation efficiency larger than that installed horizontally.

In addition, the band 242 is provided so that the rotary blade 243 is rotatable only within a predetermined angle range. That is, the rotary blade 243 is hinged to the band 242 is configured to expand or fold within a certain angle range in accordance with the flow direction of the bird. As shown in FIG. 7A, the band 242 includes a stopper 242a that constrains the rotation so that the rotary blade 243 does not fall back beyond an approximately vertical angle when the rotor blade 243 is positioned to face the flow direction of the tidal stream. It is formed, the locking projection 243a is formed on the rotary blade 243 is caught by the stopper (242a). In addition, as shown in Figure 7b, the hinge coupling portion of the rotary blade 243 may be provided with a pedestal 242b for limiting the rotation of the rotary blade 243 in contact with the surface of the band 242. That is, the plural rotators 240 of this embodiment may include a band 242 and / or a rotation limiting member such as a stopper 242a and a locking jaw 243a or a pedestal 242b for limiting the rotation range of the rotary blade 243. Or it is configured to have a rotary blade 243.

As the rotary blade 243 is configured to be rotatable only within a predetermined angle range as described above, when the rotary blade 243 is positioned to face the flow direction of the tidal flow, the rotary blade 243 is unfolded as much as possible and the resistance area with the tidal current is increased. Maximize the stiffening force of the rotating body 220, and when the rotary blade 243 is accommodated in the receiving space 214, the rotary blade 243 can be folded as much as possible to minimize the resistance area with the birds.

On the other hand, the housing 210 is a guide member for protruding toward the tidal discharge port 212 to guide the rotary blade 243 used to rotate the rotor 220 is accommodated in the receiving space 214 in a more smoothly folded state. 215 is installed. And, the receiving space 214 is formed in a structure and size that can minimize the indirect and resistance to the bird as the guided rotary blades 243 guided in the folded state to the folded state as possible as possible do.

The generator 250 is for generating electricity, and is integrally coupled to one side of the rotating body 220 to produce electricity by converting kinetic energy generated while the rotating blades 232 and 243 rotate by electric current into electrical energy. It plays a role. As such, the principle of the electric generator for converting the kinetic energy into electrical energy is already well known facts, so a detailed description thereof will be omitted.

The tidal current generator 200 of the present invention configured as described above is preferably formed to form a multi-layer in the vertical (vertical) direction or to form a multi-row in the horizontal (lateral) direction in order to produce more power. However, if necessary, it may be provided alone.

In addition, the tidal current power generation device 200 of the present invention is fixedly installed in the water, such as the sea or river in which tidal current occurs, or is installed to be able to flow to the bottom, side or the like of the buoyancy line 270.

In addition, when the tidal current power generation device 200 of the present invention is installed on the bottom or side surface of the buoyancy line 270 such as a barge floating in the sea or river and flowing by the flow of tidal current, the housing 210 is perpendicular to the housing 210. The connecting rod 280 for connecting to the buoyancy line 270 is installed, the cable (not shown) for storing the electricity produced through the generator 250 as a capacitor (not shown) inside the connecting rod 280 ) Is installed.

When the tidal current power generation device 200 is installed on the buoyancy line 270, only one side is fixed by using the front or the back such that the flow always flows in the direction of the tidal flow so that it is easily rotated according to the tidal flow. For example, the bottom is not pointed and is generally flat so that the direction of the tide can be changed freely.

FIG. 8 illustrates that the tidal current power generation device 200 is installed using the connection table 280 to form one or more layers in the vertical direction to increase power generation efficiency.

In addition, when the tidal current power generation device 200 of the present invention is installed in the underwater ground, it is configured to further have a direction adjusting means 260 for adjusting the direction of the tidal inlet 211 of the housing 210 along the flow of the tidal current. .

As shown in FIG. 9, the direction adjusting means 260 is a support 261 fixed to the ground and a motor 262 which is a power source formed in the upper end of the support 261 and formed to rotate in accordance with the flow of birds. ), A first gear 263 coupled to and interlocked with the motor 262, and a second gear 264 coupled to and interlocked with the first gear 263. Here, the shaft of the second gear 264 is preferably formed to be coupled to the housing 210 of the tidal current generation device 200 to interlock.

The direction control means 260 is provided with a time sensor (not shown) for adjusting the rotation angle of the motor 262 according to the flow direction of the tidal current. That is, the rotor 220 is rotated by the tidal force to rotate in the direction of producing electricity. For example, when the tide flows from left to right when the tide is high, the tide flows from the right to the left when the tide is low, so that the direction adjusting means 260 rotates 180 ° or 360 ° according to the tide flow. The time sensor is driven. As such, since the principle of a time sensor operating according to time is a well-known fact, a detailed description thereof will be omitted.

Referring to the working state of the present invention configured as described above are as follows.

First, the algae inlet 211 is fixedly installed in the water or the sea, such as the algae generated, or formed on one side of the housing 210 of the tidal current power generation device 200 is installed to flow on the bottom of the buoyancy line 270 As the algae flows in, the rotary blades 232 and 243 of the rotating body 220 formed inside the housing 210 are rotated. That is, the algae introduced at a low speed through the algae inlet 211 passes through the algae flow passage 213, the flow rate is increased, and rotates the rotary blades (232, 243) of the rotating body 220 at a high velocity. At this time, the rotary blade 243 is maximized to maximize the resistance area with the bird to strengthen the rotational force of the rotor 220. The generator 250 connected to the rotating members 231, 241, and 241a is operated by the rotational force of the rotating body 220 to receive rotational kinetic energy and convert it into electrical energy to produce electricity. As a result, the electric power produced by the generator 250 is sent to an associated facility unit (not shown) as necessary, and can be used in a general electric power demand facility.

On the other hand, when the rotary blade 243 for rotating the rotor 220 is no longer facing the flow direction of the algae is folded by the guide member 215, after minimizing the indirect and resistance with the algae The state moves along the accommodation space 214. In addition, the algae passing through the algae flow passage 213 is discharged faster through the algae discharge port 212 having a larger cross-sectional area than the algae flow passage 213, the flow rate of the algae flowing along the algae flow passage (213) In addition to maximizing and minimizing the vortex phenomena that can occur in the algae inlet 211 to maximize the power generation effect through the rotating body (220).

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications and equivalent changes to other embodiments are possible without departing from the technical spirit of the present invention. It will be apparent to one of ordinary skill in the art to which this invention belongs.

200: bird power generation device 210: housing
211: bird inlet 211a: hook network
212: algae outlet 213: algae flow passage
214: accommodation space 215: guide member
220: rotating body 230: stand-alone rotating body
231: rotating member 232: rotating blade
240: plural rotating bodies 241, 241a: rotating member
242: band 242a: stopper
242b: pedestal 243: rotary blade
243a: jaw 250: generator
260: direction control means 261: prop
262: motor 263: first gear
264: second gear 270: buoyancy line
280: connecting rod

Claims (10)

In tidal current power generation apparatus installed in water,
Algae inlet for introducing algae, Algae outlet formed opposite to the algae inlet, and Algae outlet for discharging the algae, Algae flow passage for flowing algae introduced through the algae inlet toward the algae outlet, and the algae flow passage A housing having a receiving space formed at one side of the;
A rotating body installed in the accommodation space so that a portion of the tide flow path is exposed, and having a plurality of rotary blades which are rotated by the tide force flowing from the tide inlet and flowing along the tide flow path; And
Is coupled to one side of the rotating body includes a generator for producing electricity by converting the rotational kinetic energy of the rotating body into electrical energy,
The algae inlet and the algae outlet have a wider cross-sectional area than the algae flow passage,
The rotating body is a plurality of rotating members consisting of two rotating members having a different diameter, and a band connecting the two rotating members in the form of a belt, the plurality of rotating wings are rotatably installed on the surface, respectively. Tidal power generator. The method according to claim 1,
The algae inlet has a hopper structure in which the lateral cross-sectional area gradually decreases in a predetermined section toward the algae flow passage, and the algae outlet has a stepped structure in which the cross-sectional area of the algae flow passage increases in size. Bird power generator, characterized in that having a. delete delete The method according to claim 1 or 2,
The plural-type rotating body further comprises a rotational limiting member for limiting the rotation range of the rotary blades. The method according to claim 5,
And the housing further includes a guide member which protrudes toward the tidal outlet and guides the rotary vane, which was used to rotate the plurality of rotary bodies, to be accommodated in the accommodation space in a folded state. The method of claim 6,
The accommodating space is a tidal current generation device having a structure and size to move in a state that minimizes the indirect and resistance to the bird in the folded state guided in the folded state by the guide member to the maximum folded. The method of claim 7,
The plural-type rotating body is a tidal current generator, characterized in that installed inclined in the accommodation space of the housing. The method according to claim 1 or 2,
The tidal current power generation device is characterized in that the tidal inlet is further provided with a sieve made of a hole of the same or smaller size than the size of the tide flow passage. The method according to claim 1 or 2,
One side is fixed to the bottom surface and the other side is fixed to one side of the housing tidal current generation apparatus characterized in that it further comprises a direction control means for adjusting the direction of the algae inlet in accordance with the flow direction of the algae.

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