KR101261780B1 - A generating module for following a tidal current and a generating apparatus having the same - Google Patents

Abstract

PURPOSE: A tidal current following type generating module and a generating apparatus including the same are provided to rotate a water turbine support according to a tidal current direction, thereby maximizing generating efficiency and minimizing resistance. CONSTITUTION: A tidal current following type generating module and a generating apparatus including the same comprises a first water turbine(110), a second water turbine(120), a water turbine support(130), and a rotation force delivery unit(140). The water turbine support includes a shaft(131), a left side(132), a bottom side, a right side(133), and top and bottom surfaces. The first water turbine includes a first rotating shaft(111) and several first water vanes(113). The second water turbine is installed in parallel and adjacently to the first water turbine and comprises a second rotating shaft(121) and several second water vanes(123). The rotation force delivery unit rotates the generating shaft of the support by receiving rotation power from a pair of the water turbines.

Description

A tidal current type power generation module and a power generation apparatus including the same {A generating module for following a tidal current and A generating apparatus having the same}

The present invention relates to a tidal current type power generation module and a power generation apparatus including the same, and more particularly, a tidal current type power generation module that can be generated by moving in accordance with the direction of the current and always generating a rotational force regardless of the direction of the tidal current and the same It relates to a power generation device that includes.

Algae power generation refers to the production of electrical energy from the flow of algae by installing a water turbine (turbine) where the water in the ocean is fast. It uses natural tidal flow as it is, and it is separated from tidal power generation, which traps and flows seawater to the dam and uses turbines to turn the turbines into electricity.

Algae generation is an environmentally friendly alternative energy system that does not need to block dams to secure reservoirs (George), free ships, does not interfere with fish movement and does not affect the surrounding ecosystem.

The ocean, which occupies 70% of the earth's surface, has infinite natural clean energy. Among them, the algae generated by the difference of tides can generate energy by using two low tide and two high tide regularly every day. The characteristic of such tidal power generation is that the amount of energy per unit area is large, and tidal current is generated near the land, so it is convenient to use, and the same facility can be used in the river flowing inland.

Since algae flows in a constant area, algae energy can be said to be an infinitely clean energy that can be predicted to some extent and depleted no matter how much it is used with solar energy.

Although algae in Korea's coast are abundant, the strong algae around 10km / s are small in number, and the algae of low flow rate are less than that. Even relatively low tidal currents of around 3km / s should produce electricity without damming the dams or damaging nature.

Although there are propellers and aberrations as a device to convert tidal currents into rotational force, the propellers must be limited and magnified due to the characteristics of the vane face, but the coastal environment of Korea is inadequate to install propellers that must be magnified due to low depth. Since the working fluid has a rectangular structure on the vane surface, the amount of energy absorbed by the dispersed energy cannot exceed 25%. The plate of the aberration allows the mass of the mass flow energy to be absorbed because the fluid can act vertically, but as shown in FIG. There was a problem that the rotation direction is opposite to the tide direction, the efficiency is lowered.

Related patent documents include Japanese Laid-Open Patent Publication No. 2011-033019, Korean Registered Patent No. 1046917, and the like.

 The present invention is to solve the above problems, an object of the present invention is to install a pair of aberrations adjacent to overlap and to prevent the flow of algae in the overlapping portion and to meet the algae in the non-overlapping portion, and also in the direction of the algae Accordingly, the aberration support is rotated to provide an algae driven power generation module that maximizes the power generation efficiency and minimizes the resistance of the algae.

Another object of the present invention is to provide a bird-driven power generation device that can be installed in a variety of locations, such as sea level, underwater, seabed by installing a plurality of tidal wave power generation module to be supported on the matrix support.

Bird-driven power generation module according to the present invention for achieving the above object,

A support center axis 131, a left side 132 extending at a predetermined angle from the support center axis 131, and extending at an angle from the support center axis 131 symmetrically with the left side 132. The right side 133 and the bottom side 134 connecting the left side 132 and the right side 133 and the left side 132 and the right side 133 and the bottom side 134 are respectively installed to seal the upper and lower ends thereof. An aberration support 130 having an upper and lower surfaces 136, a portion of which extends from the base 134; Upper and lower ends of the first rotation shaft 111 fixedly coupled to one side of the upper and lower surfaces 136 of the aberration support 130, and a plurality of first aberration blades 113 rotating around the first rotation shaft 111. A first aberration 110 including; A second rotary shaft 121 installed in parallel with the first aberration 110 and fixedly coupled to the other side of the extended upper and lower surfaces 136 of the aberration support 130; and the second rotary shaft 121 A second aberration 120 including a plurality of second aberration wings 123 rotating about the center; And a rotational force transmission unit 140 installed on the upper surface 135 of the aberration support 130 to receive rotational power from the pair of aberrations 110 and 120 so as to rotate the support development shaft 137. Each of the first and second aberration blades 113 and 123 is installed so that a portion thereof is exposed out of the base 134, and the exposed first and second aberration blades 113 and 123 are opposite to each other by a bird. Rotate

The support power generation shaft 137 is positioned inside the support central axis 131 to form a concentric axis, and the support center axis 131 is a rotation center so that the aberration support 130 changes direction according to a tidal current. This is configured to move along the bird together with the pair of aberrations 110 and 120 and the aberration support 130 integrally.

In addition, a part of each of the first and second aberration blades 113 and 123 located inside the bottom side 134 of the aberration support 130 is installed so that the rotation radius thereof overlaps each other.

The plurality of aberration blades 113 and 123 of each of the aberrations 110 and 120 are installed at right angles with respect to the rotation shafts 111 and 121, and each of the aberration blades 113 is coupled to the rotation shaft 111 and extends from the rotation shaft. It is installed so as to include a plurality of wing support 114 is installed in the height direction of the rotary shaft 111, and a wing plate 115 is installed to be supported by the plurality of wing support (114).

On the other hand, on the upper surface 135 of the aberration support 130, the intermediate support shaft 138 located between the first rotary shaft 111 of the first aberration 110 and the second rotary shaft 121 of the second aberration 120 ) Is installed, the rotational force transmission unit 140, the first aberration sprocket 141 formed on the first rotation shaft 111 of the first aberration 110; An intermediate support shaft sprocket 142 formed on the intermediate support shaft 138; A second aberration sprocket 143 formed on the second rotation shaft 121 of the second aberration 120; A support shaft development sprocket 144 formed on the support shaft 137; A first chain 145 connected to the first aberration sprocket 141 and the intermediate support shaft sprocket 142 to transmit the rotational force of the first aberration sprocket 141 to the intermediate support shaft sprocket 142; And a second chain 146 connected to the second aberration sprocket 143 and the support shaft shaft sprocket 144 to transmit rotational force of the second aberration shaft sprocket 143 to the support shaft shaft sprocket 144; It includes. Some paths of the second chain 146 are positioned to contact the intermediate support shaft sprocket 142 to receive the rotational force of the first intermediate support shaft sprocket 142, so that the rotational force of the first aberration and the second aberration is added. It is transmitted to the support shaft shaft sprocket 144 through the second chain 146.

The intermediate support shaft sprocket 142 may include a first intermediate support shaft sprocket 142a installed in parallel with the first aberration sprocket 141 and connected to the first chain 145, and the first intermediate support shaft sprocket 142. 142 is installed to be located below, and includes a second intermediate support shaft sprocket 142b installed in parallel with the second aberration sprocket 143 to be in contact with a part of the path of the second chain 146.

The inner space sealed by the left side 132, the right side 133, the bottom side 134, and the upper and lower surfaces 136 of the aberration support 130 is configured to be empty so that the aberration support 130 performs a function of buoyancy. do.

On the other hand, the bird-driven power generation module according to the present invention is connected to the support shaft generation shaft 137 rotated by the rotational force transmission unit 140, and is connected to an external generator or an external hydraulic device to provide a power generation power It further includes a delivery unit (150).

On the other hand, according to the present invention for achieving the above-mentioned bird-driven power generation device, the bird-driven power generation module 100; The bird driving type power generation module 100 includes a row support 220 for supporting it so as to constitute a plurality of rows or a plurality of columns, and the bird driving type power generation module 100 supported by the row support 220 is adjacent to each other. Are arranged so as not to overlap each other for the tidal current driven module 100 and the tidal direction of the column or row.

The algae driven generator is installed at various locations such as sea level, underwater or seabed.

As described in the present invention, according to the bird-driven estrous module and the power generation apparatus according to the present invention, the aberration support is rotated and moved so as to face the bird direction with the support center axis as the rotational center, and a part of the pair of aberration wings is in the bird direction. By installing it on the aberration support so that the remaining part is not exposed and the remaining part is not exposed, there is an advantage that the power generation efficiency can be improved by being always rotatable and receiving a minimum resistance regardless of the direction of the bird. . In addition, there is an advantage that can improve the power generation efficiency by installing the rotation axis of the aberration layer and separately installing the intermediate support shaft to transmit the sum of the rotational force of both aberrations to the support power generation shaft by an appropriate combination thereof. In addition, it is possible to adjust the buoyancy of the algae driven power generation module by making the inside of the triangular support of the aberration support empty and inserting various buoyancy control materials therein, so that it can be applied to various locations according to the environment such as sea level, underwater, and water table. It can be effective.

1 is a view showing the direction of rotation of the aberration and the direction of the aberration during the rotation of the aberration,
Figures 2a and 2b is a perspective view seen from one direction and the other direction of the bird-driven power generation module according to an embodiment of the present invention,
3 is a plan view of a tidal current type power generation module according to an embodiment of the present invention;
4 is a side view of the bird-driven power generation module according to an embodiment of the present invention;
5 is a view showing a state in which the first and second aberrations are removed in FIG. 2A;
6 is an enlarged perspective view of a first aberration of the tidal current driving module of FIGS. 2a and 2b;
Figure 7 is an enlarged perspective view of the rotational force transmission unit of the tidal current driving module of Figures 2a and 2b,
8 is an enlarged perspective view of a power generating unit of the tidal current driving module of FIGS. 2a and 2b;
9 to 11 are perspective views of aberrations according to other embodiments of the present invention,
12 is a view for explaining the operation of the bird-driven power generation module according to an embodiment of the present invention;
13 to 14 is a view showing a bird-driven power generation apparatus according to an embodiment of the present invention,
15 and 16 is a view showing a state in which the algae driving type power generation apparatus according to an embodiment of the present invention is installed on the sea surface and the sea floor,
17 is a view for explaining the operation of the overload hydraulic power generation unit according to an embodiment of the present invention.

The above objects, features and other advantages of the present invention will become more apparent by describing the preferred embodiments of the present invention in detail with reference to the accompanying drawings. Hereinafter, a bird driving type power generation module and a power generation apparatus including the same according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2a is a perspective view from one direction of the bird-driven power generation module according to an embodiment of the present invention, Figure 2b is a perspective view from the other direction, Figure 3 is a plan view, Figure 4 is a side view.

Bird driven type power generation module 100 according to an embodiment of the present invention, the aberration support 130, a pair of first aberration 110 and the second aberration 120, the rotational force transmission unit 140, power generation transmission It is configured to include the unit 150.

FIG. 5 illustrates a state in which the first and second aberrations 110 and 120 are removed from FIG. 2A to facilitate the description of the aberration support 130. 2A to 5, the aberration support 130 includes a cylindrical support center axis 131 having a predetermined diameter, a left side 132 extending at an angle from the support center axis 131, and a left side ( 132 symmetrically with respect to the right side 133 extending at an angle from the support center axis 131, the bottom side 134 connecting the left side 132 and the right side 133, the left side 132 and the right side ( 133 and the bottom side 134 are respectively installed to seal the upper and lower ends, and a portion thereof is configured to include an upper surface 135 and a lower surface 136 extending from the lower side 134.

As shown, the aberration support 130 has the support center axis 131 as a triangle vertex, and has a triangular prism shape by the surfaces of the left side 132, the right side 133, and the bottom side 134. On the other hand, the left side 132 and the right side 133 has a streamlined curved surface rather than a plane, which is to minimize the frictional force with the algae because the left side 132 and the right side 133 is hit by the flowing algae. On the other hand, the inside of the triangular prism is sealed by the upper surface 135 and the lower surface (136). Therefore, since the inside of the triangular prism constitutes a closed community and functions as a buoyancy cylinder, the aberration support 130 can float the tidal current driven power generation module 100 according to the present invention in the sea. To provide buoyancy. To increase buoyancy, you can put materials such as air, styrofoam, and plastic inside the triangular prism as needed.

The upper surface 135 and the lower surface 136 are installed so that a portion thereof extends from the lower side 134, and the first and second aberrations 110 and 120 on the sides of the extended upper surface 135 and the lower surface 136. Shaft holes into which the rotary shafts 111 and 121 of the aberrations are inserted are formed so as to be coupled to each other. On the other hand, the lower surface of the upper surface 135 is provided with an auxiliary upper surface (135a) extending from the rotor to the base 134. In addition, the upper surface 135 is provided with an intermediate support shaft 138 positioned between the first rotary shaft 111 of the first aberration 110 and the second rotary shaft 121 of the second aberration 120. The intermediate support shaft 138 is installed to be supported only on the upper surface, unlike the first rotation shaft 111 and the second rotation shaft 121.

In the aberration support 130 having the above structure, the support central axis 131 forming the vertex of the triangular prism is directed in the direction in which the current flows. That is, since the left side 132 and the right side 133 extending from the support center axis 131 are closed surfaces, the resistance by the tide is large, and the support center axis 131 receives the least resistance, and thus the support center axis 131. It will be located in the direction of the flow.

Referring back to FIGS. 1 to 4, the first aberration 110 has a first rotary shaft 111 fixedly coupled to one side of the upper and lower surfaces 136 of the upper and lower ends of the aberration support 130, and the first rotary shaft 111. It has a plurality of first aberration blades 113 to rotate about. The second aberration 120 includes a second rotary shaft 121 fixedly coupled to the other side of the upper and lower surfaces 136 extending from the upper and lower ends of the aberration support 130, and a plurality of second rotations about the second rotary shaft 121. The aberration wing 123 is included. The first aberration 110 and the second aberration 120 are located in a position corresponding to the bottom surface 134 of the aberration support 130 and are installed in parallel to each other and have the same configuration, so that the first aberration ( Only the configuration of 110 will be described.

Referring to FIG. 6, the first aberration 110 includes a first rotational shaft 111 and a plurality of first aberration wings 113. The first aberration blades 113 are installed at equal intervals around the first rotation shaft 111. The first aberration blade 113 is again coupled to the first rotary shaft 111 and the wing support 114 is installed to extend radially from the first rotary shaft 111, and the wing plate is supported to be supported by the wing support 114 It consists of 115. The wing support 114 is provided in plurality in a predetermined interval in the height direction of the first rotation shaft 111, the wing plate 115 is installed to be connected to the plurality of wing support 114. On the other hand, the wing plate 115 has the shape of a semi-cylindrical hollow inside, the impingement to the concave space inside the cylinder of the wing plate 115 with respect to the direction in which the flow of the bird will eventually rotate the aberration blades. The shape of the aberration wing, in particular the wing plate of the present invention is not limited to this embodiment and may have various shapes, which will be described later. In addition, in this embodiment, three aberration blades are not illustrated, but the present invention is not limited thereto and may be installed in various numbers as long as the rotation is not hindered.

Meanwhile, referring to FIGS. 2 to 4, some of the plurality of aberration wings 113 and 123 are installed to be exposed out of the bottom side 134. That is, a part of the first aberration blade 113 of the first aberration 110 is exposed in the left direction of the bottom side 134, that is, the left side 132 direction, and the second aberration wing 123 of the second aberration 120. A portion of is exposed to the right side of the bottom side 134, that is, the right side 133 direction. In addition, a part of the first aberration blade 113 and a part of the second aberration blade 123 inside the bottom side 134 (facing the bottom side) are positioned so that their rotation radii overlap each other. The radius of rotation does not overlap, that is, it can be configured to increase the distance between the axis of rotation (111, 121) of each aberration, but in this case the length of the base side 134 becomes large, the volume of the aberration support 130 is eventually increased, In addition, since the area where the aberration blades are exposed to the algae is increased, the resistance of the aberration is increased. Therefore, a part of the first aberration blade 113 and the second aberration inside the base 134 as in the present embodiment are generated. Part of the blade 123 is preferably located so that the rotation radius of each other overlap.

On the other hand, as shown, each of the wing plates (115, 125) of the exposed first and second aberration blades (110, 120) are installed to be located in the opposite direction to each other, eventually the first aberration blade (113) and the second The aberration blades 123 rotate in opposite directions, which will be described later.

Rotational force transmission unit 140 is installed on the upper surface 135 of the aberration support 130 to receive the rotational power from a pair of aberrations (110, 120) to rotate the support shaft (137), Figure 7 For reference, the rotational force transmitting unit 140 includes a first aberration sprocket 141 formed on the first rotation shaft 111 of the first aberration 110 and an intermediate support shaft sprocket 142 formed on the intermediate support shaft 138. And a second aberration sprocket 143 formed on the second rotation shaft 121 of the second aberration 120, a support shaft power shaft sprocket 144 formed on the support shaft 137, and a first aberration sprocket ( The first chain 145 and the second aberration sprocket 143 and the support that are connected to the 141 and the intermediate support shaft sprocket 142 to transfer the rotational force of the first aberration sprocket 141 to the intermediate support shaft sprocket 142. The second chain 146 is connected to the power generation shaft sprocket 144 to transmit the rotational force of the second aberration sprocket 143 to the support power generation shaft sprocket 144. The. That is, the first aberration sprocket 141 and the first intermediate support shaft sprocket 142a of the intermediate support shaft sprocket 142 are parallel, and the second intermediate of the second aberration sprocket 143 and the intermediate support shaft sprocket 142. The support shaft sprocket 142b is parallel.

Meanwhile, the intermediate support shaft sprocket 142 has two sprockets 142a and 142b formed to have a layer. Specifically, a first sprocket 142 is installed to be parallel to the first aberration sprocket 141 and connected to the first chain 145. An intermediate support shaft sprocket 142a and a lower intermediate portion of the first intermediate support shaft sprocket 142 installed in parallel with the second aberration sprocket 143 to contact a part of the path of the second chain 146. It consists of two intermediate support shaft sprockets (142b). Accordingly, some paths of the second chain 146 are positioned to contact the second intermediate support shaft sprocket 142b, and are coaxially installed with the second intermediate support shaft sprocket 142b and operate together with the first intermediate support shaft sprocket. The rotational force of 142a is transmitted through the second chain 146. As a result, the rotational force by the first aberration 110 and the second aberration 120 is combined with the second chain 146 to be transmitted to the support shaft shaft sprocket 144.

Referring to FIG. 8, the power generating unit 150 is connected to the support generating shaft 137 and is connected to an external generator or an external hydraulic device.

The support shaft development shaft 137 is provided with the above-described support shaft development sprocket 144, and thus the support shaft development shaft 137 is rotated by receiving the rotational force by the second chain 146 of the rotational force transmission unit 140. . As shown, the support power generation shaft 137 is installed in the support central axis 131 and is concentric with the support central axis 131, but the support central axis 131 is fixed to the aberration support 130 to be installed. In contrast, the support generating shaft 137 has a movable type that operates to rotate as described above. Here, the support center axis 131 is fixed does not mean that it does not move at all, but does not rotate about the center as the support shaft 137, as described above, the support center axis 131 is aberration support As described above, the aberration support 130 serves as a center of rotation so as to change the direction according to the bird 130 as a body. The support power generating shaft 137 may be installed in a separate position, but considering the miniaturization and efficiency of the device, the stability of the components, and the like, the support power generating shaft 137 is formed inside the support central shaft 131. It is preferably installed in.

The generating force transmission unit 150 is connected to the support generating shaft 137 which receives the rotational power generated from the pair of aberrations 110 and 120, and as shown in the example, the bevel gear 152 to the supporting generating shaft 137. The bevel gear 152 is connected to the rotary shaft 153 of the generator (not shown) to eventually enable the generator to operate by the rotation of the generator rotary shaft 153. Although bevel gears are shown, worm gears or helical gears having similar functions may be applied. As another example, the hydraulic pump 155 is installed on the support power generating shaft 137 and the hydraulic hose 156 is connected to the hydraulic pump 155, through the hydraulic hose 156 (land or sea). Can be sent to the generator to drive the generator. Although the embodiments of the present invention have described some examples of the power generation unit 150, the present invention is not limited thereto and may be connected to the support generating shaft 137 to apply various methods of transmitting rotational force or hydraulic pressure to the generator. Of course.

As described above, in the present invention, the aberration has revealed that various embodiments may be applied, and FIGS. 9 to 11 illustrate other embodiments of the aberration 160 to 180 in the tidal current driven module. The configuration of the aberration is the same that the rotation shaft and the aberration blades are the same, but a plurality of aberration wings are the same, but the shape and shape of the wing plate of the aberration wings are different from each other.

Aberration 170 according to another embodiment of the present invention shown in Figure 9 includes a rotation shaft 171, aberration blades 173 composed of the wing support 174 and the wing plate 175. The wing plate 175 has a shape of a semi-square pyramid with an empty inside. The aberration wing plate 115 (refer to FIG. 6) according to an embodiment of the present invention and the aberration plate 175 according to another embodiment of the present invention constitute an empty space inside, and the concave portion of the empty space is a bird. It is installed to face in the direction of the flow, so that when the bird strikes the aberration wing, the bird gathers in the empty space inside to gather the force of the bird so that the aberration wing rotates. Therefore, according to the present invention, the wing plate may have various polygonal pyramid shapes such as triangular pyramids, pentagonal pyramids, hexagonal pyramids, and the like.

Aberrations 160 and 180 according to still another embodiment of the present invention shown in FIGS. 10 and 11 are also aberrations consisting of the rotary shaft (161, 181), wing supports (164, 184) and wing plates (165, 185) Wings 163 and 183. The wing plates 165 and 185 have a planar shape, and a plurality of wing plates 165 and 185 are installed in the longitudinal direction on one aberration wings 163 and 183, and each wing plate 165 and 185 is provided in a vertical direction. ) Is configured to be rotatable about the rotation shafts 165a and 185a coupled to the wing supports 164 and 185. Here, the wing plate (165 ', 185') is closed when some of the aberration wing hit the bird, the aberration wing is rotated by the force, wing plate (165 '' of the other aberration wing that does not hit the bird, 185 '') open to receive a small resistance.

Hereinafter, with reference to Figure 12, the operation of the bird-driven power generation module according to an embodiment of the present invention having the above configuration will be described.

The algae flowing in the direction of the arrow branches from the support central axis 131 of the aberration support 130, and flows in the direction of arrow B along the right side 133 in the direction of arrow A along the left side 132. As described above, the support central axis 131 moving integrally with the aberration support 130 is positioned in the direction in which the current flows. The algae flowing in the direction of the arrow A hits the first aberration blade 113 of the first aberration 110 and the algae flowing in the direction of the arrow B hits the second aberration wing 123 of the second aberration 120. Here, each of the aberration blades 113 and 123 is disposed so that the concave portion of the wing plate collides with the bird to be rotated by the bird. Therefore, the first aberration blade 113 rotates in the arrow X direction (counterclockwise direction), and the second aberration blade 123 rotates in the arrow Y direction (clockwise direction).

The first aberration sprocket 141 installed on the first rotation shaft 111 by the rotation of the first aberration blade 113 rotates in the direction of the arrow X (counterclockwise) and is connected to the first aberration sprocket 141. The rotational force of X 'is transmitted to the intermediate support shaft sprocket 142 installed on the intermediate support shaft 138 through the chain. On the other hand, the second aberration sprocket 143 installed on the second rotary shaft 121 by the rotation of the second aberration blade 123 is rotated in the direction of the arrow Y (clockwise), the second aberration sprocket 143 Through the two chains 146 to transmit the rotational force of the Y 'to the support shaft shaft sprocket 144. In this case, since the second chain 146 is in contact with the intermediate support shaft sprocket 142 in some paths and receives a rotational force, the support chain shaft shaft sprocket 144 has a second aberration of the first aberration blade through the second chain 146. The rotational force of X '+ Y', which is the sum of the rotational force and the rotational force of the second aberration blade, is transmitted. do.)

As described above, according to the current-driven power generation module according to the present invention, the aberration support is rotated and moved so as to face the tide direction with the support center axis as the rotational center, and a part of the pair of aberration wings is exposed to the tide direction. By installing the rest on the aberration support so as not to be exposed to minimize the algae resistance, there is an advantage to improve the power generation efficiency by being always rotatable regardless of the direction of the algae received a minimum resistance. In addition, there is an advantage that can improve the power generation efficiency by installing the rotation axis of the aberration layer and separately installing the intermediate support shaft to transmit the sum of the rotational force of both aberrations to the support power generation shaft by an appropriate combination thereof.

13 to 16 show embodiments of the tidal current type power generation apparatus 200 to which the tidal current type power generation module 100 is applied. The algae driven power generation apparatus 200 according to the embodiment of the present invention is coupled to the column support 220 is configured to support a plurality of algae driven power generation module 100 in at least one row or / and at least one column. It can be applied in various forms. For example, as illustrated in FIG. 13, the plurality of tidal current type power generation modules 100 are arranged in a single column, coupled to and supported by the row support 220, and as illustrated in FIGS. 14A and 14B. Three bird driven power generation module 100 is arranged to have a plurality of rows and a plurality of columns form is coupled and supported by the row support 220. Here, it should be noted that each tidal current type power generation module 100 coupled to the row support 220 does not overlap each other for the tidal direction with other tidal current type power generation modules in a column or row adjacent to each other, that is, so as not to overlap each other. It is preferable to arrange. On the other hand, each tide driving type power generation module 100 is installed so that the support center axis 131 of the aberration support is rotatable in the row support 220, each tide driving type power generation module 100 is rotated according to the tidal current Facing in the direction of the flow of algae. In addition, the support generating shaft 137 is positioned to be exposed to the upper portion of the row support 220, so that the rotational power can be transmitted to the outside. An external generator can be individually connected to each tidal current generation module 100, or as shown in the drawing, the rotational forces of a plurality of tidal current generation power generation modules 100 supported in one row or column are combined with each other. Of course, it can be connected to the generator, of course, can be applied in various ways depending on the arrangement of the bird-driven power generation module. As described above, the algae driven power generation device has the advantage of being stably installed in a strong algae by installing a plurality of algae driven power generation modules fixed to the row support 220.

On the other hand, since the flow rate or flow of algae is different depending on the position of the bottom or the upper floor of the sea, the algae driven power generation apparatus according to the present invention can be applied to the environment by adjusting the installation position by buoyancy according to the position There is this. As described above, the triangular prism of the aberration support of the bird-driven power generation module 100 is formed as an empty space, so that buoyancy can be adjusted by appropriately inserting buoyancy control materials such as air, styrofoam, and plastics therein. . Figure 15 shows that the algae driving type generator according to the embodiment of the present invention is installed on the sea surface, Figure 16 shows that the algae driving type generator is installed on the seabed.

On the other hand, it is possible to produce electricity from a central generator (not shown in the city) installed on land or at sea without turning the generator directly from the tidal drive type generator installed in the sea or the sea, thereby preventing the trouble of the generator or underwater insulation. It can be overcome. In addition, when hydraulic pressure is supplied to a central hydraulic system (not shown) installed on the sea or on land by using a hydraulic system, the flow of water flows alternately with a low tide and a high tide twice a day due to the nature of the tide. -Since the flow rate of the tank is changed and the flow rate difference between the peak and the peak is big, it is necessary to solve the problem due to the overload of the generator. In addition, when the device according to the present invention is installed in the river, the flow rate such as a typhoon or a storm increases suddenly changes the flow rate, the moment the hydraulic pressure is excessively large and turns the generator, the generator is damaged or a failure due to overload. In order to solve this problem, when hydraulic pressure is supplied to a central hydraulic apparatus (not shown) installed on the sea or on land using a hydraulic apparatus, as shown in FIG. Forming and installing generators in each flow path diverges excessive hydraulic pressure into multiple flow paths to prevent excessive hydraulic pressure from concentrating on one generator.

17 shows an embodiment of the overload hydraulic power generation unit 70 according to the present invention. The overload hydraulic power generation unit 70 includes a plurality of flow passages 77a to 77c for dividing the hydraulic pressure flowing from the inlet 72, and a plurality of generators 71 installed at each of the plurality of flow passages 77a to 77c; It is composed of a plurality of check valves (74a ~ 74c) is installed in the vicinity of the inlet (72) of the plurality of flow paths (77a ~ 77c) selectively open at least one according to the strength of the hydraulic pressure introduced. In the drawing, a plurality of check valves 74a to 74c are divided and displayed as 74a, 74b and 74c, respectively. However, a representative mark 74 is indicated when referring to the whole without specifying any one. The same applies to other codes.

The plurality of flow paths 77 allow the hydraulic pressure flowing through the inlet 72 to flow by partial pressure. Check valves 74 provided at each of the inlets of the plurality of flow paths 77 are opened and closed according to the size of different hydraulic pressure. That is, the first check valve 74a is opened when the hydraulic pressure is P0, the second check valve 74b is opened when the hydraulic pressure is P1, and the third check valve 74c is opened when the hydraulic pressure is P3. The hydraulic pressure may be set as P0 = 1 / 2P1 = 1/3 P2. For example, when the hydraulic pressure of P0 flows from the inlet 72, only the first check valve 74a is opened and the second and third check valves ( 74b and 74c remain closed. When the hydraulic pressure corresponding to three times P0 flows in, the third check valve 74c is closed and only the first and second check valves 74a and 74b are opened to open the first flow path 77a and the second flow path ( 77b) each has a fluid having a hydraulic pressure of 1.5 P0. However, the present invention is not limited to this, and each check valve can be opened by, for example, the same hydraulic pressure. When a large amount of hydraulic pressure flows in such a way, the oil pressure is divided into multiple flow paths so that the hydraulic pressure flows by a sudden weather change such as a typhoon or a storm. Can be prevented.

Although the preferred embodiments of the present invention have been described, the present invention is not limited to the specific embodiments described above. It will be apparent to those skilled in the art that numerous modifications and variations can be made in the present invention without departing from the spirit or scope of the appended claims. And equivalents should also be considered to be within the scope of the present invention.

100. Algae driven power generation module 110. First aberration
111. First rotating shaft 113. First aberration blade
120. Second aberration 121. Second rotation axis
123. Second Aberration Wing 160 ~ 180. aberration
130. Aberration support 131. Central axis of support
137. Support shaft development 138. Intermediate support shaft
140. Torque transmission unit 141. First aberration sprocket
142. Middle support shaft sprocket 143. Second aberration sprocket
144. Support shaft sprocket 145. First chain
146. Second chain 150. Generating force transmission unit
200. Bird Driven Generator 220. Process Support

Claims (13)

A support center axis 131, a left side 132 extending at a predetermined angle from the support center axis 131, and extending at an angle from the support center axis 131 symmetrically with the left side 132. The right side 133 and the bottom side 134 connecting the left side 132 and the right side 133 and the left side 132 and the right side 133 and the bottom side 134 are respectively installed to seal the upper and lower ends thereof. An aberration support 130 having an upper and lower surfaces 136, a portion of which extends from the base 134;
Upper and lower ends of the first rotation shaft 111 fixedly coupled to one side of the upper and lower surfaces 136 of the aberration support 130, and a plurality of first aberration blades 113 rotating around the first rotation shaft 111. A first aberration 110 including;
A second rotary shaft 121 installed in parallel with the first aberration 110 and fixedly coupled to the other side of the extended upper and lower surfaces 136 of the aberration support 130; and the second rotary shaft 121 A second aberration 120 including a plurality of second aberration wings 123 rotating about the center; And
It is installed on the upper surface 135 of the aberration support 130, receives a rotational power from the pair of aberrations (110, 120) rotational force transmission unit 140 to rotate the support shaft (137); and includes ,
Each of the first and second aberration blades 113 and 123 is installed to partially expose the bottom side 134, and the exposed first and second aberration blades 113 and 123 rotate in opposite directions by birds.
Part of each of the first and second aberration blades (113, 123) located in the bottom side 134 of the aberration support 130, the rotational radius of the bird driven type power generation module, characterized in that installed so as to overlap each other.
The method of claim 1,
The support power generation shaft 137 is positioned inside the support central axis 131 to form a concentric axis, and the support center axis 131 is a rotation center so that the aberration support 130 changes direction according to a tidal current. The bird driving type power generation module, characterized in that configured to move along the bird together with the pair of aberration (110, 120) and the aberration support (130) integrally.
delete The aberration blades 113 and 123 of the aberrations 110 and 120 are equiangularly installed with respect to the rotation shafts 111 and 121, respectively.
Each of the aberration blades 113 is coupled to the rotation shaft 111 and installed to extend from the rotation shaft and a plurality of wing support 114 is installed in the height direction of the rotation shaft 111, the plurality of wing support 114 Bird-driven power generation module, characterized in that it comprises a wing plate (115) installed to be supported on.
The method of claim 4, wherein
The wing plate of the aberration wing is a bird-driven power generation module, characterized in that it has a hollow semi-cylindrical shape or a hollow polygon (pyramid) shape inside.
The method of claim 4, wherein
The wing plate of the aberration blade has a flat plate shape,
The wing plate is a bird-driven power generation module, characterized in that rotatably installed on the wing support.
The method of claim 1,
On the upper surface 135 of the aberration support 130, an intermediate support shaft 138 positioned between the first rotation shaft 111 of the first aberration 110 and the second rotation shaft 121 of the second aberration 120 is formed. Installed,
The rotational force transmission unit 140,
A first aberration sprocket 141 formed on the first rotation shaft 111 of the first aberration 110;
An intermediate support shaft sprocket 142 formed on the intermediate support shaft 138;
A second aberration sprocket 143 formed on the second rotation shaft 121 of the second aberration 120;
A support shaft development sprocket 144 formed on the support shaft 137;
A first chain 145 connected to the first aberration sprocket 141 and the intermediate support shaft sprocket 142 to transmit the rotational force of the first aberration sprocket 141 to the intermediate support shaft sprocket 142; And
A second chain 146 connected to the second aberration sprocket 143 and the support shaft shaft sprocket 144 and transmitting the rotational force of the second aberration shaft sprocket 143 to the support shaft shaft sprocket 144; ,
Some paths of the second chain 146 are positioned to contact the intermediate support shaft sprocket 142 to receive the rotational force of the first intermediate support shaft sprocket 142, so that the rotational force of the first aberration and the second aberration is added. Bird driven type power generation module, characterized in that the transmission via the second chain (146) to the support shaft shaft sprocket (144).
The method of claim 7, wherein the intermediate support shaft sprocket 142,
A first intermediate support shaft sprocket 142a installed in parallel with the first aberration sprocket 141 and connected to the first chain 145;
The second intermediate support shaft sprocket is installed so as to be located below the first intermediate support shaft sprocket 142, and is installed in parallel with the second aberration sprocket 143 to contact a part of the path of the second chain (146) ( Bird driving type power generation module comprising: 142b).
The method of claim 1,
The inner space sealed by the left side 132, the right side 133, the bottom side 134, and the upper and lower surfaces 136 of the aberration support 130 is configured to be empty so that the aberration support 130 performs a function of buoyancy. Bird driven type power generation module, characterized in that.
The method of claim 1,
It is connected to the support generating shaft 137 rotated by the rotational force transmission unit 140, characterized in that it further comprises a power generation transmission unit 150 to be connected to an external generator or an external hydraulic device to provide a power generation power. Bird driven power generation module.
Claims 1 to 2, 4 to 10 according to any one of the bird-driven power generation module 100;
The bird-driven power generation module 100 includes a row support 220 for supporting it so as to constitute a plurality of rows or a plurality of columns,
The tidal current driven power generation module 100 supported by the row support 220 is a tidal current drive, characterized in that it is disposed so as not to overlap each other in the direction of the tidal current driven power generation module 100 and the tidal direction of adjacent columns or rows. Mold generator.
The method of claim 11,
The algae driven generator is an algae driven generator, characterized in that installed on the sea surface or underwater or seabed.
The method of claim 11,
The rotational force produced by each power generation module constituting the tide driving type generator is converted into hydraulic pressure and sent to the central hydraulic device installed on the sea or land through the intermediate hydraulic device to generate the power by rotating the central generator.
The central hydraulic device includes a plurality of flow paths 77 for dividing the hydraulic pressure flowing from the inlet 72, a plurality of generators 71 installed in the plurality of flow paths 77, and a plurality of flow paths 77. Tidal flow type generator characterized in that the overload hydraulic prevention power generation unit 70 is composed of a plurality of check valves (74) to be selectively opened according to the strength of the hydraulic pressure introduced to the inlet (72).

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