KR101139295B1 - Wind power generator having windmill wings based variable - Google Patents

Abstract

The present invention relates to a wind power generator having a variable windmill wings, the mounting table 10; A vertical rotation shaft 20; Bearing 20 '; 'C' stab support 30; An inner wing installation device 40; A support rod 40 '; An outer wing fitting 50; A support ring 60; A vertical support rod 60 '; A support 60a; A plurality of diagonal supports (60b) connected and fixed between the upper outer wing installation unit (50) and the lower inner wing installation unit (40) in the same group; A ladder 60c; Windmill wings 70; A support 80; Power generation means (90); Windmill wing fixing means (90 '); It is composed of the fixing means driving device (100 ') can be operated in the breeze regardless of the wind direction, when the windmill wings are unfolded in the direction of the wind and rotates 180 °, the windmill wings are folded, thereby minimizing the resistance of air and wind during the rotation of the windmill wings Power generation efficiency can be improved, and it is easy to manufacture with simple structure and can be installed in various places without any limitations on the installation place, so it is possible to maximize the power production per unit area, which enables industrialization and does not cause pollution such as greenhouse gas. Wind turbines installed in groups of up and down multi-stages can be produced firmly, and the rotational movement of the windmill blades can be easily stopped as needed. Easy access for convenient follow-up of maintenance This invention is useful in special benefits I can.

Description

Wind power generator having windmill wings based variable

The present invention relates to a wind power generator, and more specifically, the windmill wings are unfolded in the direction of wind, windmill wings are folded in a direction rotated 180 ° in the direction of wind to minimize the resistance of the air during the rotation of the windmill wings power generation While improving efficiency, it is easy to install a large number of windmill generators regardless of the installation site, and a large number of windmill generators can be installed in a narrow space to maximize the power production per unit area. It relates to a wind power generator provided.

Commonly used power generation methods include thermal power generation using large fossil fuels, nuclear power generation using uranium, and hydroelectric power generation requiring large-scale desalination facilities. It is the urgent need for more eco-friendly power generation methods because it generates radiation wastes that are the main culprit of warming or difficult to treat or causes large environmental destruction.So, solar power and wind power are the most widely researched as alternative eco-friendly power generation methods. Wind power generation using dual wind power is the most widely favored and in Korea, three sides are surrounded by the sea.

Wind power generation using the force of wind is a technology that obtains power by converting a rotor into mechanical energy by using the aerodynamic characteristics of the kinetic energy of air flow. It is classified into horizontal type and vertical type according to the direction of the rotating shaft, and the main components control the rotor composed of vanes and hubs, the speed increaser, the generator and various safety devices that drive the generator by increasing the rotation of the rotor. And a control device, a hydraulic brake device, a power control device, and a steel tower.

In addition, wind power generation uses no-pollution and infinite wind scattered everywhere, so there is little effect on the environment, and the land can be used efficiently, and in the case of large-scale power generation facilities, power generation costs can compete with existing power generation methods. It is a level of new energy generation technology.

In such a wind generator, the windmill is converted into electrical energy by using kinetic energy rotated by the wind. At this time, the windmill theoretically converts about 60% of the kinetic energy of the wind into mechanical energy, which is then converted into electrical energy. Is converted to a lot of energy. Therefore, the conversion efficiency of converting wind energy into electrical energy is substantially different depending on the shape of the windmill, but it is only about 20 to 40%.

However, in the conventional wind power generation as described above, the wind is maintained at a constant speed or higher and the density of the air is high so that the kinetic energy of the wind is transmitted to the wings, and thus the windmill is rotated, thereby converting the kinetic energy of the wind into electrical energy. It is implied. In other words, when the wind is weak and the breeze blows, since the rotation of the windmill is weakened, the situation that the generation of wind power generation is impossible.

In particular, when the wind turbine blade rotates 180 ° in the direction of receiving wind, the wind turbine blade is further reduced in power generation efficiency because the rotation of the windmill blade is blocked by the wind or air resistance.

As developed to solve such a problem, a "windmill for a wind power generator with a deformable wing" of Patent Publication No. 10-2009-56280 is published in Korea Patent Publication.

As shown in FIG. 1, the patent document 10-2009-56280 "windmill having a variable wing" is coupled to a rotor shaft of a wind turbine and rotates together with the rotor shaft. )Wow; Wings 120 which are installed at regular intervals along the circumferential direction and the longitudinal direction of the case 110 so that the case 110 is rotated by the wind, and is developed and folded by the force of the wind; The wing member 120 is rotatably installed and installed in the case 110, and the driving member for rotating the wing member 120 so that the wing member 120 is easily deployed and folded according to the wind direction ( 130, the drive member 130 is installed on the case 110, the bracket (131) to which the wing 120 is rotatably attached through a hinge (H); A cylinder 133 installed at the bracket 131 and having an operating space 133a formed therein; A piston 135 embedded in the working space 133a and linearly reciprocating; A tension spring (137) embedded in the working space (133a) such that the piston (135) is elastically supported in the direction of the blade (120); One end is connected to the wing 120, the other end is composed of a link 139 is connected to the piston 135, the windmill 100 is rotated and the front surface 121 of the wing 120 is extended. When the blowing direction is facing, the wing 120 is unfolded, when the rear surface 123 of the wing 120 is facing the wind blowing direction, the wing 120 is due to the elasticity of the wind and tension spring 137 Since the wind power delivered to the wing 120 is reduced by being quickly rotated and folded in the bracket 131, the rotational force of the windmill 100 is increased.

However, the "windmill 100 for a wind turbine with a variable wing" of the Patent Publication No. 10-2009-56280, although the wing 120 is developed or folded by the blowing wind, the wing 120 is 90 ° due to the movement or deployment or folding is not only a defect that causes the wing 120 is not well deployed or folded well, as well as the elastic force of the tension spring 137 to fold the wing 120 is the windmill 100 Because it acts as a force to block the rotation of the improvement of power generation efficiency does not meet expectations.

In addition, the "windmill 100 with a deformable wing" of the Patent Publication No. 10-2009-56280 also had a problem that maintenance is difficult because there is no separate means for repairing the failure . That is, even when any one of the plurality of blades 120 does not operate by failure, the windmill 100 is rotated by the wind, so it is difficult to stop the rotating windmill 100 to repair the broken blades 120. There was also a problem.

The present invention has been invented to solve various defects and problems caused by the conventional wind turbines, and the object thereof is to operate in a low wind with low wind speed and to operate regardless of the direction of the wind, so that the generation efficiency is high. It is to provide a wind power generator having a windmill blade.

Another object of the present invention is to improve the power generation efficiency by minimizing the resistance to the rotational force of the windmill shaft by minimizing the resistance of air and wind during the rotation of the windmill blade is rotated when the windmill blade is rotated 180 ° to rotate in the wind direction It is to provide a wind turbine with a variable windmill wings that can be made.

Another object of the present invention is easy to manufacture in a simple structure, but can be installed in a variety of places without limitation in the installation place is possible to maximize the amount of power production per unit area, industrialization is possible and does not cause pollution, such as greenhouse gases, environmentally friendly electricity To provide a wind turbine with a variable windmill wings to produce.

Still another object of the present invention is to install a group of up and down multi-stage wind turbines are installed firmly, and can easily stop the rotation operation of the windmill blades as needed, while the maintenance worker to the corresponding windmill wing position that needs repair. It is to provide a wind power generator with a variable windmill wings that can be easily accessed to facilitate post-maintenance maintenance.

Wind turbine with a variable windmill wings of the present invention for achieving the above object is installed on the floor with a '+' shape and having a vertical rotary shaft support in the center (10); A vertical rotation shaft 20 rotatably installed in the center of the mounting table 10; A bearing 20 'to which an upper end of the vertical rotation shaft 20 is rotatably inserted; A 'c' shaped support 30 which is connected and fixed between the bearing 20 'and the mounting table 10; A plurality of inner wing fittings 40 fixedly installed at regular intervals up and down on the vertical rotation shaft 20; A support rod 40 'having one end fixed to the inner wing fitting 40; An outer wing installation port 50 to which an outer end of the support bar 40 'is fixed; A support ring (60) made of a steel wire connected to the outer wing installation device (50) on the same horizontal plane; Vertical support rod (60 ') consisting of a steel wire that the upper and lower outer wing installation portion 50 is formed in a multi-stage group, the outer wing installation portion 50 in the same group connected up and down; A plurality of supports (60a) formed of steel wires connected between the support rods 40 'positioned at the top and the support rods 40' positioned at the bottom of the same group; A plurality of diagonal supports (60b) connected and fixed between the upper outer wing installation unit (50) and the lower inner wing installation unit (40) in the same group; A ladder (60c) fixed to the support bar (40 ') of each end; Windmill wings 70 which are installed in the upper and lower multistage between each of the inner wing installation 40 and the outer wing installation 50; The windmill wings 70 is formed on the vertical rotation shaft 20 between the groups in groups of up and down multi-stage support '80' connected to the 'c'-shaped support 30 by a wire 81; Power generation means 90 is installed on the lower surface of the central portion of the mounting table (10); A windmill wing fixing means 90 'installed on the inner wing installation portion 40 so as to be movable upward and downward on the vertical axis of rotation 20 to fix the displacement of the windmill blade 70; Characterized in that it consists of a fixing means drive device (100 ') installed on the lower end side of the vertical rotation shaft (20).

The present invention can be operated in the low wind speed of the wind while operating regardless of the wind power generation efficiency is high, the windmill wings are expanded in the direction of the wind and rotate 180 ° windmill wings are folded, the air and wind at the time of rotation of the windmill wings The power generation efficiency can be improved by minimizing the resistance acting on the rotational force of the windmill shaft by minimizing the resistance of the power plant. Industrialization is possible, but it does not cause pollution such as greenhouse gas, so it can produce electricity in an eco-friendly way, and wind turbines installed in groups of multiple stages up and down are installed firmly, and the rotation operation of windmill blades can be easily stopped as needed. Those who still need repair The windmill wing has a special advantage that can be easily accessed by maintenance workers for convenient post-management of maintenance.

1 is a perspective view showing the configuration of a windmill for a conventional wind turbine having a variable wing,
Figure 2 is a cross-sectional view showing the configuration of the blade and the drive member installed in the windmill for a conventional wind turbine having a variable wing,
3 is a perspective view of a wind power generator having a variable windmill vane according to the present invention;
Figure 4a is a perspective view showing the installation state of the windmill blades in accordance with the present invention rotates in a clockwise direction,
Figure 4b is a perspective view showing the installation state of the windmill blades in accordance with the present invention rotates counterclockwise,
5 is a view showing the configuration of the support is installed on the same plane in the same group according to the present invention,
Figure 6 is an exploded perspective view of the main part of the wind power generator having a variable windmill wings of the present invention,
Figure 7a is a perspective view showing another embodiment of the inner wing installation and moving tool according to the present invention,
Figure 7b is a view showing a multi-stage arrangement state of the inner wing installation and moving tool for each group of windmill wings according to the present invention,
Figure 8a is a view showing a fixing means driving device according to the invention when the rotation of the windmill blade,
8b is a view showing a fixing means driving device according to the invention when the rotation stop of the windmill blade,
9 is a perspective view of a fixing means driving apparatus according to the present invention,
10 is a bottom view of the fixing means driving apparatus according to the present invention;
Figure 11a is a view for explaining the operating state of the windmill blade fixing means according to the present invention when the rotation of the windmill blade,
11b is a view for explaining the operating state of the windmill blade fixing means according to the present invention at the time of rotation stop of the windmill blade,
12a is a view showing the operating state of the windmill blade fixing means according to the present invention when the rotation of the windmill blade,
Figure 12b is a view showing the operating state of the windmill blade fixing means according to the invention when the rotation stop of the windmill blade,
Figure 13a is a view showing a state of the windmill blades displaced by the operation of the windmill blade fixing means according to the present invention when the rotation of the windmill wings,
Figure 13b is a view showing a state of the windmill blades displaced by the operation of the windmill blade fixing means according to the invention at the time of rotation stop of the windmill blade,
14 is a schematic plan view showing the wind flow between the windmill wings when a plurality of wind power generators having a variable windmill wing of the present invention are installed.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the wind power generator having a variable windmill wings of the present invention.

Figure 3 is a perspective view of a wind power generator having a variable windmill wings of the present invention, Figure 4a is a perspective view showing the installation state of the windmill blades according to the present invention to rotate clockwise, Figure 4b to the present invention to rotate in a counterclockwise direction Figure 5 is a perspective view showing the installation state of the windmill wings, Figure 5 is a view showing the configuration of the support is installed on the same plane in the same group according to the present invention, Figure 6 is a main portion of the wind turbine with a variable windmill wings of the present invention Figure 7a is a perspective view showing another embodiment of the inner wing installation and the moving tool according to the present invention, Figure 7b is a multi-stage arrangement of the inner wing installation and the moving device for each group of windmill wings according to the present invention Figure 8a is a view showing a fixing means driving device according to the present invention when the rotation of the windmill blade rotation, Figure 8b is a fixed water according to the present invention when the rotation stop of the windmill blade 9 is a perspective view of the fixing means driving apparatus according to the present invention, Figure 10 is a bottom view of the fixing means driving apparatus according to the present invention, Figure 11a is a windmill wing according to the present invention when the rotation of the windmill wings Figure 11b for explaining the operating state of the fixing means, Figure 11b is a view for explaining the operating state of the windmill wing fixing means according to the invention when the rotation stop of the windmill blade, Figure 12a Figure 12b is a view showing the operating state of the windmill blade fixing means, Figure 12b is a view showing the operating state of the windmill wing fixing means according to the invention when the rotation stop of the windmill blade, Figure 13a is a windmill wing according to the invention when the rotation of the windmill blade Figure 13b is a view showing a state of the windmill blade displaced by the operation of the fixing means, Figure 13b is a windmill blade displaced by the operation of the windmill blade fixing means according to the invention at the time of rotation stop of the windmill blade 14 is a schematic plan view showing wind flow between windmill wings when a plurality of wind turbines having variable windmill wings are installed according to the present invention. (A) is mounted on the floor to the '+' shape and having a vertical support for the vertical axis of rotation in the center (10); A vertical rotation shaft 20 rotatably installed in the center of the mounting table 10; A bearing 20 'to which an upper end of the vertical rotation shaft 20 is rotatably inserted; A 'c' shaped support 30 which is connected and fixed between the bearing 20 'and the mounting table 10; A plurality of inner wing fittings 40 fixedly installed at regular intervals up and down on the vertical rotation shaft 20; A support rod 40 'having one end fixed to the inner wing fitting 40; An outer wing installation port 50 to which an outer end of the support bar 40 'is fixed; A support ring (60) made of a steel wire connected to the outer wing installation device (50) on the same horizontal plane; Vertical support rod (60 ') consisting of a steel wire that the upper and lower outer wing installation portion 50 is formed in a multi-stage group, the outer wing installation portion 50 in the same group connected up and down; A plurality of supports (60a) formed of steel wires connected between the support rods 40 'positioned at the top and the support rods 40' positioned at the bottom of the same group; A plurality of diagonal supports (60b) connected and fixed between the upper outer wing installation unit (50) and the lower inner wing installation unit (40) in the same group; A ladder (60c) fixed to the support bar (40 ') of each end; Windmill wings 70 which are installed in the upper and lower multistage between each of the inner wing installation 40 and the outer wing installation 50; The windmill wings 70 is formed on the vertical rotation shaft 20 between the groups in groups of up and down multi-stage support '80' connected to the 'c'-shaped support 30 by a wire 81; Power generation means 90 is installed on the lower surface of the central portion of the mounting table (10); A windmill wing fixing means 90 'installed on the inner wing installation portion 40 so as to be movable upward and downward on the vertical axis of rotation 20 to fix the displacement of the windmill blade 70; It consists of a fixing means driving device (100 ') installed on the lower end side of the vertical rotation shaft 20.

The inner wing installation portion 40 is divided into an installation portion 40a and the installation portion 40b, and the installation portion 40a and the installation portion 40b are separated by the bolt 41, and the inner wing installation portion ( 40, one end of the support rod 40 'is inserted in the horizontal direction in the front, rear, left and right four directions, and is fixed by a bolt 42 inserted downward from the upper surface, and the inner wing is installed on the same plane as the support rod 40'. One end of the blade rotation shaft 71 is rotatably inserted into the sphere 40, and the windmill wing fixing means 90 'is provided in the inner wing installation hole 40 under the support rod 40' and the blade rotation shaft 71 insertion portion. One end of the rotary shaft 96 is rotatably inserted, the other end of the support rod 40 'is inserted into the outer wing installation 50 is fixed, the other end of each of the blade rotation shaft 71 and the rotary shaft 96 Is rotatably inserted into the outer wing mounting tool 50.

The windmill blade 70 has a wing rotation shaft 71 rotatably installed between the inner wing installation 40 and the outer wing installation 50 on the same plane as the support rod 40 ', and the wing rotation shaft A wing piece 72 having one side fixed to the blade 71 and a wing spring 73 inserted into a central portion of the blade rotation shaft 71 to maintain the wing piece 72 at a horizontal angle of 45 ° during non-operation. It consists of.

The wing piece 72 is preferably formed of a light weight and strong material, it is preferable to form any one of transparent or opaque reinforced plastic, tempered glass, nonferrous metal, duralumin.

As shown in FIG. 5, the blade rotation shafts 71 are fixed to each other by supporters 60d of a plurality of steel wires, and the blade rotation shafts 71 positioned on the same plane in the same group are fixed between the support rings 60. A plurality of steel wire supports 60e are connected and fixed, and the support 60d and the support 60e and the support 60d and the support ring 60 are connected and fixed to each other.

As shown in FIG. 6, the inner wing mounting device 40 has a structure in which the cut surface of the central part divided into the mounting tool 40a and the mounting tool 40b is parallel to the outer side, and shown in FIG. 7A. As shown in FIG. 6, the cutting surface divided into the mounting tool 40a 'and the mounting tool 40b' is divided into a diagonal structure, and the moving tool is also a moving tool so that the cutting surface of the center part is parallel to the outer side as shown in FIG. The structure divided into 91a and the movement tool 91b, and the cutting surface divided into the movement tool 91a 'and the movement tool 91b' as shown in FIG. As shown in the figure, the group located at the upper side of the support 80 becomes a group in which the cutting plane is parallel to the outer side, and the lower portion is alternately installed so that the cutting plane is a group in the diagonal. 80) the group located at the top of the The face is a diagonal group, and the lower part is alternately installed so that the cut surface is a group parallel to the outer side) of the wing pieces 72 of the windmill blades 70 in one group to vertically wind Since the wing piece 72 in the other group corresponding to the receiving wing piece 72 is located 45 ° more rotated or 45 ° less rotated than the wing piece 72 receiving wind vertically. For each group, the wing piece 72 receives the wind vertically every time the blade rotation shaft 71 of the windmill blade 70 rotates 90 °, but in the case of the entire group, the blade rotation shaft 71 is 45 ° Each turn, the wing piece 72 of the group alternately receives the wind vertically to enable efficient wind power generation.

In addition, the support 80 is divided into a support 80a and a support 80b so that the support 80a and the support 80b are separated and separated by bolts 82, and the support 80a and the support 80b. The support plate is inserted into the circular protrusion 83 of the lower surface formed by the coupling of the support plate is divided into the support plate 84a and the support plate 84b to form a hinge structure on one side, and the other side of the bolt through the bracket (85) 86, one end of the wire 81 is fixed to the rectangular corner portion of the state in which the support plate 84a and the support plate 84b are coupled, and the other end of the wire 81 is the 'c' magnetic support ( 30) is fixed to the connection.

The windmill wing fixing means 90 'is divided into the movable tool 91a and the movable tool 91b, and the movable tool 91a is movable up and down on the vertical rotating shaft while the vertical rotating shaft 20 is inserted into the center portion. And the moving tool 91b are separated by the bolt 92, and the moving shaft for moving the moving tool 91a and the moving tool 91b up and down between the moving tool 91a and the moving tool 91b ( 93 is inserted and fixed, one end of the straight lever 94 is fixed to each of the outer surfaces formed by the moving tool 91a and the moving tool 91b, and 'L' at the other end of the straight lever 94. One end of the magnetic lever 95 is rotatably connected, and the other end of the 'L'-shaped lever 95 is the rotary shaft 96 is the inner wing fitting (with the rotary shaft 96 having the spring 96a inserted therein) In addition to being rotatably inserted into the 40, the inner blade mounting hole 40, the other end of the 'L' shaped lever 95 is positioned to stop the rotation of the 'L' shaped lever 95 The stopper pin (95a) is inserted and fixed, one end of the spring (96a) is fixed to the support rod 40 'and the other end is adjacent to the connection of the straight lever 94 and the' L 'shaped lever (95) It is fixed on the 'L' shaped lever 95, the plurality of levers 97 are fixed on the rotary shaft 96 at regular intervals.

In addition, the fixing means driving device (100 ') and the rectangular cylinder (101'); A lower fixing plate 102 'fixed to a lower portion of the rectangular cylinder 101'; A pair of rollers 103 'installed at one side of a lower surface of the lower fixing plate 102'; A lower roller 104 'installed at each corner of a lower surface of the lower fixing plate 102'; A lower movable plate 105 'moving up and down in the rectangular cylinder 101'; A spring 106 'inserted into a central portion of an upper surface of the lower movable plate 105'; A plurality of moving shafts 107 'which are erected and fixed at the corners of the lower movable plate 105'; An upper fixing plate 108 'fixed to an upper portion of the rectangular cylinder 101'; An upper roller 109 'installed at each lower edge of the upper fixing plate 108'; An upper moving plate 110 'fixed to an upper end of the plurality of moving shafts 107'; Rope means 111 'composed of ropes 111a to 111d caught by the pair of rollers 103' and upper and lower rollers 109 'and 104'; It is composed of a motor 112 'for winding and releasing the rope means 111'.

The rectangular cylinder 101 'is formed with guide grooves 101a of upper and lower long grooves on one side thereof, and the lower fixing plate 102' is formed in the rectangular cylinder 101 'by a' b 'shaped bracket (a). It is fixed to the lower portion, the roller 103 'and the roller 104' is fixed to the lower surface of the lower fixing plate 102 'by the bracket (b), the moving shaft 107' is the lower end of the nut ( c, c ') is fixed to the edge of the lower movable plate 105' and the upper end of the moving shaft 107 'is fixed to the upper movable plate 110' with nuts c and c '. A guide bundle 105a having a guide protrusion d is fixed to one side of an upper surface of the lower movable plate 105 'so that the guide protrusion d is inserted into the guide groove 101a, and the upper fixing plate 108' is fixed. A fixing protrusion (e) is formed at the side of the side so that the fixing protrusion (e) is inserted into and fixed to the side of the inside of the rectangular cylinder (101 '), and the upper roller is formed on the lower surface of the upper fixing plate (108') by the bracket (b). (109 ' ) Is fixed.

As described above, in the support tool 80, the support body 80a and the support body 80b are bisected, and the support plate is also bisected into the support plate 84a and the support plate 84b. Also in the 90 ', the movable tool 91a and the movable tool 91b or the movable tool 91a' and the movable tool 91b 'are divided into two structures, and the inner wing mounting tool 40 is provided with a mounting tool ( The structure divided into 40a) and the installation tool 40b and the installation tool 40a 'and the installation tool 40b' is for making it easy to replace and repair only the corresponding part at the time of a failure.

Here, the windmill wings 70 are installed in a plurality of stages in the upper and lower n stages, and a plurality of wind generators A having the windmill wings 70 in the upper and lower n stages are installed in the horizontal direction in the front, rear, left and right directions, respectively. It is preferable that the power generation means 90 for each power supply unit 90 are electrically connected to each other so that the power generation power of each power generation unit 90 is combined to increase the power generation power.

In addition, when a large number of wind generators (A) having the wind turbine blades 70 of the upper and lower stages are installed in a horizontal direction front, rear, left and right, as shown in FIG. The wind generator (A) does not block the sun's light even when the pole (X) and the bearing (20 ') of each of the wind generators (A) are connected and fixed with wires (Y). It can be installed in the upper spaces of forests, etc., or the upper spaces of marine farms.

Next will be described in detail the operation of the wind turbine with a variable windmill wings of the present invention configured as described above.

Wind turbine blade (70) of the present invention is opposed to the direction in which the wind blows the wind turbine blades 70 are pushed by the blowing wind to receive the wind while the wing piece 72 is caught in the lever 97 to form a vertical state (support rod ( 40 ') is pushed by the wing piece 72 receives the wind to rotate the vertical axis of rotation 20 through the blade rotation axis 71 to generate power.

At this time, the wing piece 72 rotated when the vertical axis of rotation 20 rotates by 90 ° from the vertical plane forming the plane perpendicular to the direction of the wind, and the blade piece 72 is rotated horizontally with the force of air as the wing piece 72 further rotates. The rotating shaft 20 is rotated and is not subjected to air resistance so that the vertical rotating shaft 20 is rotated, and the blade piece 72 rotated further by 270 ° from the vertical plane which is further rotated to form a vertical plane with the direction of the wind. The wing spring 73 maintains 45 ° in the horizontal plane, and if it is rotated further in this state, it is pushed again by the blowing wind so that the wing piece 72 is caught by the lever 97 and the wind is vertical. Received by pushing the blade rotation shaft 71 by the vertical rotation shaft 20 is continuously rotated to generate power.

The operation of the windmill wing 70 as described above has a structure (see FIGS. 4A and 4B) in which the wing piece 72 which is subjected to the wind is caught by the lever 97 in front and rear, and the wing piece 72 is rotated by 180 °. It is possible to form a horizontal plane with the ground.

14 is a schematic plan view showing the wind flow between the windmill wings when a plurality of wind turbines (A) having a variable windmill wing of the present invention is installed.

In FIG. 14, the arrow P indicates a direction in which the wind blows, and the arrow Q indicates a rotation direction of each of the wind turbines A. The wind turbines A of the first row rotate clockwise. The second row of wind turbines A rotates counterclockwise. In addition, the third row of wind turbines A rotates clockwise, and the fourth row of wind turbines A rotates counterclockwise. In this way, each row of wind generators A alternately rotates in the opposite direction.

At this time, the wind blowing in the wide area is narrow between the wind turbine (A) of the first row and the wind turbine (A) of the second row, between the wind turbine (A) of the third row and the wind turbine (A) of the fourth row. As the wind passes through the area, the wind strength becomes stronger, so that the power generation efficiency of the wind turbines (A) is increased. In this case, the wind turbines (A) are paired by two rows even when the wind blows obliquely in the front, rear, left, and right directions. Wind generators (A) located in one row of the paired rows to rotate in a clockwise direction, wind turbines (A) located in the other row rotates counterclockwise to generate power.

Such a rotational direction of the wind turbines A has a structure in which the wing piece 72 is caught by the lever 97 in the rear from the front (see FIG. 4A) and the lever 97 in which the wing piece 72 is in the rear from the front. It is possible to select and adopt a structure to be applied (see Fig. 4B) according to each column. That is, the wind power generator A having the windmill blade 70 as shown in FIG. 4A rotates clockwise, and the wind power generator A having the windmill wing 70 as shown in FIG. 4B rotates counterclockwise. .

As described above, the wind power generator A having the variable windmill wings of the present invention for generating wind power does not operate the windmill wing fixing means 90 'as shown in FIGS. 8A, 11A, 12A, and 13A. In the state, the lever 97 is in a vertical downward state, so that the lever 97 keeps the windmill blade 70 receiving the wind in a vertical state, thereby operating in a normal state in which the windmill blade 70 can generate electricity. If you want to protect the wind turbine (A) from typhoons or the like, or if you want to stop the operation of the wind turbine (A) as necessary due to the failure, maintenance, repair, etc. of the wind turbine (A), shown in Figure 8b As shown in FIGS. 11B, 12B, and 13B, the fixing means driving device 100 ′ is operated to move the moving shaft 93 of the windmill wing fixing means 90 ′ upward. That is, when the motor 112 'is rotated forward, the rope 111 is wound around the shaft of the motor 112' so that the spring 106 'is compressed and the lower movable plate 105' is raised. As the moving shaft 107 'rises, the upper moving plate 110' is raised.

Ascending of the upper movable plate 110 ′ causes the movable shaft 93 to move upward, thereby causing the movable holes 91a and 91b fixed to the movable shaft 93 to rise along the vertical rotation shaft 20. As the straight lever 94 is raised, the straight lever 94 pulls the 'L' shaped lever 95 upward, thereby rotating the rotation shaft 96 so that the lever 97 is the wing piece of the windmill blade 70. By lifting 72, the wing pieces 72 of all the windmill wings 70 are kept level with the ground, so that the wing pieces 72 of the windmill wings 70 do not receive the blowing wind (FIG. 11B, 12B and 13B) The vertical rotation shaft 20 stops rotating, and in this state, the wind turbine A may be repaired, maintained, or repaired.

Here, unlike the case of stopping the operation of the wind power generator (A) by completely moving the moving shaft 93 upwards, the vertical plane and the wing piece of the windmill wings 70 according to the degree of moving the moving shaft 93 upward When the typhoon and the like are expected by setting the angle formed by the (72), all the wind blowing from the wing piece 72 by fixing the moving shaft 93 upward in advance according to the expected intensity of the typhoon. Without passing through a certain amount of wind as it is to protect the wind turbine (A) from typhoons.

In addition, the worker who performs the repair after stopping the operation of the wind power generator A by completely moving the moving shaft 93 upwards goes up to the working position on the ladder 60c, and if necessary, After lifting up, the small ladder is placed between the supporting rods 40 'in the horizontal direction, and then the small ladder is moved to the working position.

The motor 112 'may be reversely rotated when the raised moving shaft 93 is lowered and returned. That is, when the motor 112 'is reversely rotated, the rope 111 wound around the shaft of the motor 112' is released and the lower movable plate 105 'is lowered by the elastic force of the spring 106'. Accordingly, as the moving shaft 107 'is lowered, the upper movable plate 110' is lowered.

The lowering of the upper movable plate 110 'causes the moving shaft 93 to move downward, and accordingly, the lowering of the moving shaft 93 causes the end of the' L 'shaped lever 95 to hang on the stopper pin 95a. As it is lowered until the rear rotation is prevented (to the state where the lever 97 is vertically lowered), the state as shown in FIGS. 8A, 11A, 12A, and 13A, that is, the wind power generator A can normally generate power. It becomes the state that I can.

While the present invention has been described as a preferred embodiment, the present invention is not limited thereto, and various modifications can be made without departing from the gist of the invention.

10: mounting table 20: vertical axis of rotation
20 ': bearing 30:' c 'stair support
40: inner wing installation hole 40 ': support rod
40a, 40b, 40a ', 40b': Mounting port 41: Bolt
42: bolt 50: outer wing installation
60: support ring 60 ': vertical support rod
60a: support 60b: diagonal support
60c: ladder 60d, 60e: support
70: windmill wing 71: wing rotation axis
72: wing piece 73: wing spring
80: support 80a, 80b: support
81: wire 82: bolt
83: circular projection 84a, 84b: support plate
85: Bracket 86: Bolt
90: power generation means 90 ': windmill wing fixing means
91a, 91b, 91a ', 91b': Moving port 92: Bolt
93: moving axis 94: linear lever
95: 'L' shaped lever 95a: stopper pin
96: rotating shaft 96a: spring
97: lever 100 ': fixing means drive device
101 ': rectangular cylinder 101a: guide groove
102 ': lower fixing plate 103': roller
104 ': Lower roller 105': Moving plate
105a): Guide bundle 106 ': Spring
107 ': moving shaft 108': upper fixing plate
109 ': upper roller 110': upper transfer plate
111 ': Rope 111a ～ 111d: Rope branch
112 ': Motor A: Wind Power Generator
X: Holding Y: Wire
a: 'B' shaped bracket b: bracket
c, c ': nut d: guide protrusion
e: fixing protrusion

Claims (13)

A mounting table 10 mounted on the floor with a '+' shape and having a vertical rotation shaft support at a center thereof; A vertical rotation shaft 20 rotatably installed in the center of the mounting table 10; A bearing 20 'to which an upper end of the vertical rotation shaft 20 is rotatably inserted; A 'c' shaped support 30 which is connected and fixed between the bearing 20 'and the mounting table 10; A plurality of inner wing fittings 40 fixedly installed at regular intervals up and down on the vertical rotation shaft 20; A support rod 40 'having one end fixed to the inner wing fitting 40; An outer wing installation port 50 to which an outer end of the support bar 40 'is fixed; A support ring (60) made of a steel wire connected to the outer wing installation device (50) on the same horizontal plane; Vertical support rod (60 ') consisting of a steel wire that the upper and lower outer wing installation portion 50 is formed in a multi-stage group, the outer wing installation portion 50 in the same group connected up and down; A plurality of supports (60a) formed of steel wires connected between the support rods 40 'positioned at the top and the support rods 40' positioned at the bottom of the same group; A plurality of diagonal supports (60b) connected and fixed between the upper outer wing installation unit (50) and the lower inner wing installation unit (40) in the same group; A ladder (60c) fixed to the support bar (40 ') of each end; Windmill wings 70 which are installed in the upper and lower multistage between each of the inner wing installation 40 and the outer wing installation 50; The windmill wings 70 is formed on the vertical rotation shaft 20 between the groups in groups of up and down multi-stage support '80' connected to the 'c'-shaped support 30 by a wire 81; Power generation means 90 is installed on the lower surface of the central portion of the mounting table (10); A windmill wing fixing means 90 'installed on the inner wing installation portion 40 so as to be movable upward and downward on the vertical axis of rotation 20 to fix the displacement of the windmill blade 70; Wind turbine with a variable windmill wings consisting of a fixing means drive device (100 ') installed on the lower end side of the vertical rotation shaft (20). According to claim 1, wherein the inner wing mounting portion 40 is divided into a mounting hole (40a) and the mounting hole (40b) so that the mounting hole (40a) and the mounting hole (40b) is separated by the bolt 41 One end of the support rod 40 'is inserted into the inner wing installation hole 40 in the front, rear, left, and right directions in the horizontal direction, and is fixed by the bolt 42 inserted downward from the upper surface thereof. One end of the blade rotation shaft 71 is rotatably inserted into the inner wing installation hole 40 on the same plane, and the windmill blade is installed in the inner wing installation hole 40 under the support rod 40 'and the blade rotation shaft 71 insertion portion. One end of the rotating shaft 96 of the fixing means 90 'is rotatably inserted, and the other end of the supporting rod 40' is inserted into and fixed to the outer wing fitting 50, and the blade rotating shaft 71 and the rotating shaft are fixed. (96) Variable windmill blade, characterized in that the other end is rotatably inserted into the outer wing installation 50 Wind generator with dog. According to claim 2, wherein the inner wing mounting device 40 is a structure separated so that the cut surface of the central portion divided into the mounting tool 40a and the mounting tool 40b parallel to the outer side, the mounting tool (40a ') And wind turbine generators with variable windmill wings, characterized in that the cut surface divided into two installation holes (40b ') is classified into a diagonal structure and is employed for each group of windmill wings 70 that form a group in the upper and lower stages. . According to claim 1, The windmill blade 70 is a blade rotating shaft 71 is rotatably installed between the inner wing installation 40 and the outer wing installation 50 on the same plane as the support rod 40 '. ), A wing piece 72 having one side fixed to the blade rotation shaft 71, and inserted into a central portion of the blade rotation shaft 71 to maintain the blade piece 72 at a horizontal plane of 45 ° during non-operation. The wind turbine with a variable windmill wings, characterized in that the wing spring (73) is configured. 5. The blade rotation shaft 71 of claim 4, wherein the blade rotation shafts 71 positioned on the same plane in the same group are connected and fixed by a plurality of rigid supports 60d, and a plurality of blade rotation shafts 71 are supported. The rigid support of 60e is connected and fixed, the support 60d and the support 60e and the support 60d and the support ring 60 is provided with a variable windmill wings, characterized in that the connection is fixed to each other. Wind power generator. The wind turbine generator of claim 4, wherein the wing piece (72) is any one of transparent or opaque tempered plastic, tempered glass, nonferrous metal, and duralumin. According to claim 1, wherein the support (80) is divided into a support (80a) and the support (80b) so that the support (80a) and the support (80b) is separated by the bolt 82, the support (80a) The support plate is inserted into the circular protrusion 83 of the lower surface formed by the combination of the support and the support (80b), the support plate is divided into the support plate (84a) and the support plate (84b) to form a hinge structure on one side, the other side bracket (85) One end of the wire 81 is fixed to the square corner portion of the state coupled to the bolt 86 via the support plate 84a and the support plate 84b, and the other end of the wire 81 'C' wind turbine with a variable windmill wing, characterized in that is fixed to the support (30). The method of claim 1, wherein the windmill blade fixing means (90 ') is divided into a moving hole (91a) and the moving hole (91b) to move up and down on the vertical axis of rotation in the state in which the vertical axis of rotation (20) is inserted in the center. The movable tool 91a and the movable tool 91b are separated by the bolt 92, and the movable tool 91a and the movable tool 91b are moved up and down between the movable tool 91a and the movable tool 91b. The moving shaft 93 for moving is inserted and fixed, and one end of the straight lever 94 is fixed to each of the outer surfaces formed by the moving tool 91a and the moving tool 91b, and the straight lever 94 One end of the 'L' shaped lever 95 is rotatably connected to the other end, and the other end of the 'L' shaped lever 95 has the rotating shaft 96 inserted with the rotating shaft 96 having the spring 96a inserted therein. Rotation of the 'L' shaped lever 95 is inserted into the inner wing installation 40 and rotatably inserted into the inner wing installation 40 where the other end of the 'L' shaped lever 95 is located. A stopper pin (95a) for stopping the stop is inserted and fixed, one end of the spring (96a) is fixed to the support rod 40 'and the other end is connected to the connection of the straight lever 94 and the L-shaped lever (95) It is fixed on the adjacent 'L' shaped lever (95), the wind turbine with a variable windmill wings, characterized in that a plurality of levers (97) are fixed at regular intervals on the rotary shaft (96). 9. The moving tool (91a ') of claim 8, wherein the moving tool (91a) and the moving tool (91b) form a structure in which the cut surface of the central portion divided into two parts is parallel to the outer side, and the cut tool has a diagonal structure. And a moving tool 91b ', which is further provided with a moving tool 91a and a moving tool 91b in one group of the windmill wings 70 which are grouped in multiple stages up and down, and a moving tool in the other group. Wind turbine with a variable windmill blade, characterized in that (91a ') and the moving port (91b') is employed. According to claim 1, wherein the fixing means drive device (100 ') and the rectangular cylinder (101'); A lower fixing plate 102 'fixed to a lower portion of the rectangular cylinder 101'; A pair of rollers 103 'installed at one side of a lower surface of the lower fixing plate 102'; A lower roller 104 'installed at each corner of a lower surface of the lower fixing plate 102'; A lower movable plate 105 'moving up and down in the rectangular cylinder 101'; A spring 106 'inserted into a central portion of an upper surface of the lower movable plate 105'; A plurality of moving shafts 107 'which are erected and fixed at the corners of the lower movable plate 105'; An upper fixing plate 108 'fixed to an upper portion of the rectangular cylinder 101'; An upper roller 109 'installed at each lower edge of the upper fixing plate 108'; An upper moving plate 110 'fixed to an upper end of the plurality of moving shafts 107'; A rope 111 'composed of rope branches 111a to 111d caught by the pair of rollers 103' and upper and lower rollers 109 'and 104'; Wind turbine with a variable windmill wings, characterized in that consisting of a motor (112 ') for winding and releasing the rope (111). The rectangular cylindrical body (101 ') has a guide groove (101a) of the upper and lower long groove is formed on one side, the lower fixing plate (102') is the square by the 'b' shaped bracket (a) It is fixed to the lower portion in the cylinder 101 ', the roller 103' and the roller 104 'is fixed to the lower surface of the lower fixing plate 102' by the bracket (b), the moving shaft 107 ' The lower end thereof is fixed to the edge of the lower movable plate 105 'by the nuts c and c', and the upper end of the movable shaft 107 'is connected to the upper movable plate 110'. ') Is fixed, the guide bundle (105a) having a guide protrusion (d) is fixed to one side of the upper surface of the lower movable plate (105'), the guide protrusion (d) is inserted into the guide groove (101a), A fixing protrusion (e) is formed at the side of the upper fixing plate (108 ') so that the fixing protrusion (e) is inserted into and fixed to the side of the inside of the rectangular cylinder (101') and a bracket (on the lower surface of the upper fixing plate (108 ')). b) to It is fixed to the upper roller (109 '), a wind power generator having the variable windmill wings which is characterized in that. According to claim 1, wherein the windmill wings 70 are installed in a plurality of stages in the top and bottom n stages, and a plurality of wind generators (A) having a top and bottom n stage windmill wings 70 in a horizontal direction, respectively, Wind turbines with variable windmill wings, characterized in that the power generation means 90 for each of the wind generators (A) is electrically connected to each other and configured to combine the power generated by each of the power generation means (90). The plurality of wind turbines (A) having the upper and lower n-stage windmill blades (70) according to claim 12, when a plurality of wind turbines (A) are installed in the horizontal direction of the front, rear, left and right, the plurality of pillars (X) perpendicular to the front, rear, left and right. Wind turbines with variable windmill wings, characterized in that the up and down, left and right struts (X) and the bearing (20 ') of each of the wind turbine (A) with a wire (Y).

Images