JP5594811B2 - Combined wind power generator - Google Patents

Description

  The present invention relates to a combined wind power generator, and more specifically, a combined wind power having a novel structure capable of obtaining a combined power generation output by both wind power and solar energy by integrally combining a windmill and a solar panel. The present invention relates to a power generation device.

  In recent years, from the viewpoint of preventing global warming and environmental destruction by power generation facilities using fossil fuels, natural energy such as wind power generation devices using wind turbine rotation by wind power, solar power generation facilities using solar heat, etc. Various power generation facilities utilizing the above have been proposed and put into practical use.

  In addition, many composite power generation systems combining wind power generators and solar power generation facilities have been proposed.

  However, in the case of conventional combined power generation systems, most wind turbines for wind power generation and solar panels for solar power generation are configured separately, and the wind turbine and solar panel are integrated. There are currently no simple and good-looking structures combined with the above.

  In Patent Document 1, a rotating dome provided with a plurality of blades is rotatably provided on a dome support having a relatively large diameter via a thrust roller and a radial roller, and the rotating dome is fitted to the dome support, Insert the rotating shaft of the rotating dome into the dome support and properly bearing it to obtain wind power output from the rotation of the rotating shaft, and provide a solar power generation module on the upper surface of the rotating dome. There has been proposed a wind power generation apparatus configured to collect power from a wind power generation output to obtain electric power.

  Also in this patent document 1, the rotating dome functioning as a windmill and the photovoltaic power generation module are separately configured, and the two are not integrated.

JP 2003-83228 A

  The problem to be solved is a composite type that can obtain a combined power output from both wind power and solar energy while having a simple and well-structured structure that combines a windmill and a solar panel integrally. There is no wind power generator.

  The present invention provides a support base shaft that is fixedly supported in a vertical arrangement in order to obtain a combined power generation output by both wind and solar energy with a simple and well-structured structure in which a windmill and a solar panel are integrally combined. A vertical axis vertical airfoil wind turbine supported by the support base shaft, a rotor that outputs power generated by the rotation of the wind turbine, a generator having a coreless coil body coaxially inverted, and a vertical blade of the wind turbine And a solar power transmission body that outputs solar power that is supported by the support base shaft and transmitted from the solar panel via a transmission cable. To do.

According to the present invention , a wind turbine having a vertical axis vertical airfoil structure with three streamline blades and three solar panels attached to each blade are combined together, and an outer rotor and a coreless coil body are coaxially combined. Provided is a combined wind power generator capable of obtaining a combined power generation output by effectively using both wind energy and solar energy based on a simple and good-looking structure equipped with a reversible generator. be able to.

According to the second aspect of the present invention, both wind power and solar light have the same structure as that of the first aspect of the invention, and a simple and good-looking structure with a multi-stage coreless coil body. It is possible to provide a combined wind power generator that can effectively use the energy of the above to obtain a combined power generation output and increase the power generation output by wind power.

According to the invention described in claim 3, a wind turbine having a vertical axis vertical airfoil and a three-streamline blade structure and three solar panels attached to each blade are combined together, and an inner rotor and a coreless type are combined. Combined wind power generation that can use both wind power and solar energy effectively to obtain a combined power generation output based on a simple and good-looking structure equipped with a power generator that uses a coaxial reversal type coil body An apparatus can be provided.

According to the invention described in claim 4 , both wind power and sunlight are based on the same configuration as that of the invention described in claim 3 , and based on a simple and good-looking structure in which the coreless type coil body has a multi-stage structure. It is possible to provide a combined wind power generator that can effectively use the energy of the above to obtain a combined power generation output and increase the power generation output by wind power.

1 is a schematic front view of a combined wind power generator according to an embodiment of the present invention. It is a schematic plan view of the combined wind power generator according to the present embodiment. It is the elements on larger scale which show the attachment state of the braid | blade with respect to the support base shaft in the composite type wind power generator which concerns on a present Example, a solar panel, and a solar power transmission body. It is an expansion perspective view which shows the braid | blade and solar panel in the composite type wind power generator concerning a present Example. It is an expansion perspective view of the back surface of the blade in the combined wind power generator according to the present embodiment. It is a general | schematic exploded sectional view which shows the coaxial inversion type coreless generator in the composite type wind power generator which concerns on a present Example. It is a schematic plan view of the coaxial inversion type coreless generator in the composite type wind power generator concerning this example. It is a general | schematic exploded sectional view which shows the modification of the coaxial inversion type coreless generator in the composite wind power generator of a present Example. It is a general | schematic exploded sectional view which shows another modification of the coaxial inversion type | mold coreless generator in the composite type wind power generator which concerns on a present Example.

  The present invention is supported by a support base for the purpose of obtaining a combined power generation output by both wind power and solar energy while having a simple and well-structured structure in which a windmill and a solar panel are integrally combined. A vertical axis vertical airfoil windmill, a rotor that outputs power generated by the rotation of the windmill, a generator with a coreless coil body coaxially inverted, and a solar panel attached to the surface of the vertical blade of the windmill And a solar power transmission body that outputs solar power that is supported by the support base shaft and transmitted from the solar panel through a transmission cable, and realized by a simple configuration.

  Hereinafter, a combined wind turbine generator 101 according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 7.

  As shown in FIGS. 1 to 3, the combined wind power generator 101 according to this embodiment includes, for example, a gyromill (vertical axis vertical blade type) and a streamlined blade 5 having, for example, three streamlined blades 5. A power generation output is obtained using the rotational force of the windmill 2 that is disposed between the lower end and the upper end of the hollow support base 6 that supports the windmill 2 at a predetermined height from the ground. A coaxial inversion type coreless generator 1, three solar panels 102 of, for example, a polycrystalline module and an amorphous module structure that generate electricity by sunlight attached to the surface of each blade 5 of the windmill 2, and the support base 6 The solar power that is supported coaxially with the coaxial reversing coreless generator 1 and transmitted from the solar panel 102 via the transmission cable 103 is passed through the current collector 105. Wind power comprising a solar power transmission member 104, a retrieving Te constitute the solar power generation complex structure.

  For example, three blades 5 are attached to the wind turbine shaft 3 at an equal interval of 120 degrees around the wind turbine shaft 3 via an arm 4 with respect to the wind turbine shaft 3, and the lower end portion 3a of the wind turbine shaft 3 is connected to the coaxial inversion type. The solar power transmission body 104 is attached to the coreless generator 1 and further to the lower side of the coaxial inversion coreless generator 1.

  Here, the solar power transmission body 104 supported at the lower position of the coaxial inversion coreless generator 1 by the support base shaft 6 will be described with reference to FIG.

  The solar power transmission body 104 includes a rotating annular body 106 that is rotatably supported via a bearing 112 with respect to the support base shaft 6, and is disposed below and in proximity to the support base shaft 6. A fixed annular body 107 fitted and fixed to a hollow annular transmission arm 108 having one end connected to the outer peripheral portion of the rotating annular body 106 and the other end connected to the back side of the blade 5; A slip ring 109 constituting a current collector 105 disposed on a surface facing the fixed annular body 107 and a current collector disposed on the surface of the stationary annular body 107 facing the rotating annular body 106 so as to contact the slip ring 109. And a brush 110 constituting 105.

  One end of the transmission cable 103 that penetrates the transmission arm 108 is connected to the solar panel 102, and the other end is connected to the slip ring 109. Further, another transmission cable 103a having one end connected to the brush 110 is connected to the controller 111 described later via the support shaft 6, and further, the power generation output by the solar panel 102 is supplied to a load (not shown). ing.

  In FIG. 3, the power transmission structure for one solar panel 102 is shown, but it goes without saying that the remaining two solar panels 102 are configured in the same manner as described above. Further, as the current collector 105, for example, a brushless type current collector including a configuration using electromagnetic inductive coupling of a primary transformer and a secondary transformer, a configuration combining a magnet, a coil, and an electronic circuit for commutation, and the like. You can also

  Next, specific examples of the blade 5 and the solar panel 102 in the combined wind turbine generator 101 according to this embodiment will be described with reference to FIGS. 4 and 5.

  In this embodiment, the material of the blade 5 is an aluminum alloy material that is corrosion-resistant and recyclable, and its side surface shape is a streamline shape that generates lift by wind energy as shown in FIG. As a whole, the plane is formed in a substantially rectangular shape.

  Moreover, as shown in FIG. 5, the back surface of the blade 5 (surface on the wind turbine shaft 3 side) is provided with an opening 5a for capturing wind energy from the back surface over a plurality of locations.

  By adopting such a blade 5, wind energy can be efficiently converted into generated power regardless of the wind direction from wind speed 1 m / sec to strong wind, and mechanical strength is high and durability. The windmill 2 excellent in safety is configured.

  Further, a thin plate-like solar panel 102 is attached over substantially the entire surface of the blade 5, thereby forming a composite type windmill 2 having a simple structure that has not been heretofore integrated with the blade 5 and the solar panel 102. .

  According to the composite wind power generator 101 according to the present embodiment as described above, a combined power generation output by the energy of both wind power and sunlight is obtained with a simple structure in which the windmill 2 and the solar panel 102 are integrally combined. Can be obtained. The windmill 2 is not limited to the three-blade structure described above, and a four-blade structure or the like can also be employed.

  Next, the coaxial inversion coreless generator 1 in the composite wind power generator 101 according to the present embodiment will be described in detail with reference to FIGS. 6 and 7.

  As shown in FIG. 6, the coaxial reversing coreless generator 1 includes a generator body 10 and a shaft support 11 that rotatably supports the generator body 10.

  The generator body 10 includes an outer rotor 12 that rotates in response to the rotational force of the windmill 2, a generator shaft 13 that pivotally supports the central portion of the outer rotor 12, and that allows the outer rotor 12 to rotate. And a disk-like coreless coil body (a bundle of coils compressed into a disk shape) 14 incorporated in the outer rotor 12 in a state where the central portion is supported by the generator shaft 13.

  The generator shaft 13 is provided with a screw 13a at the lower end, a large diameter portion 13b at the upper end side, and a protruding disc portion 13c below the large diameter portion 13b.

  The outer rotor 12 has a dish-disk-shaped upper rotor 21 having an opening on the lower side and a dish-disk-shaped lower rotor 31 having an opening on the upper side but joined to each other in a vertical arrangement, and is arranged in a circle at a position near the outer periphery of both. Are fixed together using a number of fixing bolts 22.

  The upper rotor 21 of the outer rotor 12 is fitted with the upper end portion of the generator shaft 13 at the lower side of the center portion, and is provided with a cylindrical windmill mounting portion 21a protruding upward at the center portion.

  The wind turbine mounting portion 21a is provided with a number of screw holes 21b in a circular arrangement, and is joined to the lower end portion 3a of the wind turbine shaft 3 to connect the upper rotor 21 and the lower end portion 3a of the wind turbine shaft 3 with mounting bolts (not shown). They are integrally connected and configured to transmit the rotational force of the wind turbine shaft 3.

  Further, a main bearing 23 is disposed between the upper surface side of the large-diameter portion 13b of the generator shaft 13 and the inner bottom portion of the upper rotor 21 in the vicinity thereof, so that the upper rotor 21, and thus the outer rotor 12 can be rotatably supported. doing.

  A circular protrusion 25 having an inner diameter slightly larger than that of the large-diameter portion 13b is provided at an outer position of the main bearing 23 in the inner bottom portion of the upper rotor 21, and the lower end surface of the circular protrusion 25 is circular over the entire circumference. A gear 26 is provided.

  At a position near the outer periphery of the inner bottom portion of the upper rotor 21, a required number of magnets 24 are embedded in a circular arrangement with the end face facing the inner bottom surface.

  The lower rotor 31 is formed in a substantially symmetrical shape with respect to the upper rotor 21. That is, a circular concave step portion 32 into which the protruding disc portion 13c enters is provided on the upper surface of the central portion, and the generator shaft 13 is configured to penetrate the central position of the circular concave step portion 32.

  Further, in the vicinity of the outer periphery of the inner bottom portion of the lower rotor 31, a required number of magnets 24 are embedded in a circular arrangement in such a manner that the end surface faces the inner bottom surface and is opposed to the magnets 24 on the upper rotor 21 side. doing.

  With such a configuration of the upper rotor 21 and the lower rotor 31, an accommodation chamber 33 for accommodating the coreless type coil body 14 is formed inside both of them.

  On the lower surface side of the lower rotor 31, a cylindrical mounting portion 34 that protrudes downward is provided at the center thereof, and a screw hole 35 is provided in a circular arrangement in the mounting portion 34.

  The coreless coil body 14 is coaxially arranged with the outer rotor 12 in the accommodating chamber 33, and an upper hole having an inner diameter into which the circular protrusion 25 of the upper rotor 21 enters, A slightly larger diameter hole than the large-diameter portion 13b of the generator shaft 13 is provided so that the large-diameter portion 13b passes therethrough.

  The coreless coil body 14 is rotatably supported by the generator shaft 13 via a bearing 46 disposed between the outer periphery of the lower end of the large diameter portion 13b and the prepared hole of the coreless coil body 14.

  A coil portion 41 is disposed on the upper surface of the coreless coil body 14 so as to correspond to and close to the magnet 24 on the upper rotor 21 side. Similarly, the lower rotor 31 is disposed on the lower surface thereof. The coil part 41 is arranged in a state of being in a corresponding arrangement with the magnet 24 on the side and in the proximity thereof.

  Furthermore, each coil part output end 42 in each of the upper and lower coil parts 41 in the coreless type coil body 14 is disposed at a position facing the lower surface of the coreless type coil body 14, and the power generation located in the circular concave step part 32. It is comprised so that the protrusion disc part 13c in the axis 13 may be made to oppose.

  Then, the generator main body 10 is connected to each brush (collector) 43 disposed on the upper surface of the projecting disk portion 13 c corresponding to each coil portion output end 42 via an output cable 44 connected to each brush 43. It is configured to take out the power generation output by.

  Instead of the configuration of each coil portion output end 42 and brush 43, for example, a configuration using electromagnetic inductive coupling of a primary transformer and a secondary transformer, a magnet for the coreless coil body 14, and a coil on the protruding disk portion 13c side. In addition, a brushless type current collector having a configuration in which an electronic circuit for commutation is provided may be used.

  A circular gear 45 similar to the circular gear 26 of the circular protrusion 25 is provided over the entire circumference on the upper surface side (upper hole side) of the circular protrusion 14 a that forms the lower hole in the coreless coil body 14. .

  A plurality of reverse gears 51 are mounted on the outer periphery of the large-diameter portion 13b of the generator shaft 13 so as to be positioned in the upper hole and have a rotational axis in the horizontal direction. The reverse gears 51 are connected to the circular gear 26. The gears are respectively coupled to the circular gears 45.

  With such a configuration, when the outer rotor 12 rotates in the direction of arrow a shown in FIG. 2, the coreless coil body 14 is configured to reversely rotate in the direction of arrow b shown in FIG. Yes.

  That is, the outer rotor 12 and the coreless coil body 14 are configured to be coaxially reversed using the reverse gear 51.

  The shaft support 11 has a fixed support 61 for fixing and supporting the generator shaft 13 by fitting the generator shaft 13 into a central hole 61a and projecting it downward, and screwing a nut 62 into the screw 13a of the generator shaft 13 from below. A superposed structure is formed with the rotating support 71 through which the generator shaft 13 passes through a through-hole 71a having the same diameter as the central hole 61a provided in the central portion in close contact with the fixed support 61.

  That is, the rotary support 71 is rotatably supported with respect to the fixed support 61 via a bearing 63 provided therebetween, and is rotated in a circular groove 61b provided on the outer periphery of the upper surface of the fixed support 61. A circular ridge 71 b provided on the outer peripheral portion of the lower surface of the support 71 is fitted, whereby the rotation support 71 is configured to be able to rotate smoothly while closely contacting on the fixed support 61.

  A screw hole 64 is provided on a side surface of the fixed support 61 so as to be orthogonal to the axial direction of the central hole 61a. The upper end of the support base shaft 6 is fitted from below the fixed support 61, and a bolt 65 is used. The shaft support 11 is configured to be attached to the upper end portion of the support base shaft 6.

  A mounting bolt 72 is disposed on the rotary support 71 in a position corresponding to the screw hole 35 of the mounting portion 34 in the lower rotor 31, and this rotation is performed before the rotary support 71 and the fixed support 61 are assembled. The support 71 is attached to the lower rotor 31, and then the fixed support 61 is assembled to the rotation support 71.

  A support bearing 73 for the generator shaft 13 is disposed at the upper end portion of the through hole 71 a in the rotary support 71.

  In FIG. 2, reference numerals 52 denote roller bearings disposed between the upper rotor 21 and the coreless coil body 14 and between the lower rotor 31 and the coreless coil body 14.

  According to the coaxial reversible coreless generator 1, when the windmill 2 rotates in the direction of arrow a shown in FIG. 2 by wind energy, for example, the outer rotor 12 also rotates in the direction of arrow a. The force is transmitted to the reverse gear 51. As a result, the coreless coil body 14 rotates in the direction of the arrow b shown in FIG. 2 via the reverse gear 51 (coaxial reversal).

  As a result, a large power generation output corresponding to an increase in the relative speed between each magnet 24 and the coil portion 41 is transmitted from the coil portion output end 42 of the coreless type coil body 14 to the controller 111 via the brush 43 and the output cable 44. It is possible to transmit power and supply power to a load (not shown).

  More specifically, according to the coaxial reversing coreless generator 1, the outer rotor 12 and the coreless coil body 14 are coaxially reversed only by a simple element called the reverse gear 51 according to the rotation of the windmill 2. For example, twice the relative speed can be obtained between the outer rotor 12 and the coreless coil body 14 as compared with a generator using a normal rotor and stator, and the same wind energy is required. Below, it becomes possible to obtain a power generation output larger than that of a normal wind power generator.

  Specifically, when it is assumed that the power generation output is 100 at a rotation speed of 100 in a normal generator, the coaxial inversion coreless generator 1 according to the present embodiment generates 100 power generations at a rotation speed of 50. Output can be obtained. Or, if the rotational speed is 100, 200 power generation outputs can be obtained.

  Next, a coaxial inversion coreless generator 1A, which is a modification of the coaxial inversion coreless generator 1, will be described with reference to FIG.

  The coaxial reversing coreless generator 1A of the modification is basically based on the same principle as the coaxial reversing coreless generator 1 described above, and has a similar configuration. The same elements as those of the machine 1 are denoted by the same reference numerals, and detailed description thereof is omitted.

  A coaxial inversion coreless generator 1A according to a modification employs a generator body 10A shown in FIG. 4 in place of the generator body 10 in the coaxial inversion coreless generator 1 described above.

  In other words, the intermediate rotor 30 is interposed between the upper rotor 21 and the lower rotor 31 integrally with the upper rotor 21 and the lower rotor 31, and the upper rotor 21 and the intermediate rotor 30 and the intermediate rotor 30 and the lower rotor 31 are vertically arranged in two stages. The outer rotor 12 </ b> A including the storage chambers 33, 33 having the same configuration as the case is used.

  Then, the two coreless coil bodies 14 having the same configuration as those described above are disposed in the two accommodating chambers 33 in the outer rotor 12A, and the generator shaft 13 is also vertically moved correspondingly. The reverse rotation gear 51 is arranged over two stages, and the two coreless type coil bodies 14 are driven to be coaxially reversed. The brushes 43 are arranged over the generator shaft 13 over two stages, and an output cable is connected to each brush 43. 44 is connected and the power generation output is taken out through the upper and lower brushes 43.

  Moreover, although not shown in FIG. 4, the coaxial reversing coreless generator 1 </ b> A of the modification is fitted and supported by the shaft support 11.

  Also in the coaxial reversing coreless generator 1A of the modified example, as in the case of the coaxial reversing coreless generator 1, the outer rotor 12 and each coreless coil are compared with the generator using a normal rotor and stator. For example, it is possible to obtain, for example, twice the relative speed between the bodies 14 and 14, and to obtain a larger power generation output under the same wind energy conditions.

  Thereby, if it is set as the composite wind power generator 101 which employ | adopted the coaxial inversion type coreless generator 1A of this modification instead of the said coaxial inversion type coreless generator 1, the windmill 2 and the solar panel 102 will be integrated. Although the combined structure is simple, it is possible to obtain a combined power generation output by both wind power and solar energy, and in particular, it is possible to realize a combined wind power generation apparatus 101 that can further increase the power generation output by wind power.

  In addition, in the coaxial reversal type coreless generator 1A of the modified example, the case where the two-stage coreless type coil body 14 is arranged in the outer rotor 12A is shown, but in addition to this, there are three stages and four stages in the outer rotor. It is also possible to have a configuration in which a multi-stage coreless type coil body is arranged. By adopting these structures, it is possible to obtain a combined power output by both wind power and solar energy while being a simple structure. In particular, it is possible to realize the combined wind power generator 101 that can further increase the power generation output by wind power.

  Next, a coaxial inversion coreless generator 1B, which is still another modification, will be described with reference to FIG. The coaxial inversion coreless generator 1B is characterized in that it adopts the same configuration as the coaxial inversion coreless generator 1 and is an inner rotor type.

  In FIG. 9, the same components as those of the coaxial reversing coreless generator 1 are denoted by the same reference numerals, and detailed description thereof is omitted.

  A coaxial inversion coreless generator 1 </ b> B shown in FIG. 9 includes an inner rotor type generator main body 80 fixedly disposed on a shaft support 81.

  The generator main body 80 includes a housing 83, an inner rotor 82 having substantially the same structure as the outer rotor 12 that rotates by receiving the rotational force of the windmill 2, and a housing 83 that pivotally supports a central portion of the inner rotor 82. And the generator shaft 13 similar to the above-described case where the inner rotor 82 is rotatable and the center portion is supported by the generator shaft 13 and is built in the inner rotor 82. And a disk-like coreless type coil body 14 similar to the above case.

  The housing 83 is configured to cover an upper surface, a side surface, and a lower surface of the upper rotor 21 constituting the inner rotor 82 except for the wind turbine mounting portion 21a. An attachment portion 83a is provided on the lower surface side, and the attachment portion 83a is in close contact with the shaft support 81 and is configured to be attached to the shaft support 81 integrally.

  The shaft support 81 has substantially the same configuration as that of the shaft support 11, but the configuration of the rotation support 71 is omitted, and includes, for example, an upper support 91 and a lower support 92 in a vertically divided structure. A bolt 93 projecting upward from the inside of the upper support 91 is screwed into a screw hole 83 a provided in the mounting portion 83 a of the housing 83 so as to be integrated with the housing 83.

  Other configurations are the same as those of the coaxial reversing coreless generator 1.

  According to the coaxial reversal type coreless generator 1B, as in the case described above, the relative speed between the magnets 24 and the coil portion 41 is increased by the reverse rotation of the inner rotor 82 and the coreless type coil body 14. A corresponding large power generation output can be transmitted from the coil portion output end 42 of the coreless type coil body 14 to the controller 111 via the brush 43 and the output cable 44.

  As a result, as in the case of the coaxial reversal type coreless generator 1, it is possible to obtain, for example, twice the relative speed between the inner rotor 82 and the coreless type coil body 14 as compared with a generator using a normal rotor and stator. Therefore, it is possible to obtain a larger power output than a normal wind power generator under the same wind energy conditions.

  Also in this case, it is of course possible to arrange the multi-stage coreless type coil body 14 in the inner rotor 82 in two stages, three stages, four stages, and the like. The same operations and effects as in the case of the generator 1A and the like can be exhibited.

  Therefore, if the composite wind power generator 101 adopting the coaxial reversal type coreless power generator 1B of this modification instead of the coaxial reversal type coreless power generator 1, the windmill 2 and the solar panel 102 are integrated. In addition to the simple structure combined with the above, it is possible to obtain a combined power generation output by both wind and solar energy. Further, if a multi-stage coreless coil body 14 is arranged, the power generation output by wind power can be further increased. The composite wind power generator 101 that can be increased can be realized.

The combined wind power generator of the present invention can be widely applied to various fields such as street lights, signal lights, highway illumination lights, disaster prevention, communication, and energy bases.

DESCRIPTION OF SYMBOLS 1 Coaxial reversal type coreless generator 1A Coaxial reversal type coreless generator 1B Coaxial reversal type coreless generator 2 Windmill 3 Windmill shaft 3a Lower end part 4 Arm 5 Blade 5a Opening part 6 Support base shaft 10 Generator main body 11 Shaft support body 12 Outer rotor DESCRIPTION OF SYMBOLS 13 Generator shaft 13a Screw 13b Large diameter part 13c Projection disc part 14 Coreless type coil body 14a Circular projection part 21 Upper rotor 21a Windmill attachment part 21b Screw hole 22 Fixing bolt 23 Main bearing 24 Magnet 25 Circular projection 26 Circular gear 30 Medium Rotor 31 Lower rotor 32 Circular concave step portion 33 Accommodating chamber 34 Mounting portion 35 Screw hole 41 Coil portion 42 Coil portion output end 43 Brush 44 Output cable 45 Circular gear 46 Bearing 51 Reverse gear 52 Roller bearing 61 Fixed support 61a Central hole 61b Circular groove 62 Nut 3 Bearing 64 Screw hole 65 Bolt 71 Rotating support 71a Through hole 71b Circular protrusion 72 Mounting bolt 73 Support bearing 80 Generator body 81 Shaft support body 82 Inner rotor 83 Housing 83a Mounting portion 91 Upper support body 92 Lower support body 93 Bolt DESCRIPTION OF SYMBOLS 101 Combined wind power generator 102 Solar panel 103 Transmission cable 103a Transmission cable 104 Solar power transmission body 105 Current collector 106 Rotating annular body 107 Fixed annular body 108 Transmission arm 109 Slip ring 110 Brush 111 Controller 112 Bearing

Claims (4)

A support shaft fixedly supported in a vertical arrangement;
A vertical axis vertical airfoil wind turbine supported by the support base shaft, a rotor that outputs power generated by the rotation of the wind turbine, a coaxial reversing coreless generator having a coreless coil body as a coaxial reversing type, and
A solar panel attached to the surface of the vertical wing of the windmill;
A solar power transmission body that outputs solar power supported by the support base shaft and transmitted from the solar panel via a transmission cable;
In a combined wind power generator having
The coaxial reversing coreless generator includes a generator main body and a shaft support that rotatably supports the generator main body, and the generator main body includes:
A generator shaft, an outer rotor with a magnet that is rotatably supported by the generator shaft and is driven to rotate by the rotational force of the windmill, and a coaxial arrangement within the outer rotor and rotatably supported by the generator shaft A coreless type coil body in which a coil portion is arranged in correspondence with the magnet, and a gear connected to a circular gear that is supported by the generator shaft and provided in a circular arrangement on both the outer rotor and the coreless type coil body. A reverse gear that rotates the coreless coil body in the reverse direction according to the rotation of the rotor, and the relative speed between the magnet and the coil portion is increased by the reverse rotation of the outer rotor and the coreless coil body. Through a current collector that is fixedly arranged around the generator shaft from the coil part output end of the coreless type coil body. Configured to take out,
The shaft support is a fixed support that is fixedly supported by fitting a generator shaft of the generator body into a central hole and projecting downward, and screwing a nut into the screw of the generator shaft from below. A rotating structure through which the generator shaft penetrates a through hole having the same diameter as a central hole in which the generator shaft provided in the central portion is fitted in a close contact state on the fixed support body, and the rotation The support is rotatably supported with respect to the fixed support via a bearing provided between the two , and a lower peripheral portion of the lower surface of the rotary support is provided in a circular groove provided on the upper peripheral portion of the fixed support. The circular support provided on the fixed support is configured so that the rotary support can rotate smoothly while closely contacting the fixed support. Screw holes are provided in the arrangement perpendicular to the axial direction of the center hole, and fixed The coaxial inverted coreless generator can be supported by the support base shaft by fitting the upper end portion of the support base shaft from the lower side of the holding body and attaching the shaft support body to the upper end portion of the support base shaft using a bolt. Configure as you can
Further, the windmill is attached to the windmill shaft via an arm with three blades arranged at an equal interval of 120 degrees around the windmill shaft, and the lower end of the windmill shaft is attached to the coaxial inversion coreless generator. Each blade employs an aluminum alloy material that is corrosion-resistant and recyclable, and its side surface shape is a streamline shape that generates lift by wind energy, and is formed into a generally rectangular shape as a whole, and the back surface (on the wind turbine shaft side) The surface) is provided with openings for capturing wind energy from the back side over a plurality of locations, and a thin solar panel is attached over substantially the entire surface of each blade of the wind turbine, A combined wind turbine generator comprising a combined wind turbine integrated with a panel. A support shaft fixedly supported in a vertical arrangement;
A vertical axis vertical airfoil wind turbine supported by the support base shaft, a rotor that outputs power generated by the rotation of the wind turbine, a coaxial reversing coreless generator having a coreless coil body as a coaxial reversing type, and
A solar panel attached to the surface of the vertical wing of the windmill;
A solar power transmission body that outputs solar power supported by the support base shaft and transmitted from the solar panel via a transmission cable;
In a combined wind power generator having
The coaxial inversion coreless generator includes a generator main body and a shaft support that rotatably supports the generator main body, and the generator main body is rotatably supported by the generator and the generator shaft. And an outer rotor in which a multi-stage accommodation chamber is provided in the direction along the generator shaft, and magnets are arranged on the wall surfaces of the accommodation chamber,
A multi-stage coreless coil body in which each coil portion is disposed in a coaxial arrangement and rotatably supported by a generator shaft in each accommodating chamber, and is arranged corresponding to each magnet.
Each coreless coil body is reversely rotated according to the rotation of the outer rotor by being supported by the generator shaft and geared with each circular gear provided in a circular arrangement on both the outer rotor and each coreless coil body at each stage. And a multi-stage reversing gear that rotates
Each coil part output end of each coreless type coil body for generating output according to an increase in relative speed between each magnet and each coil part due to rotation of the outer rotor and each coreless type coil body in the reverse direction. Configured to be taken out through each current collector fixedly arranged in multiple stages around the generator shaft,
The shaft support is a fixed support that is fixedly supported by fitting a generator shaft of the generator body into a central hole and projecting downward, and screwing a nut into the screw of the generator shaft from below. A rotating structure through which the generator shaft penetrates a through hole having the same diameter as a central hole in which the generator shaft provided in the central portion is fitted in a close contact state on the fixed support body, and the rotation The support is rotatably supported with respect to the fixed support via a bearing provided between the two , and a lower peripheral portion of the lower surface of the rotary support is provided in a circular groove provided on the upper peripheral portion of the fixed support. The circular support provided on the fixed support is configured so that the rotary support can rotate smoothly while closely contacting the fixed support. Screw holes are provided in the arrangement perpendicular to the axial direction of the center hole, and fixed The coaxial inverted coreless generator can be supported by the support base shaft by fitting the upper end portion of the support base shaft from the lower side of the holding body and attaching the shaft support body to the upper end portion of the support base shaft using a bolt. Configure as you can
Further, the windmill is attached to the windmill shaft via an arm with three blades arranged at an equal interval of 120 degrees around the windmill shaft, and the lower end of the windmill shaft is attached to the coaxial inversion coreless generator. Each blade employs an aluminum alloy material that is corrosion-resistant and recyclable, and its side surface shape is a streamline shape that generates lift by wind energy, and is formed into a generally rectangular shape as a whole, and the back surface (on the wind turbine shaft side) The surface) is provided with openings for capturing wind energy from the back side over a plurality of locations, and a thin solar panel is attached over substantially the entire surface of each blade of the wind turbine, A combined wind turbine generator comprising a combined wind turbine integrated with a panel. A support shaft fixedly supported in a vertical arrangement;
A vertical axis vertical airfoil wind turbine supported by the support base shaft, a rotor that outputs power generated by the rotation of the wind turbine, a coaxial reversing coreless generator having a coreless coil body as a coaxial reversing type, and
A solar panel attached to the surface of the vertical wing of the windmill;
A solar power transmission body that outputs solar power supported by the support base shaft and transmitted from the solar panel via a transmission cable;
In a combined wind power generator having
The coaxial reversing coreless generator includes a generator main body and a shaft support that rotatably supports the generator main body, and the generator main body includes:
A fixedly arranged housing, a generator shaft fixedly supported in the housing, an inner rotor with a magnet that is rotatably supported by the generator shaft in the housing and driven to rotate by an external force, and in the housing The coreless coil body is coaxially arranged and rotatably built by the generator shaft, and the coil portion is arranged in correspondence with the magnet, and is supported by the generator shaft and is circularly arranged on both the inner rotor and the coreless coil body. And a reverse gear that rotates the coreless coil body in the reverse direction according to the rotation of the inner rotor by being gear-coupled with the circular gear provided on the inner rotor, and by rotating the inner rotor and the coreless coil body in the reverse direction. The power generation output corresponding to the increase in the relative speed between the magnet and the coil portion is obtained from the coreless coil body. Configured to retrieve from the yl unit output end through a fixing arrangement brushes around the generator shaft,
The shaft support is a fixed support that is fixedly supported by fitting a generator shaft of the generator body into a central hole and projecting downward, and screwing a nut into the screw of the generator shaft from below. A rotating structure through which the generator shaft penetrates a through hole having the same diameter as a central hole in which the generator shaft provided in the central portion is fitted in a close contact state on the fixed support body, and the rotation The support is rotatably supported with respect to the fixed support via a bearing provided between the two , and a lower peripheral portion of the lower surface of the rotary support is provided in a circular groove provided on the upper peripheral portion of the fixed support. The circular support provided on the fixed support is configured so that the rotary support can rotate smoothly while closely contacting the fixed support. Screw holes are provided in the arrangement perpendicular to the axial direction of the center hole, and fixed The coaxial inverted coreless generator can be supported by the support base shaft by fitting the upper end portion of the support base shaft from the lower side of the holding body and attaching the shaft support body to the upper end portion of the support base shaft using a bolt. Configure as you can
Further, the windmill is attached to the windmill shaft via an arm with three blades arranged at an equal interval of 120 degrees around the windmill shaft, and the lower end of the windmill shaft is attached to the coaxial inversion coreless generator. Each blade employs an aluminum alloy material that is corrosion-resistant and recyclable, and its side surface shape is a streamline shape that generates lift by wind energy, and is formed into a generally rectangular shape as a whole, and the back surface (on the wind turbine shaft side) The surface) is provided with openings for capturing wind energy from the back side over a plurality of locations, and a thin solar panel is attached over substantially the entire surface of each blade of the wind turbine, A combined wind turbine generator comprising a combined wind turbine integrated with a panel. A support shaft fixedly supported in a vertical arrangement;
A vertical axis vertical airfoil wind turbine supported by the support base shaft, a rotor that outputs power generated by the rotation of the wind turbine, a coaxial reversing coreless generator having a coreless coil body as a coaxial reversing type, and
A solar panel attached to the surface of the vertical wing of the windmill;
A solar power transmission body that outputs solar power supported by the support base shaft and transmitted from the solar panel via a transmission cable;
In a combined wind power generator having
The coaxial reversing coreless generator includes a generator main body and a shaft support that rotatably supports the generator main body, and the generator main body includes:
A housing having a fixed arrangement, a generator shaft fixedly supported in the housing, and rotatably supported by the generator shaft in the housing, driven to rotate by an external force, and accommodated in multiple stages in the direction along the generator shaft. An inner rotor having magnets arranged on the walls of the storage chambers, and coaxially arranged in each of the storage chambers and rotatably supported by a generator shaft. A multi-stage coreless type coil body having a portion arranged thereon and a shaft connected by the generator shaft, and geared with each of the circular gears provided in a circular arrangement over both the inner rotor and the coreless type coil body to rotate the inner rotor. And a multi-stage reversing gear that rotates each coreless coil body in the opposite direction according to the inner rotor, The power generation output corresponding to the increase in the relative speed between each magnet and each coil part due to the reverse rotation of each coreless type coil body is multistage around the generator shaft from each coil part output end of the coreless type coil body. It is configured to be taken out through each fixed current collector,
The shaft support is a fixed support that is fixedly supported by fitting a generator shaft of the generator body into a central hole and projecting downward, and screwing a nut into the screw of the generator shaft from below. A rotating structure through which the generator shaft penetrates a through hole having the same diameter as a central hole in which the generator shaft provided in the central portion is fitted in a close contact state on the fixed support body, and the rotation The support is rotatably supported with respect to the fixed support via a bearing provided between the two , and a lower peripheral portion of the lower surface of the rotary support is provided in a circular groove provided on the upper peripheral portion of the fixed support. The circular support provided on the fixed support is configured so that the rotary support can rotate smoothly while closely contacting the fixed support. Screw holes are provided in the arrangement perpendicular to the axial direction of the center hole, and fixed The coaxial inverted coreless generator can be supported by the support base shaft by fitting the upper end portion of the support base shaft from the lower side of the holding body and attaching the shaft support body to the upper end portion of the support base shaft using a bolt. Configure as you can
Further, the windmill is attached to the windmill shaft via an arm with three blades arranged at an equal interval of 120 degrees around the windmill shaft, and the lower end of the windmill shaft is attached to the coaxial inversion coreless generator. Each blade employs an aluminum alloy material that is corrosion-resistant and recyclable, and its side surface shape is a streamline shape that generates lift by wind energy, and is formed into a generally rectangular shape as a whole, and the back surface (on the wind turbine shaft side) The surface) is provided with openings for capturing wind energy from the back side over a plurality of locations, and a thin solar panel is attached over substantially the entire surface of each blade of the wind turbine, A combined wind turbine generator comprising a combined wind turbine integrated with a panel.

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