JP3199218U - Wind power generator - Google Patents

Abstract

A wind power generator capable of stably generating power using running water is provided. SOLUTION: A cylindrical main body 1 is provided in the vicinity of a flowing water portion 50 such as a river or an irrigation channel, a windmill portion 2 is provided in the cylindrical main body 1, and the windmill portion is provided in the cylindrical main body 1. A power generation unit 3 that generates electric power by rotation of 2 is provided, and a water turbine unit 4 that rotates in response to running water in the water flow unit 50 is provided in the water flow unit 50, and the wind turbine is driven by the rotational force of the water turbine unit 4. A blower unit 5 that blows air to the unit 2 and rotates the windmill unit 2 is provided. [Selection] Figure 1

Description

  The present invention relates to a wind turbine generator.

  Conventionally, as a wind power generator that generates power using wind power, for example, a wind power generator disclosed in Japanese Patent Application Laid-Open No. 2003-278635 (hereinafter referred to as a conventional example) has been proposed.

  This conventional example is a structure in which a wind turbine is provided in a cylindrical main body (commonly called a wind tunnel), and the power generation unit generates power by receiving wind passing through the cylindrical main body and rotating the wind turbine. This structure increases the wind flow and efficiently rotates the windmill.

  Therefore, the conventional example can generate electric power satisfactorily by rotating the windmill strongly even in a situation where the wind is weak.

JP 2003-278635 A

  The inventor has advanced further research and development on the wind turbine generator with a windmill in the cylindrical body described above, and as a result, developed an innovative wind turbine generator that demonstrates unprecedented effects. did.

  The gist of the present invention will be described with reference to the accompanying drawings.

  A cylindrical main body 1 is provided in the vicinity of a flowing water portion 50 such as a river or a water channel, and a windmill portion 2 is provided in the cylindrical main body 1, and the cylindrical main body 1 includes the windmill portion 2. A power generation unit 3 that generates electric power by rotation is provided, and the water flow unit 50 is provided with a water wheel unit 4 that rotates in response to water flowing in the water flow unit 50. The present invention relates to a wind turbine generator that is provided with a blower unit 5 that blows air to the windmill unit 2 and rotates the windmill unit 2.

  Further, in the wind turbine generator according to claim 1, the water turbine portion 4 is provided at a lower end portion of the movable arm portion 6 provided in the cylindrical main body 1 and is configured to float and rotate in flowing water of the flowing water portion 50. The present invention relates to a wind power generator characterized by being.

  The wind turbine generator according to any one of claims 1 and 2, wherein the cylindrical main body 1 is provided at a position above the flowing water portion 50. is there.

  Moreover, the wind power generator of any one of Claims 1-3 WHEREIN: The said water flow part 50 is a U-shaped groove structure which provided the side wall part 50b in the right and left of the bottom part 50a, and the said cylindrical main body 1 is the said The wind turbine generator according to the present invention is provided between the side wall portions 50b of the flowing water portion 50 and above the side wall portions 50b.

  5. The wind turbine generator according to claim 1, wherein the wind turbine unit 2 is provided with a wind turbine blade member 2 b on a wind turbine rotating shaft 2 a, and the water turbine unit 4 is mounted on a water turbine rotating shaft 4 a. A blade member 4b is provided, and the air blowing unit 5 is a wind power generator characterized in that the air blowing blade member 5b is provided on the air blowing rotating shaft 5a.

  The wind turbine generator according to claim 5, wherein the blower rotating shaft 5 a of the blower unit 5 is connected to the water turbine rotating shaft 4 a of the water turbine unit 4 via the rotational force transmission mechanism 8. It relates to a wind power generator.

  Since the present invention is configured as described above, compared to the above-described conventional example, it is possible to generate power in a cylindrical body by using flowing water and to stably generate power, and so on. It will be a groundbreaking wind power generator that will be demonstrated.

It is a perspective view explaining a present Example. It is operation | movement explanatory drawing of the principal part of a present Example. It is operation | movement explanatory drawing of the principal part of a present Example.

  The preferred embodiment of the present invention will be briefly described with reference to the drawings showing the operation of the present invention.

  The turbine unit 4 is rotated by receiving the flowing water from the flowing unit 50, and wind is generated from the blower unit 5 using the rotational force of the turbine unit 4 as a driving force.

  The wind turbine unit 2 rotates in response to the wind sent from the blower unit 5, and the wind turbine unit 2 rotates to generate power in the power generation unit 3.

  Therefore, it is possible to generate electricity stably by generating wind in the cylindrical main body 1 using running water.

  Specific embodiments of the present invention will be described with reference to the drawings.

  The present embodiment has a cylindrical main body 1 provided in the vicinity of a flowing water portion 50 such as a river or an irrigation channel, and a windmill portion 2 is provided in the cylindrical main body 1. A power generation unit 3 that generates electric power by rotation of the unit 2 is provided, and a water turbine unit 4 that rotates by receiving flowing water in the water flow unit 50 is provided in the water flow unit 50, and the rotational force of the water turbine unit 4 is used as a driving force. As a wind power generation apparatus, a blower unit 5 that blows air to the windmill unit 2 and rotates the windmill unit 2 is provided. In addition, although the flowing water part 50 of a present Example is a U-shaped groove structure (irrigation channel) which provided the side wall part 50b on the right and left of the inclination bottom part 50a, if it is an area | region with flowing water, a river, a lake, and the sea may be sufficient.

  Hereinafter, each component according to the present embodiment will be described in detail.

  The cylindrical main body 1 is a rectangular cylindrical main body formed of an appropriate metal member as illustrated in FIGS. 1 to 3, and includes a bottom plate portion 1 a, left and right side plate portions 1 b, and a top plate portion 1 c. The dimensions are set according to the size of the portion 50 (in this embodiment, the height and width are about 90 cm, and the length is about 180 cm). The cylindrical main body 1 may be cylindrical, the material may be made of synthetic resin or wooden, and may be a tunnel-like structure in which a sheet material is installed on a frame material.

  Moreover, the cylindrical main body 1 is provided in a erected state between the upper position of the flowing water part 50, specifically, between the upper ends of the left and right side wall parts 50b constituting the flowing water part 50.

  Further, a windmill portion 2 is provided at one end portion in the cylindrical main body 1.

  As shown in FIGS. 1 to 3, the wind turbine unit 2 is provided with a plurality of wind turbine blade members 2 b radially provided on the wind turbine rotating shaft 2 a, and a duct 2 c (tubular member) is provided around the wind turbine unit 2. Yes, the windmill portion 2 rotates upon receiving the wind passing through the duct 2c.

  In addition, the windmill part 2 is not restricted to the structure employ | adopted in the present Example.

  In this embodiment, the windmill portion 2 is connected to the power generation portion 3 installed on the top surface of the top plate portion 1c of the cylindrical main body 1 via a rotational force transmission mechanism (not shown). The power generation unit 3 is configured to generate power by receiving and rotating wind in the cylindrical main body 1.

  Further, an installation base 11 is provided in the cylindrical main body 1 at a position opposite to the windmill part 2, and the cylindrical rotating shaft part 13 rotates on the left and right bearing parts 12 provided on the installation base 11. A pair of arm members 6a project from the left and right positions of the rotary shaft 13, and a movable arm 6 is provided. The rotary shaft portion 13 is provided in a cylindrical shape so that a second rotary shaft 17 of the rotational force transmission mechanism 8 described later can be disposed therein.

  A water turbine unit 4 described later is provided at the lower end of the movable arm unit 6, and the movable arm unit 6 is configured to rotate in the vertical direction as the water turbine unit 4 moves in the vertical direction.

  As shown in FIGS. 1 to 3, the water turbine unit 4 is radially provided around a water turbine rotating shaft 4 a that is rotatably provided at the lower end of the movable arm unit 6, and a central diameter large portion 4 a ′ of the water turbine rotating shaft 4 a. And a plurality of turbine blade members 4b that protrude from the top.

  The central diameter portion 4 a ′ of the water turbine rotating shaft 4 a has a hollow structure that floats on water. Therefore, the water turbine portion 4 is configured as a buoyancy rotator that rotates while floating in the flowing water of the flowing water portion 50.

  Further, the water wheel rotating shaft 4 a of the water wheel unit 4 is connected to a blower rotating shaft 5 a of the air blowing unit 5 described later via a rotational force transmission mechanism 8.

  As shown in FIGS. 1 to 3, the rotational force transmission mechanism 8 is connected to the water wheel rotating shaft 4 a of the water wheel unit 4 via the water wheel rotating shaft 4 a and the bevel gear structure 14 and to the side of the movable arm unit 6. A first rotary shaft 15 provided; a second rotary shaft 17 connected to the first rotary shaft 15 via a bevel gear structure 16 and disposed in the rotary shaft portion 13; the second rotary shaft 17 and a pulley 18a. And a third rotating shaft 19 connected via a belt 18b. The third rotating shaft 19 is connected to the blower rotating shaft 5a of the blower 5 via a bevel gear structure (not shown).

  Therefore, the rotational force of the water turbine unit 4 is transmitted to the air blowing unit 5 via the rotational force transmission mechanism 8, and thus the air blowing unit 5 rotates using the rotational force of the water wheel unit 4 as a driving force to generate wind.

  The blower unit 5 is provided with a plurality of blower blade members 5b radially around a blower rotation shaft 5a rotatably provided on the installation base 11 as illustrated in FIGS. It is provided at the facing position.

  As described above, the rotational force of the water turbine unit 4 is transmitted to the blower unit 5 via the rotational force transmission mechanism 8, and thus the blower unit 5 rotates using running water.

  Since the present embodiment is configured as described above, the water turbine unit 4 rotates upon receiving water from the water flow unit 50, and wind is generated from the blower unit 5 using the rotational force of the water wheel unit 4 as a driving force. At this time, even if the water level of the flowing water part 50 changes, the movable arm part 6 moves up and down and the water turbine part 4 reliably receives the flowing water and rotates.

  The wind turbine unit 2 rotates in response to the wind sent from the blower unit 5, and the wind turbine unit 2 rotates to generate power in the power generation unit 3.

  Therefore, according to the present embodiment, it is possible to generate electricity stably by generating wind in the cylindrical main body 1 using running water.

  Further, in this embodiment, the water wheel unit 4 is provided at the lower end of the movable arm unit 6 provided in the cylindrical main body 1 and is configured to float and rotate in the flowing water of the flowing water unit 50, so that the water level of the flowing water unit 50 is In response to the above, the water turbine unit 4 rotates reliably.

  Further, in this embodiment, the flowing water portion 50 has a U-shaped groove structure in which side wall portions 50b are provided on the left and right sides of the bottom portion 50a. Since it is provided in the upper position, the structure is such that the upper space of the flowing water part 50 is effectively used.

  Further, in this embodiment, the water turbine unit 4 is provided with the water turbine blade member 4b on the water turbine rotating shaft 4a, and the air blowing unit 5 is provided with the air blade member 5b on the air rotating shaft 5a. Since the blower rotating shaft 5 a of 5 is connected to the water turbine rotating shaft 4 a of the water turbine unit 4 via the rotational force transmission mechanism 8, the rotational force of the water turbine unit 4 can be reliably transmitted to the air blowing unit 5. .

  The present invention is not limited to the present embodiment, and the specific configuration of each component can be designed as appropriate.

DESCRIPTION OF SYMBOLS 1 Cylindrical main body 2 Windmill part 2a Windmill rotating shaft 2b Windmill blade member 3 Electric power generation part 4 Waterwheel part 4a Waterwheel rotating shaft 4b Waterwheel blade member 5 Blower part 5a Blower rotating shaft 5b Blower blade member 6 Movable arm part 8 Rotational force transmission mechanism
50 Running water section
50a bottom
50b Side wall

Claims (6)

  A cylindrical main body provided in the vicinity of a flowing water section such as a river or an irrigation channel, a windmill part is provided in the cylindrical main body, and a power generation unit that generates electric power by rotation of the windmill part in the cylindrical main body Further, the water flow portion is provided with a water turbine portion that rotates by receiving the water flowing in the water flow portion, and the wind turbine portion is rotated by using the rotational force of the water wheel portion as a driving force to rotate the wind turbine portion. The wind power generator characterized by the above-mentioned.   2. The wind turbine generator according to claim 1, wherein the water turbine portion is provided at a lower end portion of a movable arm portion provided in the cylindrical main body, and is configured to float and rotate in flowing water of the flowing water portion. Wind power generator.   The wind power generator according to any one of claims 1 and 2, wherein the cylindrical main body is provided at a position above the flowing water portion.   4. The wind turbine generator according to claim 1, wherein the flowing water portion has a U-shaped groove structure in which side wall portions are provided on the left and right sides of the bottom portion, and the cylindrical main body is between the side wall portions of the flowing water portion. The wind power generator is provided at a position above the side wall.   The wind turbine generator according to any one of claims 1 to 4, wherein the wind turbine unit is provided with a wind turbine blade member on a wind turbine rotating shaft, and the water turbine unit is provided with a turbine blade member on a turbine rotating shaft, The wind power generator is characterized in that the air blower member is provided with a blower blade member on the air blow rotating shaft.   6. The wind turbine generator according to claim 5, wherein the blower rotation shaft of the blower unit is connected to the turbine wheel shaft of the water turbine unit via a rotational force transmission mechanism.

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