JP6800360B1 - Wind power generator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wind power generator in which a problem is unlikely to occur in the continuity of a ground wire in a blade. A tower, a nacelle, a hub 130, at least one blade 140, and a lightning arrester 150 including a receptor 151 and a ground wire 152 provided on the blade 140 are provided, and the ground wire 152 includes a blade 140. It is provided with a main ground wire 154 and a sub ground wire 155 laid inside, and the gap spacing dA of the discharge gap between the main ground wire 154 and the ground main wire 153 is the gap spacing dB of the discharge gap between the sub ground wire 155 and the ground main wire 153. Narrower than the wind generator 100. [Selection diagram] Fig. 3

Description

The present invention relates to a wind power generator.

The development of solar power generation and wind power generation is being promoted toward the main power source of renewable energy. In particular, wind power generation is expected to accelerate development as the development area shifts from land to offshore. Wind power generation at sea is operated in a harsh natural environment and is difficult to access. Therefore, it is required to operate and maintain the wind power generator reasonably and efficiently.

Generally, a blade made of FRP (fiber reinforced plastic) of a wind power generator is provided with a receptor at the tip and a ground wire inside as a lightning arrester in order to suppress damage due to a lightning strike. Since the blade is the part of the wind power generator where lightning strikes most easily, the failure of the ground wire continuity tends to occur inside the blade.
Patent Document 1 discloses a wind power generator in which a pull-down lead wire (earth wire) and a measurement cable for measuring the electric resistance of the pull-down lead wire are provided in the blade.

Japanese Unexamined Patent Publication No. 2012-42473

However, in a wind power generator as in Patent Document 1, when a problem occurs in the continuity of the ground wire in the blade due to a lightning strike or the like, it is necessary to stop the operation in order to repair the ground wire, which is particularly stable at sea. Difficult to operate.

An object of the present invention is to provide a wind power generator in which the continuity of the ground wire in the blade is less likely to be defective.

The present invention has the following aspects.
[1] A tower, a nacelle rotatably provided on the upper part of the tower around the central axis of the tower, and a hub rotatably provided in front of the nacelle around an axis orthogonal to the central axis. The hub comprises at least one blade and a lightning arrester, the lightning arrester comprising a receptor provided on the blade and a ground wire connecting the receptor and the ground, said ground. The main ground wire connected to the ground and laid inside the tower, the nacelle and the hub, and the main ground wire and the sub-ground wire connected to the receptor and laid inside the blade. The electric resistance of the path from the receptor to the ground main line via the main ground wire is smaller than the electrical resistance of the path from the receptor to the ground main line via the sub ground wire. Generator.
[2] Discharge gaps are provided between the terminal of the main ground wire and the terminal of the ground main wire, and between the terminal of the sub ground wire and the terminal of the ground main wire, and the main ground wire has a discharge gap. The wind generator according to [1], wherein the gap between the terminal and the terminal of the ground main line is narrower than the gap between the terminal of the sub-ground wire and the terminal of the ground main line.

According to the present invention, it is possible to provide a wind power generator in which the continuity of the ground wire in the blade is less likely to be defective.

It is sectional drawing which showed an example of the wind power generator of this invention. It is an enlarged cross-sectional view of the vicinity of the blade of the wind power generator of FIG. It is the schematic which showed the wiring of the earth wire near the blade of the wind power generator of FIG.

Hereinafter, an example of the wind power generator of the present invention will be described with reference to the drawings. It should be noted that the dimensions and the like of the figures illustrated in the following description are examples, and the present invention is not necessarily limited to them, and the present invention can be appropriately modified without changing the gist thereof. ..

As shown in FIG. 1, the wind power generator 100 of the present embodiment includes a tower 110, a nacelle 120, a hub 130, at least one blade 140, and a lightning arrester 150.

The tower 110 is erected on land or offshore. The nacelle 120 is rotatably provided above the tower 110 around the central axis O1 of the tower 110. The hub 130 is rotatably provided in front of the nacelle 120 around an axis orthogonal to the central axis O1. The hub 130 is provided with at least one blade 140. The central axis O1 of the tower 110 coincides with the vertical direction.

The wind power generator 100 includes a generator (not shown) configured inside the hub 130 and the nacelle 120 to generate electricity using the rotational energy of the blades 140 and the hub 130. The generator is not particularly limited, and a known generator can be adopted. A hydraulic transmission may be used as the generator, or a gear type speed increaser may be used.

In the wind power generator 100, by rotating the nacelle 120 at the upper part of the tower 110, the front hub 130 provided with the blade 140 can be directed upwind. When the blade 140 receives the wind, the hub 130 rotates together with the blade 140, and the rotational energy generates electricity in the generator.

The shape and dimensions of the blade 140 are not particularly limited and can be set as appropriate.
The number of blades 140 attached to the hub 130 is not particularly limited, and may be, for example, three. When a plurality of blades 140 are attached to the hub 130, it is preferable that the plurality of blades 140 are radially attached at equal angular intervals when the hub 130 is viewed from the front.

As shown in FIGS. 1 to 3, the lightning arrester 150 of this example includes a receptor 151 provided at the tip of each blade 140, and a ground wire 152 connecting the receptor 151 and the ground.
The ground wire 152 includes a ground main wire 153 laid inside the tower 110, the nacelle 120, and the hub 130, and a main ground wire 154 and a sub ground wire 155 laid inside the blade 140.

The ground main line 153 is connected to the ground by being connected to the ground rod 156 at the lower part of the tower 110. A plate-shaped terminal 153a is provided on the side of the ground main line 153 opposite to the ground rod 156. The terminal 153a of the ground main line 153 is arranged near the base of each blade 140 in the hub 130.

The main ground wire 154 and the sub ground wire 155 are laid on each blade 140, respectively, and are connected to a receptor 151 provided at the tip of each blade 140.
The terminal 154a on the opposite side of the main ground wire 154 from the receptor 151 is provided so as to be separated from the terminal 153a of the ground main wire 153 by a predetermined distance. That is, a discharge gap is provided between the terminal 154a of the main ground wire 154 and the terminal 153a of the ground main wire 153. Similarly, the terminal 155a on the side opposite to the receptor 151 of the secondary ground wire 155 is provided so as to be separated from the terminal 153a of the ground main wire 153 by a predetermined distance. That is, a discharge gap is provided between the terminal 155a of the secondary ground wire 155 and the terminal 153a of the ground main wire 153. As described above, the lightning arrester 150 in the present embodiment is a lightning arrester with a gap including a main ground wire 154 and a sub ground wire 155 provided with a discharge gap between the ground main wire 153 and the ground main wire 153 in the blade 140.

Gap distance _{d A} terminal 153a of the terminal 154a and ground main line 153 of the main ground wire 154 is narrower than the gap distance _{d B} terminal 153a of the terminal 155a and ground main line 153 of the sub-ground line 155. As a result, the electrical resistance of the path from the receptor 151 to the ground main line 153 via the main ground wire 154 becomes smaller than the electrical resistance of the path leading from the receptor 151 to the ground main line 153 via the secondary ground wire 155. There is.

d _A that it is smaller than _{d B,} when lightning current flows unevenly in the main ground line 154 from the receptor 151, discharge occurs in the discharge gap between the terminal 153a of the terminal 154a and ground main line 153 of the main ground wire 154 , Current is released to ground through the ground main line 153. Further, in a state where the continuity of the main ground wire 154 is defective, a current flows from the receptor 151 to the sub ground wire 155 at the time of a lightning strike, and the discharge gap between the terminal 155a of the sub ground wire 155 and the terminal 153a of the ground main wire 153 A discharge occurs and current is released to ground through the ground main line 153.

In the wind power generator 100 of the present embodiment, by providing the main ground wire 154 and the sub ground wire 155 in the blade 140 in this way, the sub ground wire 155 functions as a backup of the main ground wire 154. Therefore, even if there is a problem in the continuity of the main ground wire 154, the continuity of the ground wire 152 from the receptor 151 to the ground is ensured by the sub ground wire 155.

Further, when the ground fault current at the time of a lightning strike is diverted and a large current flows through each of the main ground wire 154 and the sub ground wire 155, a large repulsive force acts between the main ground wire 154 and the sub ground wire 155. When a huge repulsive force is applied, the main ground wire 154 and the sub ground wire 155 cannot be supported by the normally used support metal fittings, so that the main ground wire 154 and the sub ground wire 155 are broken or damaged, resulting in poor continuity. It may occur. However, by d _A is smaller than d _B, since the current of lightning strikes flows biased to main ground line 154 from the receptor 151, broken or the main ground line 154 and the sub-ground line 155 by a repulsive force on the blade 140 within broken Is less likely to occur, and problems with continuity can be reduced.

Generally, the blade 140 rotates around the blade axis to change the angle, and the amount of wind received can be adjusted. And the terminal 153a of the ground main 153, the main ground wire 154, and the sub-ground line 155, the blade 140 is provided so that the positional relationship is such that the _{d A} and _{d B} be rotated about the blade axis unchanged. Specifically, for example, the main ground wire 154 and the sub ground wire 155 are laid in a straight line in parallel in the blade 140, and the ground main wire 153 is laid with respect to the length direction of the main ground wire 154 and the sub ground wire 155. Make sure that the surface of terminal 153a is vertical.

d _A and _{d B,} when the terminal 155a discharge sub ground line 155 does not occur even happening discharged from the terminal 154a of the main ground wire 154 during lightning, faulty conduction of the main ground wire 154 occurs lightning Occasionally, it is set so that discharge occurs from the terminal 155a of the secondary ground wire 155.

The conductive material constituting the receptor 151 and the ground wire 152 is not particularly limited, and examples thereof include aluminum, brass, stainless steel, alloys containing these, carbon, and the like. The conductive material constituting the receptor 151 and the ground wire 152 may be one type or two or more types.

The electrical resistances of the main ground wire 154 and the sub ground wire 155 may be the same or different. For example, the conductive material constituting the main ground wire 154 and the conductive material constituting the sub ground wire 155 may be the same or different. The cross-sectional areas of the main ground wire 154 and the sub ground wire 155 perpendicular to the length direction may be the same or different.

The lightning arrester 150 of this example is provided in the wiring 157 and the wiring 157 that connect the main ground wire 154 and the sub ground wire 155 so as to bridge the vicinity of the base of the blade 140 in the main ground wire 154 and the sub ground wire 155. It further includes a switch 158 and a detector 159 provided on the wiring 157. As a result, the lightning arrester 150 can remotely control the switch 158 to check the continuity of the main ground wire 154 and the sub ground wire 155.

The lightning arrester 150 may not include the wiring 157, the switch 158, and the detector 159. If the arrester is equipped with a main ground wire and a secondary ground wire, for example, by contacting the tester terminals with the main ground wire and the sub ground wire near the base of the blade, the main ground wire and the main ground wire inside the blade can be reached from the inside of the hub. You can check the continuity of the secondary ground wire.

As described above, in the wind power generator 100, since the lightning arrester 150 includes the main ground wire 154 and the sub ground wire 155 in the blade 140, the sub ground wire 155 functions as a backup for the main ground wire 154. In addition, by d _A is smaller than d _B, repulsion hardly occurs between the main ground wire 154 during lightning sub ground line 155, defective conduction hardly occurs. As described above, the wind power generator 100 can easily maintain the continuity of the main ground wire 154 and the sub ground wire 155 in the blade 140 in a stable manner, and can be stably operated even at sea.

The wind power generator of the present invention is not limited to the wind power generator 100 described above. For example, the wind power generator of the present invention is not limited to the one provided with a lightning arrester with a gap, and may be provided with a gapless lightning arrester. In the wind power generator of the present invention, the number of secondary ground wires laid on one blade is not limited to one, and may be two or more.
In addition, it is possible to replace the components in the embodiment with well-known components as appropriate without departing from the spirit of the present invention, and the above-mentioned modifications may be appropriately combined.

100, 100A ... Wind power generator, 110 ... Tower, 120 ... Nacelle, 130 ... Hub, 140 ... Blade, 150, 150A ... Lightning arrester, 151 ... Receptor, 152 ... Ground wire, 153 ... Earth main line, 154 ... Main ground wire, 155 ... Secondary ground wire, O1 ... Central axis.

Claims (1)

A tower, a nacelle rotatably provided on the upper part of the tower around the central axis of the tower, a hub rotatably provided in front of the nacelle around an axis orthogonal to the central axis, and the hub. With at least one blade and a lightning arrester provided in
The lightning arrester includes a receptor provided on the blade and a ground wire connecting the receptor and the ground.
The ground wire is connected to the ground and is laid inside the tower, the nacelle and the hub, and the main ground wire and the sub ground wire which are connected to the receptor and laid in the blade. And with
Discharge gaps are provided between the terminal of the main ground wire and the terminal of the ground main wire, and between the terminal of the sub ground wire and the terminal of the ground main wire, and the terminal of the main ground wire and the terminal of the ground wire are provided. The gap between the terminals of the main ground wire is narrower than the gap between the terminal of the secondary ground wire and the terminal of the main ground wire.
A wind power generator in which the electrical resistance of the path from the receptor to the ground main line via the main ground wire is smaller than the electrical resistance of the path leading from the receptor to the ground main line via the sub ground wire.

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