JP7403267B2 - wind power generator - Google Patents

Description

The present invention relates to a wind power generation device that is installed, for example, in an existing abandoned tunnel and generates wind power.

BACKGROUND ART Conventionally, road tunnels, railway tunnels, and the like have been installed as existing tunnels, and some of these tunnels have a wind turbine of a wind power generation device installed inside the tunnel. In addition, there are railway tunnels in Japan that have been abandoned and road tunnels that are no longer in use due to the construction of bypass tunnels. These tunnels are often left unsealed because it would be costly to construct them.
For example, some road tunnels that pass through mountain passes have a temperature difference of more than 10 degrees between the sunny opening on one side and the shaded opening on the other side (for example, Miyako City and Iwaizumi Town). Oshikado Tunnel). Due to this temperature difference, some tunnels have openings at both ends that are naturally ventilated, while others allow sea breeze from the coast to blow in. By installing a windmill and a generator inside the tunnel, which serves as a passage for the wind, it is possible to provide lighting inside the tunnel, and the tunnel can be used for storage such as a wine cellar, storage for materials, etc.

For example, in the tunnel installation type wind power generation device described in Patent Document 1, a vehicle runs in a roadway space of a road tunnel, and a wind turbine power generation device is installed in the space above the vehicle. The wind turbine of the wind power generation device is rotated in response to the wind pressure generated by the running of the vehicle, thereby generating wind power and providing electric power to lighting devices and the like in the tunnel.

Japanese Unexamined Patent Publication No. 56-34979

However, since the tunnel-installed wind power generation device described in Cited Document 1 is a road tunnel, a small power generation device is used in an extra space near the ceiling of the tunnel so as not to interfere with passing vehicles. Therefore, the power generation capacity of the wind power generator was small. Furthermore, if part of the tunnel wall were to collapse due to an earthquake or the like, there was a risk of damaging the wind power generator.

The present invention was made in view of these problems, and provides a wind power generation device that can safely and efficiently generate power using various tunnels such as abandoned railway tunnels and abandoned road tunnels. The purpose is to provide

The wind power generation device according to the present invention includes a segment ring installed in a tunnel, a wind turbine supported within the segment ring via a support member, and a generator that generates electricity based on the rotation of the wind turbine. Features.
The wind power generation device according to the present invention can rotate the wind turbine by the wind passing through the tunnel and generate electricity with the generator, and even if the tunnel wall, rock, etc. collapse, the wind power generation device can be protected by the segment ring.

Preferably, the wind turbine includes a nacelle that rotatably supports the blades, and the nacelle is connected to the segment ring by a support member.
The wind power generator can be firmly fixed because the nacelle is attached to the segment ring by the support member.

Further, the support member may be attached to an injection hole formed in a segment of the segment ring.
When the segment ring is formed of an RC segment or the like, the wind turbine can be easily and firmly fixed by attaching a support member to the injection hole of the segment for filling the gap between the segment ring and the tunnel.

The wind power generation device according to the present invention can generate electricity using a generator by rotating a windmill using wind passing through a tunnel. In addition, by arranging segment rings inside the tunnel, it is possible to maintain the circular shape and protect the windmill, so even if a part of the abandoned tunnel collapses, the windmill will not be damaged or get in the way of rotation. .
Moreover, since the wind turbine is fixed to the segment ring via the support member, it can be firmly fixed. Additionally, since it is an abandoned tunnel, there will be no problem even if the inside of the tunnel is blocked by windmills.

FIG. 2 is an axially orthogonal cross-sectional view of a segment ring installed on the inner surface of a tunnel according to an embodiment of the present invention. FIG. 3 is an axial cross-sectional view showing a wind turbine installed inside a segment ring. 3 is a cross-sectional view taken along line AA of the wind turbine shown in FIG. 2. FIG. 3 is a sectional view taken along line BB of the wind turbine shown in FIG. 2. FIG. (a) is a perspective view of the segment, (b) is a horizontal cross-sectional view of the attachment part of the support steel member with the pin shaft attached to the injection hole in the direction of line CC in (a), and (c) is the same figure ( It is a side sectional view of the attachment part of the support steel material shown in b), seen from a direction different from 90 degrees.

DESCRIPTION OF THE PREFERRED EMBODIMENTS A wind power generator 1 according to an embodiment of the present invention will be described below with reference to the accompanying drawings.
FIG. 1 is a sectional view of a tunnel 2 in which a wind power generation device 1 according to an embodiment of the present invention is installed. This tunnel 2 is an abandoned tunnel that is not in use. Usually, the inner surface of the tunnel 2 is not formed in a perfect circle, but the upper and side walls 3 are formed in a substantially circular shape, and the bottom wall 4 is formed in an arc shape with a radius larger than the wall surface 3, and is approximately rice ball-shaped. be.
Therefore, in the installation area of the wind power generation device 1 in the tunnel 2 shown in FIGS. 1 and 2, the bottom wall 4 and the bedrock below it are excavated using a rock drill or the like. Then, the excavated bottom part 5 is filled with an injection agent 6 to form the bottom part 5 into a circular shape that is an extension of the wall surface 3.

Next, segments 8 are constructed inside the wall surface 3 and bottom portion 5 of the tunnel 2 to form a segment ring 9. The segment ring 9 is formed into a ring shape by connecting, for example, four segments 8, and is formed in two rows in the axial direction of the tunnel 2. This part becomes the installation area of the wind power generator 1. It is preferable that the two rows of segment rings 9 be formed in a staggered pattern, but they may also be formed in a zigzag pattern. The segment 8 is, for example, an RC segment, but may also be a steel segment or the like.
As shown in FIG. 5(a), an injection hole 8a is formed in the center of the segment 8, passing through the inside and outside. The gap between the segment ring 9 and the wall surface 3 and bottom 5 of the tunnel 2 is filled with a filler such as concrete or mortar through each injection hole 8a.

Next, the wind power generation device 1 installed in the segment ring 9 will be explained.
The wind turbine 10 of the wind power generator 1 is installed in the segment ring 9, and includes, for example, three blades 11 and a nacelle 12 that rotatably supports the blades 11. A generator 13 that generates electricity by rotating the blades 11 is installed inside the nacelle 12 . As shown in FIGS. 3 and 4, the nacelle 12 is installed near the central axis of the segment ring 9, and the nacelle 12 is supported by each segment 8 of the segment ring 9 by a plurality of, for example, four, supporting steel members 14. has been done. 3 and 4, the nacelle 12 is received by the lower two of the four supporting steel members 14, and is suspended and fixed by the upper two supporting steel members 14. Furthermore, four supporting steel members 14 are connected to the front side and the rear side of the nacelle 12, respectively.

Next, an example of the connection structure of the supporting steel material 14 will be explained with reference to FIG.
In FIGS. 5A and 5B, a female threaded portion 8b is formed in the injection hole 8a provided at the center of the segment 8, and a male threaded portion 16a of the pin shaft 16 is screwed into this. A groove 14a is formed at one end of the support steel 14, and with the head of the pin shaft 16 fitted into the groove 14a, the bolt 17 is inserted between the end of the support steel 14 having the groove 14a and the pin shaft. The screw holes formed in the heads of the screws 16 are passed through the screw holes, and the nuts 18 are tightened and fixed.
The other end of the supporting steel member 14 is fixed to the nacelle 12 by welding or the like, but in the same way as the one end, the pin shaft 16 screwed to the nacelle 12 is fitted into the groove 14a and fixed with bolts 17 and nuts 18. You can.

This structure makes it possible to adjust the angle of the support steel 14 with respect to the pin shaft 16 when attaching the nacelle 12 of the wind turbine 10 (see FIG. 5(c)). As a result, the four supporting steel members 14 are fixed to the segment ring 9 at approximately 90 degree intervals on the blade 11 side (referred to as the front side) of the nacelle 12, and the four supporting steel members 14 are also fixed at approximately 90 degree intervals on the rear side of the nacelle 12. It can be fixed to the segment ring 9 at degree intervals (see FIGS. 3 and 4). In addition, in order to ensure the holding strength of the nacelle 12, the support steel member 14 on the rear side may be arranged at an angle.
In addition, when a steel segment is adopted as the segment 8 instead of the RC segment, one end side of the supporting steel material 14 may be fixed to the inner circumferential surface of the segment 8 by welding or the like.

The wind power generation device 1 in the tunnel 2 according to this embodiment has the above-mentioned configuration, and how to use it will be explained next.
Wind blows through the tunnel 2 due to the temperature difference between the openings at both ends, sea breeze from the coast, natural wind, etc. The wind passing through the tunnel 2 causes the blades 11 of the wind turbine 10 of the wind power generator 1 to rotate, and in response to this rotation, a generator 13 in the nacelle 12 generates electricity. The electric power generated by the generator 13 is used, for example, for lighting inside the tunnel 2, power source for equipment, etc. The temperature inside the tunnel 2 is relatively low and temperature control is easy, so when using the inside of the tunnel 2 as a storage area for wine, aging or storage of foods such as cheese and ham, or storage of materials, etc. There is no need to draw in an external power source, and the wind passing through the tunnel 2 can be effectively used.

In addition, when constructing the segment ring 9 and installing the wind turbine 10, instead of designing each case according to the inner dimensions of the local tunnel 2, we use standard products such as segments with inner diameters of 3 m, 3.5 m, 4 m, and 4.5 m. It is advisable to prepare segments 8 such as RC segments, wind turbines 10, etc. for constructing the ring 9. In these cases, even if a gap occurs between the tunnel 2 and the segment ring 9, the wind power generator 1 can be protected by filling the gap with a filler or the like through the injection hole 8a. Alternatively, the gap may be left as a space without being filled with filler.

As described above, according to the wind power generation device 1 in the tunnel 2 according to the present embodiment, by installing the wind power generation device 1 in the tunnel 2, the wind blowing through the tunnel 2 is used to generate lights, other power sources, etc. in the tunnel 2. available for use. Therefore, there is no need to draw in an external power source, and the inside of the abandoned tunnel can be effectively used as a storage area or storage area for various materials. Furthermore, it is possible to obtain more electric power than conventional wind power generators.

Moreover, by arranging the segment ring 9 inside the tunnel 2, the circular shape can be maintained and the windmill 10 can be protected, so even if a part of the abandoned tunnel collapses, it will not interfere with the rotation of the windmill 10. Moreover, since it is an abandoned tunnel, there is no problem even if the inside of the tunnel 2 is blocked by a windmill.
When the segment ring 9 is formed of an RC segment or the like, the support steel 14 can be attached to the injection hole 8a of the segment 8 via the pin shaft 16 to fill the gap between the segment ring 9 and the tunnel 2 with a filler. The windmill 10 can be easily and firmly fixed.
In addition, the wind power generator 1 can be firmly fixed because the nacelle 12 is connected to the segment ring 9 by the supporting steel 14.

Although the wind power generation device 1 according to the embodiment of the present invention has been described in detail above, the present invention is not limited to the above-described embodiment, and appropriate changes and substitutions can be made without departing from the spirit of the present invention. Both are possible and are included in the present invention. Modifications of the present invention will be described below, but the same or similar parts and members as in the above-described embodiment will be designated by the same reference numerals, and the description thereof will be omitted.

For example, in the wind power generation device 1 according to the embodiment described above, the nacelle 12 of the wind turbine 10 is fixed within the two rows of segment rings 9 using two sets of four supporting steel members 14. The number of steel materials 14 and the number of sets can be selected as appropriate. In the present invention, the support steel material 14 is included in the support member. Further, although the generator 13 is installed inside the nacelle 12, it can be installed at an appropriate position such as inside the segment ring 9 outside the nacelle or outside the tunnel 2.
Furthermore, in the above-described embodiment, the wind turbine 10 is installed near the central axis of the segment ring 9, but by adjusting the length of the supporting steel material 14 that supports the nacelle 12, the installation position and height of the wind turbine 10 can be adjusted to the maximum of the wind force. Can be adjusted to a strong position as appropriate.
Further, the number of segment rings 9 on which the wind power generation device 1 is installed is not limited to two rows, but can be set to any number of rows.

1 Wind power generator 2 Tunnel 3 Wall surface 4 Bottom wall 5 Bottom part 8 Segment 8a Injection hole 9 Segment ring 10 Wind turbine 11 Blade 12 Nacelle 13 Generator 14 Support steel material

Claims (3)

A segment ring installed inside the tunnel,
a wind turbine supported within the segment ring via a support member;
a generator that generates electricity based on the rotation of the windmill;
Equipped with
The wind turbine includes a nacelle that rotatably supports blades,
the nacelle is connected to the segment ring by the support member;
The angle of the support member with respect to the segment of the segment ring is adjustable at an end portion connected to the segment ring.
A wind power generation device characterized by : The wind power generator according to claim 1, wherein the support member is attached to an injection hole formed in a segment of the segment ring. The support member includes a pin shaft attached to the injection hole;
a supporting steel whose angle relative to the pin axis is adjustable;
The wind power generation device according to claim 2, comprising:.

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