KR20150129983A - Wind powered streetlight - Google Patents

Abstract

The present invention relates to a street light and, more specifically, to a street light using wind power generation. The present invention comprises: a column part (110); a wind power generator (120) having a vertical shaft type wing part (140) installed at the upper end of the column part (110); supports (150a, 150b) extended outwards from the column part (110); and light emitting units (160a, 160b) installed in the supports and receiving power from the wind power generator, wherein the wing part has a rotational shaft (141) and a wing (143) coupled to the rotational shaft (141). The wing has band-shaped two blades (144) forming a single closed loop with an inner side and an outer side, and each of the two blades has: two extension parts (145, 146) facing each other across the rotational shaft (141); a first connection part (147) connecting the upper ends of the two extension parts to each other and fixated at the rotational shaft; and a second connection part (148) connecting the lower ends of the two extension parts to each other and fixated at the rotational shaft.

Description

WIND POWERED STREETLIGHT

The present invention relates to a streetlight, and more particularly, to a streetlight using wind power.

Street light is an illumination facility installed along the street for the safety and security of the street traffic. It is composed of a base structure firmly embedded in the ground, a pillar fixed at the bottom to the base structure and extending upward, A light emitting portion provided at an end of the support, and an electric wire for supplying electric power to the light emitting portion. The electric wire is passed through neighboring street lamps in turn to supply electric power to the light emitting portion. That is, it is required to connect the electric wires to the electric wires when installing the electric wires because the electric wires pass through the ground and the street lamps. In recent years, a street light using solar light has been developed and installed to solve such installation difficulties and to save energy. However, when sunlight is used, it is difficult to secure sufficient electric power when the amount of sunshine is insufficient.

An object of the present invention is to provide a streetlight using wind power. Another object of the present invention is to provide a streetlight using a wind power generator having a wing of a simple structure.

In order to achieve the above object, according to an aspect of the present invention,

(110); A wind turbine 120 having a vertical axis type wing 140 installed at an upper end of the support portion 110; Support rods (150a, 150b) extending outwardly from the support portion (110); And a light emitting unit (160a, 160b) installed on the support and supplied with electric power from the wind power generator. The wing unit includes a rotation shaft (141) and a wing (143) coupled to the rotation shaft (141) , Said blades having two band-shaped blades (144) forming a single closed curve having an inner surface and an outer surface, each of said blades having two extensions (145, 146), a first connecting portion (147) connecting the upper ends of the two extension portions and fixed to the rotating shaft, and a second connecting portion (148) connecting the lower ends of the two extending portions and fixed to the rotating shaft Development street lights are provided.

The two extensions 145 and 146 may be in the form of a flat rod having a constant width and extending parallel to the rotary shaft 141.

The two blades may be arranged to have a phase difference of 90 degrees along the circumferential direction of the rotating shaft.

According to the present invention, all of the objects of the present invention described above can be achieved. Specifically, since a street lamp is provided that operates by receiving electric power from a wind power generator having a vertical axis type wing coupled to the upper end of the main land portion, it is easy to install a street lamp, and a blade with two wing portions is coupled to the rotary shaft Because of its shape, its structure is simple.

1 is a perspective view illustrating a wind power street lamp according to an embodiment of the present invention.
2 is a side view of the wind power streetlight shown in Fig.
3 is a perspective view showing another embodiment of the wing shown in Fig.

Hereinafter, the configuration and operation of a preferred embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a perspective view of a wind power street lamp according to an embodiment of the present invention, and FIG. 2 is a side view of a wind power street lamp shown in FIG. 1 and 2, a wind power street light 100 according to an embodiment of the present invention includes a support 110, a wind power generator 120 coupled to an upper end of the support 110, Two support rods 150a and 150b extending outward from the support frame 110 and light emitting portions 160a and 160b provided at the ends of the two support rods 150a and 150b.

The support portion 110 extends upwardly along the vertical direction from the ground. Although not shown, a passageway is formed in the support portion 110 to allow electric wires to pass therethrough, and the lower end of the support portion 110 is firmly fixed to the foundation structure embedded in the ground.

The wind power generator 120 is coupled to the upper end of the support 110 to convert wind into electrical energy. The wind power generator 120 includes a power generation unit 130 that generates electricity by rotation and a wing unit 140 that rotates by the wind to provide a necessary rotational force to the power generation unit 130.

The power generation unit 130 includes a generator 131 and a case 135 for accommodating the generator 131 therein.

The construction of the generator 131 is the same as that of a conventional generator, so a detailed description thereof will be omitted. The generator 131 receives the rotational force from the wing portion 140 and supplies the required power to the light emitting portion 160. The generator 131 is connected to the light emitting unit 160 through a wire (not shown).

The case 135 receives the generator 131 therein and is fixed to the upper end of the support portion 110.

The wing portion 140 has a rotary shaft 141 and a wing 143 coupled to the rotary shaft 141 in a vertical axis manner.

The rotating shaft 141 extends long along a rotational axis A extending linearly from the power generating unit 130 and rotates around the rotational axis A. The rotation of the rotating shaft 141 is transmitted to a rotor (not shown) of the generator 131. As shown in Fig. 1, when the case 135 is fixed to the upper end of the supporting portion 110, the rotating shaft 141 is arranged to extend along the vertical direction.

The wing (143) has two blades (144) coupled to the rotating shaft (141). Each of the two blades 144 is in the form of a band forming a single closed curve having an inwardly facing inner surface 144a and an outwardly facing outer surface 144b. The blade 144 has a first extending portion 145 and a second extending portion 146 facing each other and a first connecting portion 147 and a second connecting portion 148 facing each other. That is, the blade 144 forms a single closed curve with the first extension 145, the first connection 147, the second extension 146, and the second connection 148 in this order.

Each of the two extensions 145 and 146 has a flat bar shape and has a constant width and extends in parallel with the rotary shaft 141. The two extensions 145 and 146 have the same shape and size and face each other with the rotary shaft 141 therebetween. Among the ends 145a and 145b of the first extension portion 145 and the ends 145a and 145b of the second extension portion 146 that are located remotely from the power generation unit 130 and between the ends 146a and 146b of the second extension portion 146, And the distal end 146a, which is located remotely, is connected by the first connection part 147. [ Among the ends 145a and 145b of the first extension 145 and the ends 145b and 146b of the second extension 146 that are located close to the power generation unit 130, Is connected by the second connection portion 148. The second connection portion 148 is connected to the end 146b.

The first connection portion 147 is elongated in both radial directions around the rotation axis A as a center. The longitudinal center portion 147a of the first connecting portion 147 is fixed to the rotating shaft 141. [ At both ends in the longitudinal direction of the first connection portion 147, the ends 145a and 145b of the first extension portion 145 and the ends 145a and 145 of the second extension portion 146, which are located remotely from the power generation unit 130, And the ends 146a of the ends 146a and 146b, which are located remotely from the power generation unit 130, are connected. The first connecting portion 147 is inclined gently in a direction in which the first connecting portion 147 is closer to the power generating unit 130 as seen from the longitudinal center portion 147a coupled with the rotating shaft 141 toward both ends. The connecting portion of the first connecting portion 147 and the two extending portions 145 and 146 forms a round.

The second connection portion 148 extends in the radial direction on both sides of the rotation axis A and faces the first connection portion 147. The second connection portion 148 is located adjacent to the power generation unit 130 as compared to the first connection portion 147. The longitudinal center portion 148a of the second connecting portion 148 is fixed to the rotating shaft 141. [ The ends 145b and 145a of the first and second connecting portions 148 and 145 are positioned at both ends of the second connecting portion 148 in the longitudinal direction of the second connecting portion 148, And an end 146b located near the power generation unit 130 among the ends 146a and 146b is connected. The second connection portion 148 is inclined gently in a direction away from the power generation unit 130 (in the upward direction in the figure) toward the both ends from the longitudinal center portion 148a coupled with the rotary shaft 141. [ The connecting portion of the second connecting portion 148 and the two extending portions 145 and 146 forms a round.

The two blades 144 are arranged so as to have a phase difference of 90 degrees along the circumferential direction of the rotational axis A to be fixed to the rotational shaft 141. That is, the first connecting portion 147 of the blade 144 intersects the first connecting portion 147 of the other blade 144 in a + form.

The two supports 150a and 150b are coupled to the support 110 at a relatively high height. In this embodiment, one of the two supports 150a and 150b positioned relatively higher is used as the first support 150a, and the other one of the two supports 150b lower than the first support 150a is used as the second support 150b. The two supports 150a and 150b extend in opposite directions from each other in the radial direction from the support 110. [ The first support 150a of the two supports 150a and 150b extends longer in the radial direction. A first light emitting portion 160a is provided at the end of the first support 150a and a second light emitting portion 160b is provided at the end of the second support 150b.

The two light emitting units 160a and 160b include a first light emitting unit 160a provided at the end of the first support 150a and a second light emitting unit 160b installed at the end of the second support 150b. The two light emitting units 160a and 160b are LED lamps, and are supplied with power from the wind power generator 120. In the present embodiment, it is explained that the first light emitting portion 160a reveals the driveway and the second light emitting portion 160b illuminates the delivery.

Fig. 3 shows another embodiment of the wing shown in Fig. Referring to FIG. 3, the wing portion 240 has a rotary shaft 241 and a wing 243 coupled to the rotary shaft 241, in a vertical axis manner. Since the wings 243 are made of a structure used in a conventional twist-savonius structure, a detailed description thereof will be omitted.

Although the present invention has been described with reference to the above embodiments, the present invention is not limited thereto. It will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims.

100: wind power streetlight 110:
120: wind turbine generator 130: power generator unit
131: generator 135: case
140: wing portion 141: rotating shaft
143: blade 144: blade
145: first extension part 146: second extension part
147: first connection part 148: second connection part
150a: first support frame 150b: second support frame
160a: first light emitting portion 160b: second light emitting portion

Claims (3)

(110);
A wind turbine 120 having a vertical axis type wing 140 installed at the upper end of the support portion 110;
Support rods (150a, 150b) extending outwardly from the support portion (110); And
And a light emitting unit (160a, 160b) installed on the support and supplied with power from the wind power generator,
The wing portion includes a rotating shaft 141 and a wing 143 coupled to the rotating shaft 141,
The blades have two strip-shaped blades 144 forming a single closed curve having an inner surface and an outer surface,
Each of the two blades includes two extending portions 145 and 146 opposed to each other with the rotating shaft 141 interposed therebetween, a first connecting portion 147 connecting the upper ends of the two extending portions and fixed to the rotating shaft, And a second connection portion (148) connecting the lower ends of the two extension portions and fixed to the rotation shaft. The method according to claim 1,
Characterized in that the two extensions (145, 146) are of a flat bar shape having a constant width and extending parallel to the rotating shaft (141). The method according to claim 1,
Wherein the two blades are arranged to have a phase difference of 90 degrees along the circumferential direction of the rotating shaft.

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