KR20060070125A - Vice for fixing to 3demension work goods - Google Patents

Abstract

The present invention relates to a solar generator for converting and supplying solar heat into electrical energy, and relates to a solar generator for condensing and supplying solar light into electrical energy. The present invention is a base (B); A parabolic mirror 10 connected to an upper portion of the base B to reflect sunlight; The sun is spaced apart from the upper center of the parabolic mirror 10, and formed with an area smaller than the area of the parabolic mirror 10, and is located at the center of the parabolic mirror 10 in plan view, and is reflected by the parabola mirror 10. A solar cell 20 for condensing light and converting the light into electrical energy; A solar follower for rotating the parabolic mirror 10 about its lower portion as the sun moves; A voltage regulator 40 for adjusting a voltage of electricity generated by the solar cell 20; It characterized in that it comprises a; a capacitor (50) for receiving the electricity is adjusted to the voltage supplied from the voltage regulator (40). Therefore, since the parabolic mirror 10 concentrates and supplies solar light to the solar cell 20, the expensive solar cell 20 can be manufactured and used in a small size, and the area of the solar cell 20 can be used. Compared with this, it is possible to improve the electricity production efficiency.

Solar, electricity, power generation, solar cells, small

Description

Solar generator {VICE FOR FIXING TO 3DEMENSION WORK GOODS}

1 is a perspective view of a solar generator according to an embodiment of the present invention,

Figure 2 is a side view of the solar generator shown in Figure 1,

3 is a perspective view of a solar generator according to another embodiment of the present invention,

4 is a side view of the solar generator shown in FIG.

<Explanation of symbols for the main parts of the drawings>

10: parabolic light 20: solar cell

32: motion bracket 32a: sector gear

34: optical sensor 34a: drive gear

36 controller 40 voltage regulator

50: capacitor 60: parabolic diameter

70: rod solar cell

The present invention relates to a solar generator for converting and supplying solar heat into electrical energy, and relates to a solar generator for condensing sunlight and converting it into electrical energy.

In general, solar generators provide solar cells installed outdoors to condense solar light and convert it into electrical energy. Such solar cells are often installed and used in the form of large plate on a house, a building, or a roadside.

However, such a general solar generator, because the expensive solar cells to be produced in a large size not only takes excessive manufacturing cost, but also has a problem that the electricity production efficiency is very low compared to the size of the solar cell. Therefore, it is virtually impossible for such a general solar generator to become universal.

The present invention was created in order to solve the conventional problems as described above, by concentrating the solar light to focus on the solar cell, it is possible to improve the electricity production efficiency even if the solar cell miniaturization, the solar cell to move the sun The purpose is to provide a solar generator that produces electricity while following up.

The present invention for achieving the above object, the base (B); A parabolic mirror (10) connected to an upper portion of the base (B) and reflecting sunlight to focus on the upper center; It is spaced apart from the upper center of the parabolic mirror 10, is formed with an area smaller than the area of the parabola mirror 10, is located in the center of the planar parabolic mirror 10, and is collected by the parabola mirror (10) A solar cell 20 for converting sunlight into electrical energy; A solar follower for rotating the parabolic mirror 10 about its lower portion as the sun moves; A voltage regulator 40 for adjusting a voltage of electricity generated by the solar cell 20; It characterized in that it comprises a; a capacitor (50) for receiving the electricity is adjusted to the voltage supplied from the voltage regulator (40).

In contrast, the present invention provides a base (B); A parabolic mirror 60 connected to an upper portion of the base B and formed to have a concave arc-shaped cross section to be long and reflect sunlight; It is spaced apart in the upper center of the parabolic diameter 60, is formed long along the axis of the parabolic diameter 60 and formed in a width smaller than the width of the parabolic diameter 60, the central portion of the parabolic diameter 60 on the side Located in the rod-shaped solar cell 70 for converting the sunlight collected by the parabolic mirror 60 into electrical energy; A solar follower for rotating the parabolic mirror 60 about its lower part as the sun moves; A voltage regulator 40 for adjusting a voltage of electricity generated by the rod-type cell 70; It characterized in that it comprises a; a capacitor (50) for storing electricity generated in the rod-shaped cell (70).

Here, the solar follower is, for example, integrally mounted at the lower center of the parabolic mirror 10 or parabolic mirror 60 to be hinged to the base B, and a sector gear 32a on the lower outer peripheral surface. A motion bracket 32 having; The drive gear 34a engages with the sector gear 32a of the motion bracket 32, and rotates the drive gear 34a so that the parabolic mirror 10 or parabolic mirror 10 is rotated about the motion bracket 32. A drive motor M for rotating 60; A plurality of photosensors 34 for sensing the intensity of sunlight; The controller 36 may control the driving of the driving motor M according to the solar intensity detection signal input from the optical sensor 34.

Hereinafter, a solar generator according to the present invention will be described with reference to the accompanying drawings. FIG. 1 is a perspective view of a solar generator according to an embodiment of the present invention, and FIG. 2 is a solar generator shown in FIG. 1. Side view.

As shown in Figure 1, the solar generator according to an embodiment of the present invention, the base (B); A parabolic light 10; A solar cell 20; Solar follower; A voltage regulator 40; Capacitor 50; includes.

Base B is a column as shown. However, the base B may apply other blocks as shown.

The parabolic mirror 10 is connected to the upper portion of the base B, and reflects the sunlight to focus on the upper center. Such a parabolic mirror 10 has a concave shape in the shape of a bowl, as shown. At this time, the parabolic mirror 10 has a curvature specially designed so that the solar light reflected while being focused is concentrated on the solar cell 20 of the upper portion which will be described later.

As illustrated, the solar cell 20 is spaced apart from the upper center of the parabolic mirror 10. Here, the solar cell 20 is preferably installed in the parabolic mirror 10 spaced apart using a rod, as shown. The solar cell 20 is formed with an area smaller than the area of the parabolic mirror 10 and is located at the center of the planar parabolic mirror 10.

At this time, the solar cell 20 is preferably formed in a small square as shown. Alternatively, however, it may be formed in a small disc shape. The area of the solar cell 20 is preferably formed at a ratio of 1 to 6: 4 to 9, compared to the area of the parabolic mirror 10, and is most preferably formed at a ratio of 2 to 8 as shown. It is suitable. The solar cell 20 converts sunlight collected by the parabolic mirror 10 into electrical energy.

The solar follower rotates the parabolic mirror 10 about its lower part as the sun moves. Such a solar follower, as shown in Figure 1, the motion bracket 32; A drive motor M; A plurality of photosensors (S) and; And a control unit 36.

Here, the motion bracket 32 is mounted integrally by welding or bolting to the lower center of the parabolic mirror 10, as shown in an enlarged view in FIG. Such, the motion bracket 32 is coupled to the base (B) by the hinge (H), connecting the parabolic mirror 10 and the base (B). The motion bracket 32 has a sector gear 32a on the lower outer circumferential surface as enlarged.

As shown on the rotation shaft, the drive motor M has the drive gear 34a integrally engaged with the sector gear 32a of the motion bracket 32.

In addition, the photosensor 34 is mounted on the outer circumference of the parabolic mirror 10 at equal intervals, as shown. The plurality of light sensors 34 respectively detect the intensity of sunlight at the mounted position. In addition, the optical sensor 34 applies the detected intensity signal of the sunlight to the controller 36 to be described later.

In addition, the controller 36 compares the solar intensity detection signals respectively input from the plurality of optical sensors 34 to determine the movement position of the sun. Then, the driving motor M is driven in accordance with the movement position of the sun. At this time, the controller 36 drives the driving motor M by using the electricity of the capacitor 50 described above. Such a control unit 36 is preferably configured to operate approximately once every hour.

Meanwhile, the voltage regulator 40 adjusts and supplies the voltage of electricity generated by the solar cell 20 to the set voltage. The capacitor 50 stores electricity supplied from the voltage regulator 40 and then discharges the battery if necessary.

The solar generator according to the embodiment of the present invention configured as described above is reflected while the solar light is collected in the parabolic mirror 10 as shown in FIG. 2. As such, the reflected sunlight is concentrated in the solar cell 20 due to the curvature of the parabolic mirror 10. Thus, the solar cell 20 converts the concentrated sunlight into electricity. At this time, as the solar cell 20 receives the sunlight intensively, the electrons and holes inside are very active. Accordingly, the solar cell 20 generates a large amount of electricity compared to the area.

In this way, the electricity produced is sent to the voltage regulator 40 and adjusted to the set voltage. Then, the voltage regulator 40 sends the adjusted electricity back to the capacitor 50. Therefore, the capacitor 50 accumulates electricity whose voltage is adjusted and discharges it when necessary.

On the other hand, the controller 36 determines that the sun has moved in the direction of the light sensor 34 when the light sensor 34 of any of the plurality of light sensors 34 inputs the largest solar intensity detection signal. do. Then, according to this determination, the driving of the above-described driving motor M is rotated forward or reverse.

Accordingly, the drive gear M of the sector gear 32a of the motion bracket 32 is rotated by the drive gear 34a. Accordingly, the motion bracket 32 rotates the parabola mirror 10 in the direction as shown by the arrow in FIG. 2 while rotating about the hinge H, thereby moving the parabola mirror 10 along the position of the sun. Follow me.

Of course, the solar cell 70 also follows the parabolic mirror 10 along the position of the sun. Thus, as the parabolic mirror 10 and the solar cell 70 follow the position of the sun's movement, the solar cell 70 continues to produce a large amount of electricity.

On the other hand, Figure 3 is a perspective view of a solar generator according to another embodiment of the present invention, Figure 4 is a side view of the solar generator shown in FIG. Such a solar generator of another embodiment is configured in the same manner as the solar generator of the above-described embodiment. However, it is another feature that the parabolic mirror 10 and the solar cell 20 described above are configured by changing the parabolic mirror 60 and the rod-shaped solar cell 70. Therefore, in the description of the solar generator according to another embodiment, the same components as the above-described embodiment will be described with the same reference numerals. The description of the same components and operations will be omitted, and only differences will be described.

 As shown in FIG. 3, the solar generator according to another embodiment is formed to have a concave arc-shaped cross section rather than the above-described parabolic mirror 10 on the base B, and is formed at the same time. A parabolic mirror 60 for reflecting the light and condensing it along the upper center is connected. This parabolic diameter 60 is integrally connected to the base (B) by the motion bracket 32 having a sector gear (32a) integrally mounted at the bottom.

And, as shown in the upper center of the parabolic diameter 60, the rod-shaped cell 70, not the above-described solar cell 20, is installed spaced apart from the parabolic diameter 60. The bar-shaped solar cell 70 is formed along the axis of the parabolic diameter 60 and is formed to have a width smaller than the width of the parabolic diameter 60, and is located at the center of the parabolic diameter 60 on the side surface. At this time, the width of the bar-shaped cell 70 is preferably formed in a ratio of 1 to 6: 4 to 9, compared to the width of the parabolic diameter 60, as shown in the ratio of 2: 8 Is most suitable. The bar-shaped cell 70 collects sunlight reflected from the parabolic mirror 60 and converts the solar light into electrical energy.

This solar generator of another embodiment operates in the same manner as the solar generator of the above-described embodiment. Therefore, the operation of the solar generator according to another embodiment is omitted.

The above embodiment is merely a description of the preferred embodiment of the present invention, the scope of application of the present invention is not limited to such, and can be changed as appropriate within the scope of the same idea. Accordingly, the shape and structure of each component shown in the embodiments of the present invention can be modified and carried out, and such modifications are naturally belonging to the appended claims.

The solar generator according to the present invention as described above, the parabolic mirror or parabolic mirror concentrates the solar light and supplies it to the solar cell, so that the expensive solar cell can be manufactured small and used, and the solar cell area can be used. Compared with this, it is possible to improve the electricity production efficiency.

In addition, since the parabolic mirror or parabolic mirror tracks the movement of the sun together with the solar cell or the bar-shaped cell by the solar follower, the solar cell or the bar-shaped cell can continuously produce a uniform amount of electricity. There is also.

Claims (4)

In the solar generator which converts solar heat into electrical energy and supplies it, Base (B); A parabolic mirror (10) connected to an upper portion of the base (B) and reflecting sunlight to focus on the upper center; It is spaced apart from the upper center of the parabolic mirror 10, is formed with an area smaller than the area of the parabola mirror 10, is located in the center of the planar parabolic mirror 10, and is collected by the parabola mirror (10) A solar cell 20 for converting sunlight into electrical energy; A solar follower for rotating the parabolic mirror 10 about its lower portion as the sun moves; A voltage regulator 40 for adjusting a voltage of electricity generated by the solar cell 20; And a capacitor (50) configured to receive and store electricity whose voltage is adjusted from the voltage regulator (40). The method of claim 1, wherein the solar follower, A motion bracket (32) integrally mounted at the lower center of the parabolic mirror (10) and hinged to the base (B), and having a sector gear (32a) on a lower outer peripheral surface thereof; The drive gear 34a engages with the sector gear 32a of the motion bracket 32, and rotates the drive gear 34a to rotate the parabolic mirror 10 around the motion bracket 32. A drive motor M; A plurality of photosensors 34 for sensing the intensity of sunlight; And a control unit (36) for controlling the driving of the driving motor (M) according to the solar intensity detection signal input from the optical sensor (34). In the solar generator which converts solar heat into electrical energy and supplies it, Base (B); A parabolic mirror (60) connected to an upper portion of the base (B) and formed to have a concave arc-shaped cross section, and being long and reflecting sunlight to focus along the upper center thereof; It is spaced apart in the upper center of the parabolic diameter 60, is formed long along the axis of the parabolic diameter 60 and formed in a width smaller than the width of the parabolic diameter 60, the central portion of the parabolic diameter 60 on the side Located in the rod-shaped solar cell 70 for converting the sunlight collected by the parabolic mirror 60 into electrical energy; A solar follower for rotating the parabolic mirror 60 about its lower part as the sun moves; A voltage regulator 40 for adjusting a voltage of electricity generated by the rod-type cell 70; And a capacitor (50) for storing electricity generated by the rod-type cell (70). The method of claim 3, wherein the solar follower, A motion bracket (32) integrally mounted at the lower center of the parabolic diameter (60) and hinged to the base (B), and having a sector gear (32a) on a lower outer peripheral surface thereof; A drive gear 34a that engages with the sector gear 32a of the motion bracket 32, and rotates the drive gear 34a to rotate the parabolic diameter 60 around the motion bracket 32 A motor M; A plurality of photosensors 34 for sensing the intensity of sunlight; And a control unit (36) for controlling the driving of the driving motor (M) according to the solar intensity detection signal input from the optical sensor (34).

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