KR101948880B1 - Generator using solar and solar heat - Google Patents

Abstract

The present invention relates to a generator using solar light and solar heat, and more specifically, to a generator using solar light and solar heat which can generate power of high efficiency by tracking a position of the sun changed in real time and adjusting horizontal and vertical angles of parabola mirror and perform solar generation of high efficiency even in a small installation area by installing a solar heat generation unit with a multi-layer structure.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a generator using solar and solar heat,

The present invention relates to a generator using sunlight and solar heat, and more particularly, it relates to a generator capable of generating high-efficiency electric power by controlling the horizontal angle and vertical angle of the parabolic arc by tracking the position of the sun changing in real time, The present invention relates to a generator using sunlight and solar heat that can achieve high efficiency solar power even with a small installation area by installing a power generation unit.

The conventional solar power generator has a structure in which it is fixed in one direction, and thus there is a problem that power generation efficiency is lowered depending on the position of the sun changing in real time.

In addition, the conventional solar power generator has a structure in which only the front side of the solar cell generates electricity by being collected, or the solar cell generates electricity by collecting only on the rear side of the solar cell using parabola light, .

Further, in the conventional solar power generator, there is no device for cleaning the inside of the parabolic mirror when the parabolic mirror is used for power generation, so that it is troublesome for the person to manually clean the dust and foreign matter accumulated inside the parabolic mirror by hand.

In addition, since the conventional solar power generator is installed in a plane, a large area is required to be secured, which causes a limitation in space and an increase in cost.

1. Registration Patent Publication No. 10-1186349.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a photovoltaic power generation system capable of producing a high efficiency power by controlling a horizontal angle and a vertical angle of a parabolic arc, And a generator using solar heat.

In addition, the object of the present invention is to provide a solar cell in which the front surface of a solar cell collects sunlight and solar heat, and the rear surface of the solar cell collects sunlight and solar heat reflected by the parabola sunlight, And to provide a generator using sunlight and solar heat to produce electricity.

It is also an object of the present invention to provide a generator using sunlight and solar heat, which is capable of quickly and easily cleaning dust inside the parabola by installing an ultrasonic vibration device in the parabola.

It is another object of the present invention to provide a generator using sunlight and solar heat that can achieve high efficiency solar power even with a small installation area by providing a solar power generator with a multi-layer structure.

It is also an object of the present invention to provide a generator using sunlight and solar heat, which is configured to be easily assembled and disassembled so that replacement work can be easily performed when components are broken.

The problems to be solved by the present invention are not limited to the above-mentioned problems. It is to be understood that the present invention may be embodied in many other specific forms without departing from the spirit or scope of the invention.

According to an aspect of the present invention, there is provided a solar power generation system including: a solar power generation unit that generates power using sunlight and solar heat;

A rotary unit A installed at a lower portion of the solar power generator 100 and adjusting a horizontal angle and a vertical angle;

A control unit for controlling the rotation unit A by tracking the altitude of the sun according to the sunrise or sunset of the sun to increase the power generation efficiency of the solar power generation unit 100; , ≪ / RTI >

The solar power generation unit (100)

A solar cell 110 to which solar light and a solar heat collecting plate 111 are attached to the inner surface, and solar and solar heat collecting plates 112 are attached to an outer surface,

And a parabolic bead 120 fixed to a center portion of the inner side of the solar cell 110 and reflecting sunlight and solar heat to concentrate the sunlight and the solar collecting plate 111. [

The present invention has the effect of producing high-efficiency power by tracking the position of the sun changing in real time and adjusting the horizontal angle and vertical angle of the parabola sphere.

In addition, according to the present invention, since the front surface of a solar cell collects sunlight and solar heat, and the rear surface of the solar cell collects sunlight and solar heat reflected by the parabola sunlight, There is an effect that can be produced.

In addition, according to the present invention, by providing an ultrasonic vibration device in the parabola, the dust inside the parabola can be cleaned easily and quickly by the vibration.

In addition, the present invention has the effect of achieving high efficiency solar power even with a small installation area by installing the solar power generator with a multi-layer structure.

Further, according to the present invention, since the constituent parts can be assembled so as to be easy to attach and detach, it is easy to replace the parts when the parts are broken.

1 is an overall sectional view according to an embodiment of the present invention.
2 is a plan view according to an embodiment of the present invention.
3 is a partial cross-sectional view showing a solar power generator and a rotator of the present invention.
4 is an operational state diagram of Fig.
5 is a partial cross-sectional view of Fig.
Figure 6 is a partial perspective view of Figure 5;
Fig. 7 is a plan view of Fig. 6. Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

In the drawings, the same components are denoted by the same reference numerals throughout the drawings, and detailed descriptions of well-known functions or known configurations that may unnecessarily obscure the gist of the present invention are omitted.

The present invention relates to a power generating device using sunlight and solar heat, in which a plurality of support rods 470, on which a plurality of solar power generation parts 100 are installed, are installed vertically along the support posts 410, .

As shown in FIGS. 1 to 7, a generator using sunlight and solar heat according to the present invention includes a solar thermal power generation unit 100, a rotary unit A, a control unit, and a support unit 400 .

The solar power generation unit 100 generates electric power using solar light and solar heat.

For this purpose, the solar power generator 100 includes a solar cell 110, a parabolic mirror 120, and an ultrasonic vibrator 130.

Solar light and a solar heat collecting plate 111 are attached to the inner surface of the solar cell 110 and a solar and solar heat collecting plate 112 is attached to the outer surface of the solar cell 110. The sunlight and the solar collecting plate 111 of the solar cell 110 receive sunlight and solar heat reflected and concentrated by the parabola 120 to produce electric power. The solar and solar heat collecting plates 112 of the solar cell 110 produce power using direct sunlight and solar heat. The production efficiency is maximized because the solar cell 110 generates electric power by using sunlight and solar heat simultaneously on the inner and outer surfaces thereof.

The parabola 120 is fixed to the central portion of the inner side of the solar cell 110 and reflects sunlight and solar heat to concentrate the sunlight and the solar heat collecting plate 111. The parabolic mirror 120 has a curved shape with an inner concave shape, and a reflection material of a metal material is plated therein, and a vertical rotating arm 310 is installed at a lower end thereof. The parabola 120 is made of stainless steel and the reflection film 121 and the polyester film 122 are sequentially attached to the inside of the parabola 120 to form a UV coating 123. This maximizes the reflectivity of the parabola 120 and helps to produce the maximum power.

The ultrasonic vibration device 130 is installed on the outer surface of the parabola 120 so as to communicate with the inside of the parabola 120. The ultrasonic vibration device 130 allows the parabolic bead 120 to vibrate so that the dust of the concave portion inside the parabolic bead 120 can be removed from the surface, thereby effectively removing dust. For example, when rainwater accumulates inside the upward parabolic bead 120, if the ultrasonic vibrator 130 is operated to vibrate, the dust inside the parabolic bead 120 is washed away together with the rainwater. If the angle of the parabola 120 is adjusted downward, the inside of the parabola 120 is cleaned.

The rotary unit A is installed under the solar power generator 100 to adjust the horizontal angle and vertical angle of the solar power generator 100. The rotary unit A tracks the sun's position changing in real time and controls the horizontal angle and the vertical angle of the parabola 120 to produce high efficiency power using solar and solar heat.

To this end, the rotating device unit A includes a horizontal rotating unit 200 and a vertical rotating unit 300.

The horizontal rotation means 200 includes a support plate 210, a support shaft 220, a horizontal rotation arm 230, a rotary gear 231, a first motor M1, a thrust bearing B, And a support string 251. [

The support plate 210 is formed by bending in the shape of an 'a', and the lower end of the support plate 210 is coupled to a support 470 to be described later by using a bracket 211.

The support shaft 220 protrudes upward from one side of the support plate 210.

One end of the horizontal rotating arm 230 is rotatably coupled to the outer periphery of the support shaft 220. At this time, a thrust bearing (B) is interposed between the horizontal rotary arm (230) and the support shaft (220). Also, a coupling nut 221 can be fastened to the upper end of the support shaft 220.

The rotary gear 231 is formed on the outer peripheral surface of the horizontal rotary arm 230 coupled to the support shaft 220.

The first motor M1 is attached to a wall surface formed by bending one end of the support plate 210 upward and is coupled to the driving shaft of the first motor M1 so as to engage with the rotation gear 231 of the horizontal rotation arm 230, (240) is mounted. Thus, as the first motor M1 rotates in the forward and reverse directions, the horizontal rotary arm 230 rotates about the support shaft 220 in the left-right direction.

The center shaft 250 is fitted in the center of the support shaft 220 and is supported by the support shaft 220.

The support rope 251 connects the upper surface of the horizontal rotary arm 230 and the central shaft 250 and supports the upper end of the support plate 210 and the central shaft 250 by connecting them. The supporting rods 251 serve to support the load of the horizontal rotating arm 230.

The vertical rotating means 300 includes a vertical rotating arm 310 and a second motor M2.

One end of the vertical rotating arm 310 is fixed to the lower side of the outer side of the parabola 120 and the other end of the vertical rotating arm 310 is rotatably supported on the end of the horizontal rotating arm 230, Respectively.

The second motor M2 is fixed to one side of the horizontal rotating arm 230 and the driving gear 240 is mounted on the driving shaft so as to engage with the rotating gear 231 of the vertical rotating arm 310. As the second motor M2 rotates in the forward and reverse directions, the vertical rotating arm 310 rotates in the vertical direction about the rotary gear 231.

Thus, the parabolic bead 120 is rotated in the left-right direction by the horizontal rotating means 200, and is rotated in the vertical direction by the vertical rotating means 300.

A control unit (not shown) monitors the altitude of the sun in accordance with the sunrise or sunset of the sun and controls the rotating unit A to increase the power generation efficiency of the solar power generation unit 100. The control unit controls the horizontal rotation unit 200 to track the position of the sun changing in real time to adjust the horizontal angle of the parabolic light 120 and the vertical rotation unit 300 to control the vertical angle of the parabolic light 120 To maximize the use of solar and solar heat to produce high-efficiency power.

The support part (400) stacks a plurality of solar power generation parts (100) in multiple layers up and down, thereby enabling highly efficient solar power generation in a narrow space.

The support portion 400 includes a support 410, a reinforcement support 410, a support 430, a base 440, a cushioning member 450, an anchor bolt 460, and a support 470 .

The post 410 is erected perpendicular to the ground.

The reinforcing struts 410 are placed in contact with the outer periphery of the struts 410 so as to be supported.

The lower end of the strut 410 and the reinforcing strut 410 are fitted and fixed to the pedestal 430.

The base 440 is provided below the pedestal 430.

The cushioning material 450 is interposed between the pedestal 430 and the base 440. The cushioning material 450 serves to buffer shocks received from the outside by the struts 410 and the reinforcing struts 410, thereby prolonging the life of each device.

The anchor bolt 460 is installed so as to penetrate the edge of the anchor flange 431 formed on the outer periphery of the pedestal 430 and the edge of the base 440 at the same time.

The supporting member 470 is formed in the shape of a band around the support 410 and a coupling body 471 is formed at the center of the support body 470 so that the coupling body 471 is coupled to surround the supporting column 410 and the reinforcing support 410. The supporting posts 470 are coupled along the supporting posts 410 at a predetermined interval. A plurality of solar power generation units 100 are installed at predetermined intervals in the respective support rods 470.

Hereinafter, the operation and effect of the present invention will be described in detail.

As the sun rises and the position changes in real time, the control unit senses and tracks the position of the sun to control the horizontal rotation means 200 and the vertical rotation means 300 of each solar power generation unit 100, By adjusting the horizontal angle and vertical angle of solar power, solar power and solar heat can be maximally accommodated to produce high efficiency power.

On the other hand, when the sun rises, the control unit rotates the parabolic bevel 120 of each solar power generation unit 100 downward to prevent accumulation of dust in the parabolic bead 120. [

Therefore, the present invention has an effect of producing high-efficiency power by tracking the position of the sun changing in real time and adjusting the horizontal angle and the vertical angle of the parabola sphere.

In addition, according to the present invention, since the front surface of a solar cell collects sunlight and solar heat, and the rear surface of the solar cell collects sunlight and solar heat reflected by the parabola sunlight, There is an effect that can be produced.

In addition, according to the present invention, by providing an ultrasonic vibration device in the parabola, the dust inside the parabola can be cleaned easily and quickly by the vibration.

In addition, the present invention has the effect of achieving high efficiency solar power even with a small installation area by installing the solar power generator with a multi-layer structure.

Further, according to the present invention, since the constituent parts can be assembled so as to be easy to attach and detach, it is easy to replace the parts when the parts are broken.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limiting the scope of the invention as defined by the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

100: solar power generator 110: solar cell
111: Solar and solar panel
112: Photovoltaic and solar additional solar panels
120: Parabola Sight 121: Reflective film
122: polyester film 123: UV coating
130: Ultrasonic vibration device A: Rotating device part
200: horizontal rotating means 210:
220: support shaft 230: horizontal rotation arm
M1: first motor 250: center axis
251: Support line 300: Vertical rotation means
310: vertical rotating arm 311: rotary gear
M2: second motor 400:
410: supporting column 420: reinforcing supporting column
430: pedestal 440: base
450: Cushioning material 460: Anchor bolt
470: Support 471: Coupling

Claims (4)

A solar power generator 100 for generating electricity using sunlight and solar heat;
A rotary unit A installed at a lower portion of the solar power generator 100 and adjusting a horizontal angle and a vertical angle;
A control unit for controlling the rotation unit A by tracking the altitude of the sun according to the sunrise or sunset of the sun to increase the power generation efficiency of the solar power generation unit 100; , ≪ / RTI >
The solar power generation unit (100)
A solar cell 110 to which solar light and a solar heat collecting plate 111 are attached to the inner surface, and solar and solar heat collecting plates 112 are attached to an outer surface,
And a parabolic reflector 120 fixed to the central portion of the inner side of the solar cell 110 and reflecting sunlight and solar heat to concentrate the sunlight and the solar heat collecting plate 111,
The parabola 120 is made of stainless steel and the reflection film 121 and the polyester film 122 are sequentially attached to the parabola 120 and the UV coating 123 is applied to the parabola 120,
An ultrasonic vibration device 130 is installed on the outer surface of the parabola 120 to remove dust inside the parabola 120,
The rotary unit A includes a horizontal rotary unit 200 and a vertical rotary unit 300,
The horizontal rotation means (200)
A support plate 210,
A support shaft 220 protruding upward from one side of the support plate 210,
A horizontal rotary arm 230 rotatably coupled to the outer periphery of the support shaft 220,
A rotary gear 231 formed on the outer peripheral surface of the horizontal rotary arm 230 coupled to the support shaft 220,
A first motor M1 mounted on a wall surface formed by bending one end of the support plate 210 upward and mounted with a drive gear 240 on a drive shaft so as to engage with the rotation gear 231 of the horizontal rotation arm 230,
A thrust bearing B interposed between the horizontal rotary arm 230 and the support shaft 220,
A center shaft 250 which is fitted in the center of the support shaft 220 and is supported by the support shaft 220,
A strut 251 connecting the upper surface of the horizontal rotary arm 230 and the central axis 250 and connecting the upper end of the support plate 210 and the central axis 250 to support the load of the horizontal rotary arm 230 ≪ / RTI >
The vertical rotation means (300)
A vertical rotating arm 310 fixed to an outer lower end of the parabolic arc 120 and rotatably installed at an end of the horizontal rotating arm 230 with a rotary gear 231 mounted on the other end,
And a second motor M2 fixed to the horizontal rotary arm 230 and having the driving gear 240 mounted on the driving shaft so as to engage with the rotary gear 231 of the vertical rotary arm 310, Generator used.
delete delete The method according to claim 1,
Further comprising a support part (400) for allowing a plurality of solar power generation parts (100) to be stacked in a multilayer structure up and down,
The support portion (400)
A strut 410 standing upright on the ground,
A reinforcing strut 410 standing up side by side to support the outer periphery of the strut 410,
A pedestal 430 in which the lower ends of the struts 410 and the reinforcing struts 410 are fitted and fixed,
A base 440 provided under the pedestal 430,
A cushioning material 450 interposed between the pedestal 430 and the base 440,
An anchor bolt 460 installed to penetrate the edge of the base 440 at the same time as the anchor flange 431 formed on the outer periphery of the pedestal 430 and having the lower end embedded in the ground at a certain depth,
A coupling body 471 is formed at the center of the support 410 so that the coupling body 471 is coupled to the support column 410 so as to surround the reinforcing support column 410, And a support 470 to which a plurality of members are coupled,
And a plurality of solar power generation units (100) are installed in the respective support rods (470).

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