KR101081258B1 - Efficiency multiplying system for solar photovoltatic power generation - Google Patents

Abstract

The present invention relates to a multiplication device for improving the power generation efficiency of photovoltaic power generation, and more specifically, solar light directly from the sun in a fixed installed solar module without the installation of a large-scale photovoltaic module or a plurality of solar modules Irradiation and the sunlight irradiated to and received from the first mirror body have a double irradiation method that is reflected through the outer circumferential surface of the rotatable second mirror body to evenly irradiate the solar module. The effect of irradiation and the condensation efficiency of the solar module can be improved and the amount of power generation can be increased. Also, this method of irradiation can be used for the mid-high altitude of the sun, or before and after the mid-high altitude, weather, environment, The information is collected by various sensors according to the change of seasons and tides, and the first mirror and the second mirror are automatically changed according to the collected information and the amount of generation of solar modules. That is because it works, you can always bring an increase in power generation and improve the efficiency of the condenser,

Solar module for generating power by collecting sunlight from the sun; A first mirror body installed at a predetermined distance from the front of the solar module to receive and reflect sunlight from the sun; A second mirror body installed at a predetermined distance to one side of the first mirror body to reflect the sunlight reflected from the first mirror body to the light receiving module and the solar module; A control unit which collects information according to the altitude of the sun, the weather and the environment, the season and the tides, and controls the driving of the first mirror body and the second mirror body based on the collected information; And it relates to a photovoltaic efficiency multiplication system comprising a display device for displaying each operation state for the driver to see.

Solar modules, power generation, first mirror body, second mirror body

Description

Efficiency multiplying system for solar photovoltatic power generation}

The present invention relates to a multiplication device for improving the power generation efficiency of photovoltaic power generation, and more particularly, by providing a method of irradiating solar power to the photovoltaic module that is irradiated with sunlight in a double way, two or more The present invention relates to a photovoltaic efficiency multiplication system that can obtain the effect of being irradiated with sunlight from the sun and can greatly improve the light collecting efficiency of solar light.

Generally, photovoltaic power generation equipment refers to a device that converts light energy of the sun into electrical energy using a solar module. At this time, the photovoltaic module is composed of a PN junction semiconductor to induce electricity by generating free electrons when irradiated with sunlight, it is easy to construct and use a limitless clean energy and nutrition to the installation restrictions according to environmental problems There is an advantage of not receiving.

In the conventional photovoltaic power generation system, as shown in FIG. 1, the photovoltaic module 10 for condensing a light source of the sun is fixed at a predetermined angle fixed to an installation frame 11 such as a roof, a wall, or a bottom surface. Installed, the installed solar module 10 is irradiated with sunlight to collect the sunlight, and to convert the collected solar light into electrical energy.

However, in the solar power generation system, the azimuth and altitude are different depending on the natural phenomenon of rotation and revolution of the earth and the latitude of the place where the solar module condenses the solar light. Since the light is only seen from one side, the concentration efficiency is the highest at the southern mid-high altitude, which is the highest concentration of light in the day, and the concentration of the power generation decreases gradually before and after the southern and middle altitudes, which take up a relatively long time. In addition, the irregular efficiency is greatly affected by the weather and the environment, and the change in the light collection efficiency of the season and tides (크게) is large.

On the other hand, in order to increase the condensing efficiency of the photovoltaic power generation facilities and the amount of power generation thereof, it can be solved by increasing the size of the solar modules or installing a plurality of solar modules. Due to a lot of constraints, it is very difficult to expect an increase in the size of the design of the power generation facility or the condensing efficiency by using a plurality of solar modules or increase in the amount of power generation.

The present invention has been made to solve the above problems, the solar module is directly irradiated with solar light and irradiates the sunlight by the reflection coated mirror which is directly installed and irradiated with solar light to the solar module The present invention provides a photovoltaic efficiency multiplier that can obtain the effect of being irradiated with sunlight from two or more suns by providing a double irradiation method to irradiate to improve the light condensing efficiency and increase the amount of power generation. There is a purpose.

The present invention for achieving the above object,

Solar module for generating power by collecting sunlight from the sun;

A first mirror body installed at a predetermined distance from the front of the solar module to receive and reflect sunlight from the sun;

A second mirror body installed at a predetermined distance to one side of the first mirror body to reflect the sunlight reflected from the first mirror body to the light receiving module and the solar module;

A control unit which collects information according to the altitude of the sun, the weather and the environment, the season and the tides, and controls the driving of the first mirror body and the second mirror body based on the collected information; And

It can be achieved by including a display device for displaying each operation state for the driver to see.

As described above, in the photovoltaic efficiency multiplication system of the present invention, the solar light is directly irradiated and irradiated to the first mirror body and received and received from the sun on a fixedly installed photovoltaic module without the installation of an enlarged photovoltaic module or a plurality of photovoltaic modules. The solar light has a double irradiation method that reflects through the outer circumferential surface of the rotatable second mirror body to evenly irradiate the solar module, and thus the effect of irradiating sunlight from two or more suns and condensation of the solar module The effect of improving the efficiency and increasing the amount of power generation can be obtained.

In addition, the survey method collects information from various sensors according to changes in weather, environment, seasons, and tides before and after the south and mid-high altitudes of the sun, which maintains a relatively long time. Accordingly, since the first mirror body and the second mirror body operate automatically, it is possible to obtain an effect that can bring about an improvement in the condensing efficiency and an increase in power generation at all times.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is an overall system configuration of the photovoltaic efficiency multiplication system of the present invention, Figure 3 is a full perspective view of the photovoltaic efficiency multiplication system of the present invention, Figure 4 is a first mirror body of the photovoltaic efficiency multiplication system of the present invention 5 is an exploded perspective view showing a second mirror body of the photovoltaic efficiency multiplication system of the present invention.

2 to 5, the solar cell efficiency multiplication system of the present invention includes a solar module 100 for collecting and generating sunlight, a first mirror body 200 for receiving and reflecting sunlight, A second mirror body 300 for reflecting sunlight reflected from the first mirror body 200 to the light receiving and solar modules 100, and the first mirror body 200 and the second mirror body 300. The control unit 400 for controlling the driving of the display device 500 for displaying the operation state of each.

At this time, the photovoltaic module 100 is made of a plate-shaped panel, and collects the sunlight from the sun, and converts the collected solar light into electrical energy.

In addition, the first mirror body 200 is installed to be spaced apart at a predetermined interval toward the front of the solar module 100, the support plate 220 facing both sides, the first drive fixed to the support plate 220 Motor 210 and the parabola mirror 230 for receiving and reflecting sunlight, but

The support plate 220 has a predetermined width and height and is provided with a through-shaft snow hole 221 on the upper portion of each support plate 220 facing each other.

The first drive motor 210 is fixed to the outer surface of any one of the support plate 220, the rotating shaft 211 withdrawn from the first drive motor 210 to the shaft hole 221 of both support plates 220. It is preferable to arrange them in a stacked manner.

The parabola mirror 230 has a parabolic hemispherical shape with a concave inside, and is provided with a first reflecting surface 231 reflecting coated on an inner side thereof, and a lower portion thereof is formed on the rotating shaft 211 to form a first driving motor. It is configured to be rotatable by the driving of 210, but is configured to reflect the sunlight emitted from the sun by the first reflecting surface 231 of the parabola mirror 230 to the light receiving and the second mirror body (300). .

In this case, the sunlight received by the parabolic mirror 230 is collected and reflected toward the center of the first reflection surface 231 due to the characteristics of the concave parabolic first reflection surface 231.

In addition, the second mirror body 300 is installed to be spaced apart at a predetermined interval in front of the first mirror body 200, the support plate 320 facing both sides and the second fixed to the support plate 320 The driving motor 310 and the polygon mirror-shaped polygon mirror 330 for receiving and reflecting sunlight received from the first mirror body 200,

The support plate 320 has a predetermined width and height, and the through-shape snow hole 321 is provided on each of the support plate 320 facing each other.

The second driving motor 310 is fixed to the outer surface of any one of the supporting plate 320, the rotating shaft 311 is drawn out of the second driving motor 310 to the shaft hole 321 of both support plates 320. It is preferable to arrange them in a stacked manner.

The polygon mirror 330 is formed in a hexagonal plate shape having a predetermined thickness and having a plurality of second reflecting surfaces 331 on an outer circumferential surface thereof, and the plurality of polygon mirrors 330 are arranged at regular intervals on the rotating shaft 311. However, the light reflected from the parabolic mirror 230 of the first mirror body 200 is configured to be reflected by the light receiving and solar modules 100 on any one second reflecting surface 331 of the polygon mirror 330 will be.

In addition, the controller 400 collects information according to the altitude of the sun, the weather and the environment, the season and the tides, and based on the collected information, the first mirror body 200 and the second mirror body 300. ), A sensor unit 410 for measuring various types of information, a microprocessor 420 for collecting and storing the various types of information, the first mirror body 200 and the second mirror body 300. Configured as a motor driver 430 to control the drive,

The sensor unit 410 includes a temperature sensor 411 for measuring the temperature of the day, a humidity sensor 412 for measuring the humidity of the day, an illuminance sensor 413 for measuring the illuminance of sunlight, and It is composed of a CT sensor 414 for measuring the amount of power generation of the solar module 100 in real time.

The microprocessor 420 is configured to receive and store various types of information measured by the sensor unit 410.

The motor driver 430 is configured to drive and control the 1.2 driving motors 210 and 310 of the first mirror body 200 and the second mirror body 300 by receiving a command from the microprocessor 420. .

In this case, the motor driver 430 is fed back to the operation of each mirror, and through this further comprises an encoder 431 for controlling the rotation speed of the parabola mirror 230 and the polygon mirror 330 to control the rotation speed Is preferable.

In addition, the display apparatus 500, it is preferable to use a monitor capable of outputting an image that is commonly used to display the respective operation state for the driver to see.

Meanwhile, as illustrated in FIG. 8, the support plate 220 of the first mirror body 200 may be configured to have an “c” shape with an open upper portion, and may include a vertical cylinder 240 at a lower portion thereof. will be.

That is, the end of the cylinder rod 241 of the cylinder 240 is coupled to the lower surface of the support plate 220 is configured so that the first mirror body 200 is moved up and down according to the appearance of the cylinder rod 241, The solar light irradiated from the sun by the parabola mirror 230 is rotated and lifted without passing through the second mirror body 300 to be directly reflected by the solar module 100.

In this case, the cylinder 240 may be selectively used among pneumatic cylinders using pneumatic or hydraulic cylinders using hydraulic pressure.

Hereinafter, the operation of the present invention photovoltaic efficiency multiplication system having the configuration as described above will be described in detail with reference to the accompanying drawings.

In the photovoltaic efficiency multiplication system of the present invention, as shown in FIGS. 2 and 5, the solar light irradiated from the sun is directly collected from the solar module 100 and the parabolic mirror 230 of the first mirror body 200 is used. The light is reflected and reflected by the polygon mirror 330 of the second mirror body 300, and the reflected sunlight is sequentially and repeatedly irradiated to each part of the solar module 100 through the polygon mirror 330.

That is, in the solar module 100, the energy directly radiated from the sun and the energy received from the polygon mirror 330 overlap to output electricity with higher generation efficiency.

At this time, the amount of sunlight irradiated to the solar module 100 is determined by sensing the illumination intensity and the amount of power generation of the module for each time. That is, when the weather is good, even if only natural sunlight comes up to the maximum output of the solar module 100, the mirror body is stopped or the operation amount is minimized to minimize the amount of reflection, the weather is cloudy or less than the maximum output of the solar module In this case, it is necessary to maximize the amount of reflection by increasing the amount of operation of the mirror body.

On the other hand, the photovoltaic efficiency multiplication system of the present invention having the operating state as described above, the operation is controlled by the control unit 400 for collecting and outputting information in accordance with changes in weather and environment, seasons and tides,

In the sensor unit 410 of the control unit 400, the temperature of the day is measured by the temperature sensor 411, the humidity of the day is measured by the humidity sensor 412, and the sunlight is measured by the illuminance sensor 413. The illuminance is measured, and the power generation amount of the solar module 100 is measured by the CT sensor 414.

Thereafter, the various information measured by the sensor unit 410 is transferred to the microprocessor 420 and stored.

Thereafter, the microprocessor 420 transmits a command to the motor driver 430 and drives the first mirror body 200 and the second mirror body 300 by the command of the motor driver 430 according to the stored information. will be.

In the motor driver 430, the rotation speeds of the first mirror body 200 and the second mirror body 300 are controlled by the encoder 431.

In this case, the CT sensor 414 is to sense the power generation amount of the solar module 100 in real time, the amount of solar light required for the photovoltaic module 100 is determined by the sensing of the CT sensor, the amount of light collected The microprocessor 420 transmits a command to the motor driver 430 and the motor driver 430 selectively drives the first mirror body 200 or the second mirror body 300 by the encoder 431. The rotation speed is controlled.

FIG. 6 is an explanatory view showing an operating state of the first mirror body of the photovoltaic efficiency multiplication system of the present invention, wherein the operation of the second mirror body 300 is stopped by the command of the controller 400. By the operation of the (200) is to reflect the sunlight to the second mirror body 300 and to the solar module 100, at this time, the second mirror body 300 is any one of the second reflecting surface ( 331 is preferably fixed to the solar module 100 and the first mirror body 200 to be adjusted.

First, the sunlight irradiated from the sun is primarily irradiated and focused on the solar module 100.

In addition, the sunlight is also irradiated to the first mirror body 200, the irradiated sunlight is irradiated and reflected by the parabolic mirror 230 of the first mirror body 200, the reflected sunlight is the second mirror Irradiated to the polygon mirror 330 of the sieve 300 and is reflected back to the solar module 100 from the polygon mirror 330.

At this time, as shown in FIG. 6A, in the state where the center point of the parabola mirror 230 is rotated and adjusted toward the lower end of the second reflection surface 331 of the polygon mirror 330, the sunlight reflected from the parabola mirror 230 is reflected. Is irradiated to the lower end of the second reflecting surface 331 of the polygon mirror 330, the irradiated sunlight is irradiated to the lower end of the solar module 100 by a reflection angle formed relatively narrow.

In addition, in the state in which the center point of the parabola mirror 230 is rotated and adjusted toward the upper end of the second reflecting surface 331 of the polygon mirror 330 as shown in FIG. 6B, the sunlight reflected from the parabola mirror 230 is Is irradiated to the upper end of the second reflecting surface 331 of the polygon mirror 330, the irradiated sunlight is irradiated to the upper end of the solar module 100 by a reflection angle formed relatively wide.

That is, the position of the sunlight irradiated to the photovoltaic module 100 is determined by the reflection angle reflected from the sunlight irradiated from the parabola mirror 230 and the polygon mirror 330, and the parabola mirror 230 is driven first. When rotated by the power of the motor 210, the center point thereof is irradiated to the second reflecting surface 331 sequentially from the upper end to the lower end of the second mirror 331 of the polygon mirror 330, or from the lower end toward the upper end. Received sunlight, and the received sunlight is reflected back and collected in the solar module 100 in order from the top to the bottom of the photovoltaic module 100 or from the bottom to the top according to the angle of reflection.

FIG. 7 is an explanatory view showing an operating state of the second mirror body of the photovoltaic efficiency multiplication system of the present invention, wherein the operation of the first mirror body 200 is stopped by the command of the control unit 400. The solar 300 is irradiated to the solar module 100 by the operation of the sieve 300. In this case, the first mirror body 200 has the center of the first reflection surface 231 as the second mirror body 300. Is fixed to the polygon mirror 330.

First, the sunlight irradiated from the sun is primarily irradiated and focused on the solar module 100.

In addition, the sunlight is also irradiated to the first mirror body 200, the irradiated sunlight is irradiated to the parabola mirror 230 of the first mirror body 200, the irradiated sunlight is a second mirror body ( Irradiated to the polygon mirror 330 of 300 and is reflected back to the solar module 100 from the polygon mirror 330.

At this time, as shown in (a) of FIG. 7, the angle at which the sunlight emitted from the parabola mirror 230 is irradiated and reflected on the second reflection surface 331 of the polygon mirror 330 while the polygon mirror 330 is rotating is narrow. At the time of formation, the sunlight irradiated from the parabola mirror 230 is reflected and irradiated to the lower end of the solar module 100.

In addition, as shown in FIG. 7B, the angle at which the sunlight emitted from the parabola mirror 230 is irradiated and reflected on the second reflection surface 331 of the polygon mirror 330 while the polygon mirror 330 is rotating is wide. At the time of formation, the sunlight irradiated from the parabola mirror 230 is reflected and irradiated to the upper end of the solar module 100.

That is, the position of sunlight irradiated to the photovoltaic module 100 is determined by the reflection angle reflected from the sunlight irradiated from the parabola mirror 230 and the polygon mirror 330, and the polygon mirror 330 is driven in the second drive. When rotating by the power of the motor 310 from the top of the solar module 100 to the bottom or in accordance with the change in the angle reflected by the sunlight and the second reflecting surface 331 irradiated from the parabola mirror 230 In order to sequentially reflect from the bottom to the top and the solar module 100 is to be secondarily collected.

In addition, Figure 9 is an explanatory view showing an operating state according to another embodiment of the first mirror body 200 of the photovoltaic efficiency multiplication system of the present invention, the first mirror in a state in which the second mirror body 300 is excluded It is to be directly irradiated to the solar module 100 from the sieve 200, in which case, the first mirror body 200 is to irradiate the sunlight to the solar module 100 by the lifting and lowering and rotation thereof.

First, the sunlight irradiated from the sun is primarily irradiated and focused on the solar module 100.

In addition, the sunlight is also irradiated to the first mirror body 200, the irradiated sunlight is irradiated to the parabola mirror 230 of the first mirror body 200, the irradiated sunlight is reflected back to the sunlight Irradiated by the module 100, the first mirror body 200 is to be moved up and down by the appearance of the cylinder rod 241 of the cylinder 240 coupled to the lower portion of the support plate 220, at this time, parabola The first reflective surface 231 of the mirror 230 is fixed to the solar module 100 and the sun.

In this case, as shown in FIG. 9A, when the first mirror body 200 reaches a lowered state, the first reflection surface 231 of the first mirror body 200 faces the lower end of the solar module 100. In this case, the sunlight is reflected through the first reflecting surface 231 and irradiated to the bottom of the solar module 100.

In addition, when the first mirror body 200 rises as shown in FIG. 9B, the first reflective surface 231 of the first mirror body 200 is positioned to face the upper end of the solar module 100. In this case, the sunlight is reflected through the first reflecting surface 231 is irradiated to the upper end of the solar module 100.

That is, the first mirror body 200 is repeatedly lifted and lowered by the appearance of the cylinder rod 241, the sunlight irradiated to the parabola mirror 230 is upper again from the lower end of the solar module 100 As it is or from the bottom to the top sequentially reflected and concentrated in the solar module 100.

On the other hand, the operation of the first mirror body 200 and the second mirror body 300 as described above can be operated at the same time by the command of the control unit 400, in this case, each of the 1.2 mirror body as described above ( 200) is made by the operating state of 300.

In addition, the operating state as described above is that the driver can check the operating state through the display device 500 is provided separately.

As described above, in the photovoltaic efficiency multiplication system of the present invention, the primary light condensation of the sunlight irradiated from the sun to the photovoltaic module 100 and the secondary condensation are indirectly by the 1.2 mirror bodies 200 and 300. By enabling it, it is possible to always improve the light collection efficiency.

1 is a perspective view showing a conventional solar module.

Figure 2 is an overall system configuration of the present invention photovoltaic efficiency multiplication system.

 Figure 3 is an overall perspective view of the present invention photovoltaic efficiency multiplication system.

Figure 4 is an exploded perspective view showing a first mirror of the present invention photovoltaic efficiency multiplication system.

5 is an exploded perspective view showing a second mirror of the present invention photovoltaic efficiency multiplication system.

Figure 6 is an operating state of the first mirror of the present invention photovoltaic efficiency multiplication system.

Figure 7 is an operating state of the second mirror body of the present invention photovoltaic efficiency multiplication system.

8 is a perspective view showing another embodiment of the first mirror of the present invention photovoltaic efficiency multiplication system.

Figure 9 is an operating state of the embodiment of the first mirror of the present invention photovoltaic efficiency multiplication system.

          <Description of Symbols for Main Parts of Drawings>

100: solar module 200: the first mirror body

210: first drive motor 220: support plate

230: parabola mirror 240: cylinder

300: second mirror body 310: second drive motor

320: support plate 330: polygon mirror

400: control unit 410: sensor unit

420: microprocessor 430: motor driver

500: display device

Claims (9)

A solar module 100 that collects and generates sunlight by irradiating sunlight from the sun; It is installed at a predetermined distance in front of the photovoltaic module 100 to receive and reflect the sunlight from the sun, and each support plate 220 is provided with a snow hole 221, and each one of the support plate 220 Fixed to the rotating shaft 211 forms a first driving motor 210 and the first reflective surface 231 is concave parabolic shape concave in the concave hole 221 of the two support plate 220, the lower portion of the rotating shaft ( Consists of a parabola mirror 230 is installed in the rotating 211, the reflection of the sunlight irradiated from the sun by the first reflecting surface 231 of the parabola mirror 230 to the light receiving and second mirror body (300) A first mirror body 200 configured to be; Installed at one side of the first mirror body 200 at a predetermined distance to reflect the sunlight reflected from the first mirror body 200 to the light-receiving and photovoltaic modules 100, and both sides of the first and second holes 321 are formed. A second driving motor 310 which is fixed to the support plate 320 and one of the support plates 320, and the rotation shaft 311 is formed in the hole 321 of both support plates 320, and the rotation shaft ( 311 is configured to be a polygon mirror polygon 330 having a second reflecting surface 331 on the outer circumferential surface and is rotated, the first by the second reflecting surface 331 of the polygon mirror 330 A second mirror body 300 configured to reflect the sunlight reflected from the parabolic mirror 230 of the mirror body 200 to the light receiving and solar module 100; The controller 400 collects information according to the sun's altitude, weather and environment, seasons, and tides, and controls the driving of the first mirror body 200 and the second mirror body 300 based on the collected information. ); And A display device 500 for displaying the operation state so that the driver can see it; Photovoltaic efficiency multiplication system, characterized in that consisting of. delete delete delete The method of claim 1, The support plate 220, the upper portion of the open "c" type configuration, including a vertical cylinder 240 in the lower portion, An end portion of the cylinder rod 241 of the cylinder 240 is coupled to the lower surface of the support plate 220, so that the first mirror body 200 moves up and down according to the appearance of the cylinder rod 241. Photovoltaic efficiency multiplication system. delete The method of claim 1, The polygon mirror 330 is formed in a hexagonal plate shape having a predetermined thickness and having a second reflective surface 331 on the outer circumferential surface, and a plurality of the polygon mirrors are arranged at regular intervals on the rotating shaft 311. Photovoltaic efficiency multiplication system characterized in that. The method of claim 1, The control unit 400 includes a temperature sensor 411 for measuring the temperature of the day, a humidity sensor 412 for measuring the humidity of the day, an illuminance sensor 413 for measuring the illuminance of the sunlight, and Sensor unit 410 made of a CT sensor 414 for measuring the amount of power generation of the solar module 100 in real time; A microprocessor 420 for collecting and storing various types of information measured by the sensor unit 410; And It comprises a motor driver 430 for driving control of the 1.2 driving motors 210 and 310 of the first mirror body 200 and the second mirror body 300 by receiving a command from the microprocessor 420. Photovoltaic efficiency multiplication system, characterized in that. The method of claim 8, Feedback to the operation of each mirror to the motor driver (430), and through this, further comprising an encoder (431) for controlling the rotational speed of each mirror.

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