KR20120004181A - Reflecting mirror apparatus for solar power generation - Google Patents

Abstract

PURPOSE: A reflecting device for photovoltaic power generation is provided to reduce the loss of electricity for tracking control by controlling orientation angle of a fixed reflector unit according to meridian altitude of each season. CONSTITUTION: A reflecting device for photovoltaic power generation comprises a PV(photovoltaic) module(20), a reflecting unit(30), a sensing unit, and a controller(60). The PV module is installed in the frame(10) toward the meridian altitude of solar. The reflecting unit is installed at least one side of the PV module and makes quantity of incident sunlight increased. The sensing unit detects quantity of incident sunlight and generation with respect to PV module. The controller drives the reflecting unit according to signal of the sensing unit in order to increase generating efficiency.

Description

Reflecting mirror apparatus for solar power generation

The present invention relates to a photovoltaic device, and more particularly, to a reflector device for photovoltaic power generation for contributing to an increase in power generation by minimizing power consumption required for tracking the sun.

In general, photovoltaic power generation methods are largely classified into fixed type and solar position tracking type. The former is a method in which a photovoltaic power generation facility comprehensively analyzes the solar elevation angle and the amount of sunshine, and fixes it at the most appropriate angle and orientation. The latter is a method in which the angle of the solar cell module changes according to the sun's altitude. In particular, in the latter case, Maximun Power Point Tracking (MPPT) is controlled to always operate at the maximum power point, considering that the output characteristics of the solar cell are changed according to the surrounding environment such as solar radiation, operating voltage and temperature. Perform

However, in areas where the amount of sunshine is not enough due to frequent rainfall, such as Korea, power consumption due to solar tracking is high, which causes a reduction in power generation efficiency. Therefore, a method of using an auxiliary means such as a reflector has been devised. In this regard, "photovoltaic generator having a reflector mounted on the edge of a light collecting portion" of Korean Patent Publication No. 2009-0037611, and a "mirror control solar cell" of Korean Patent Publication No. 2007-0116569 are known.

Korean Unexamined Patent Publication No. 2009-0037611 is mounted on a part or all of the tracked photovoltaic generator condensing part bent by more than 90 degrees ~ less than 135 degrees (Fig. 3: 100) in consideration of the condensing frame size and reflector size A technology that implements a low-cost solar generator by using less solar modules by using a reflector that is cheaper than a solar module by increasing the electricity output by additionally supplying solar light by placing and fixing a reflector on a table. Suggest.

Korean Patent Laid-Open Publication No. 2007-0116569 discloses a support substrate 101, a first module 110 composed of a solar cell 102 disposed thereon, and a reflective light focusing mirror 111 on a front surface thereof. In the solar cell module including the second module 120, the first and second modules 110 and 120 and the connecting portion 130 connecting them, the incident solar light 140 is a solar cell 102 ) Is directly incident to the focusing mirror 111, or is incident to the solar cell 102, the drive shaft 151 to the focusing mirror 111 and the support 112 to change the angle of the focusing mirror 111 And a shaft holder 152 is proposed.

However, according to the prior art described above, since the real-time feedback control is performed when the weight of the light collecting unit is large or when the light is collected, the power consumption of the solar tracking is increased and the overall facility and maintenance costs are also increased.

An object of the present invention for improving the conventional problems as described above is to provide a photovoltaic power reflector device for contributing to the increase of power generation by improving the condensing efficiency while minimizing the power consumption required to track the sun. .

In order to achieve the above object, the present invention provides a reflector device for assisting photovoltaic power generation: a PV module installed on the frame to face the southern position of the sun; Reflector means installed on at least one side of the PV module to increase the amount of incident light from the sun; Sensing means for detecting the amount of incident light and the amount of power generated by the sun to said PV module; And a controller for driving the reflector means according to the signal of the sensing means to increase power generation efficiency.

In addition, according to the present invention, the reflecting means is characterized in that it comprises a housing that is installed to be able to rotate up and down on the side of the frame, and a movable reflector that is installed to be rotatable on the housing.

In addition, according to the present invention, the reflector means is characterized in that it further comprises a fixed reflector which is installed to be manually adjustable angle through the fastener on the side of the frame.

In addition, according to the present invention, the sensing means is characterized in that it comprises a plurality of illuminance sensors installed on the PV modules at uniform intervals, and a current sensor installed in the inverter for power conversion.

Further, according to the present invention, the controller performs periodic rotation of the reflector means based on the position data of the sun according to the season and time, and performs fine adjustment of the reflector means using signals of the illuminance sensor and the current sensor. It features.

As described above, according to the solar reflector device of the present invention, there is an effect of contributing to the increase in power generation by improving the light collecting efficiency while minimizing the power consumption required for tracking the sun.

1 is a schematic diagram showing the overall configuration of a device according to the present invention
Figure 2 is a bottom perspective view showing the main part of Figure 1 separately
3 is a diagram illustrating the main part of FIG. 1 terminated.
4 is a block diagram showing a schematic circuit connection of the device according to the invention.

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

The present invention relates to a reflector device for assisting photovoltaic power generation. Instead of expanding the size of expensive solar cells, a reflector is added to increase the amount of power generated by the increase in the amount of collected light. In particular, the main point is to minimize the power consumption in the process of increasing the amount of condensing to improve the actual power generation efficiency.

According to the present invention, the PV module 20 is installed on the frame 10 so as to face the southern position of the sun. The PV module 20 is installed based on the position (azimuth angle, altitude) of the sun in a fixed manner rather than position tracking type. The frame 10 is inclined so that the PV module 20 is spaced 1 m or more above the ground. The PV module 20 is a thin-film silicon method with a cost competitiveness by significantly reducing the use of expensive silicon. In the case of the thin film type silicon module, the decrease in efficiency due to the temperature rise is alleviated compared to the crystalline silicon module.

In addition, according to the present invention, the reflector means 30 is installed on at least one side of the PV module 20 to increase the amount of incident light from the sun. The use of the thin-film silicon-type PV module 20 reduces the need for tracking control to maintain the light incident angle optimally because of the low light quantity reactivity.

At this time, the reflecting means 30 is provided with a housing 32 which is installed on the side of the frame 10 so as to be rotated up and down, and a movable reflector 35 which is installed to be able to rotate left and right on the housing 32. As shown in FIG. 1, the support 24 is fixed to the lower side of the housing 22, and the housing 32 is rotatably mounted via the hinge shaft 33 at the end of the support 24. The movable reflector 35 is rotatably mounted on the housing 32 via another hinge shaft 34. A ball screw 42 and a servomotor 44 are connected between the support 24 and the housing 32 to perform a swing movement of the movable reflector 35, and between the housing 32 and the movable reflector 35. Another servo motor 45 is connected to perform the yawing motion of the movable reflector 35.

On the other hand, the reflector means 30 may be further provided with a fixed reflector 37 which is installed on the side of the frame 10 via a fastener 47 manually adjustable angle. As shown in FIG. 1, the support 24 is fixed to the upper side surface of the housing 22, and the housing 32 and the fixed reflector 37 are attached through the fastener 47. As shown in FIG. Tightening port 47 is a conventional means for manually loosening and tightening the spiral engagement, it is possible to adjust the orientation angle of the fixed reflector 37 according to the height of the south of the sun according to the seasonal change. Placing the fixed reflector 37 in addition to the movable reflector 35 reduces power consumption due to tracking control.

In addition, according to the present invention is provided with a sensing means for detecting the amount of incident light and power generation of the sun to the PV module 20. Parameters affecting the amount of incident light of the PV module 20 include solar altitude, cloud cover, dust accumulation amount, temperature, and the like, and the influence of each variable appears as a change in the generation amount of the PV module 20. . The present invention avoids a method of increasing power consumption and consequently lowering power generation efficiency by performing precise feedback control with many input points as sensing means.

In this case, the sensing means includes a plurality of illumination sensors 52 installed on the PV module 20 at uniform intervals, and a current sensor 54 installed on the inverter 58 for power conversion. The illuminance sensor 52 is arranged at least four in front of the PV module 20 in the form of a lattice at uniform intervals. The inverter 58 includes a current sensor 54 for detecting the amount of power generation along with a circuit configuration for converting DC power generated in each cell of the PV module 20 into AC power. In addition, a temperature sensor may be provided on the PV module 20.

In addition, according to the present invention includes a controller 60 for driving the reflector means 30 in accordance with the signal of the sensing means to increase the power generation efficiency. Since the maximum power point of the PV module 20 changes according to parameters such as solar radiation, operating voltage, temperature, etc., it is preferable to introduce a maximum power point tracking (MPPT) control. However, a method of reducing power consumption by reducing computational load while using signals from the sensing means of the controller 60 is preferred.

At this time, the controller 60 performs the periodic rotation of the reflector means 30 on the basis of the position data of the sun according to the season and time, and the reflector using the signals of the illumination sensor 52 and the current sensor 54. Fine adjustment of the means 30 is carried out. In the memory of the controller 60, data on the solar motion trajectory (azimuth, altitude) of the region is stored. The controller 60 senses the current time with a timer and controls the servomotor 44 at a predetermined interval (for example, 30 minutes to 1 hour) to adjust the vertical angle of the movable reflector 35 at the same time. The servomotor 45 is controlled to correspond to the azimuth angle of the sun to adjust the left and right angles of the movable reflector 35. In the latter control, the change in input through the illuminance sensor 52 and the change in output through the current sensor 54 are taken into account.

In one example of the operation, the controller 60 adjusts the vertical angle of the movable reflector 35 every set time (for example, 30 minutes to 1 hour), and starts the operation of adjusting the left and right angles of the movable reflector 35 at this time. Of course, while the movable reflector 35 is rotated in one direction based on the basic data set in the memory, the stop point is determined in consideration of the change of the illumination sensor 52 and the current sensor 54. The signal inflection point of the current sensor 54 may be detected and determined while sensing the maximum signal from the illumination sensor 52 arranged in the grid. In this way, the burden on the controller 60 is minimized, contributing to the improvement of power generation efficiency.

If the amount of solar radiation through the illuminance sensor 52 is less than or equal to the reference value, it is determined that the weather is cloudy and the rotation control of the movable reflector 35 is stopped. Even in this case, since the solar position data of the current time is stored in the memory of the controller 60, the control can be continued after immediately rotating the movable reflector 35 to the predetermined position again as the weather clears. Even if the weather is clear, if the signal of the illumination sensor 52 is weak, since the dust is accumulated, an alarm (not shown) is output through the controller 60.

It is apparent to those skilled in the art that the present invention is not limited to the described embodiments, and that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, such modifications or variations will have to belong to the claims of the present invention.

10: frame 20: PV module
22: housing 24: support
30: reflector means 32: housing
33, 34: hinge axis 35: movable reflector
37: fixed reflector 42: ball screw
44: servo motor 45: servo motor
47: Tightening port 52: Ambient light sensor
54: current sensor 58: inverter
60: controller

Claims (5)

In the reflector device to help solar power generation:
PV module 20 is installed on the frame 10 to face the south position of the sun;
Reflector means 30 is installed on at least one side of the PV module 20 to increase the amount of incident light from the sun;
Sensing means for detecting the amount of incident light and the amount of power generated by the sun to the PV module 20; And
And a controller (60) for driving the reflector means (30) to increase the power generation efficiency according to the signal of the sensing means. The method of claim 1,
The reflector means 30 is characterized in that it comprises a housing 32 which is installed in the side of the frame 10 so as to be rotated up and down, and a movable reflector 35 is installed so as to rotate left and right on the housing 32. Reflector device for solar power generation. The method according to claim 1 or 2,
The reflector means 30 is a photovoltaic power reflector device, characterized in that it further comprises a fixed reflector (37) which is installed on the side of the frame (10) via a fastener (47) manually adjustable angle. The method of claim 1,
The sensing means is characterized in that it comprises a plurality of illumination sensors 52 installed on the PV module 20 at uniform intervals, and a current sensor 54 installed in the inverter 58 for power conversion Reflector device for photovoltaic power generation. The method of claim 1,
The controller 60 performs periodic rotation of the reflector means 30 based on the position data of the sun according to the season and time, and uses the signals of the illuminance sensor 52 and the current sensor 54 to reflect the reflector means ( 30) Reflector device for photovoltaic power generation, characterized in that to perform fine adjustment.

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