KR101088621B1 - Device for tracking moving trajectory of the sun with season - Google Patents

Abstract

PURPOSE: A device for controlling the rotation of a solar cell module by the variation of a sun altitude according to seasons is provided to simply control the slope of a solar cell panel. CONSTITUTION: A semicircular body(51) is located on the upper side of an assembly(50). First to fifth sense installation units(52a-52e) are formed on the upper side of the semicircular body. A proximity sensor unit(70) includes a body(71) with a combination hole(77). First to fifth proximity sensors(72-76) are regularly installed on one side of the body. A cover(80) prevents the exposure of the proximity sensor unit and a horizontal weight.

Description

Device for tracking moving trajectory of the sun with season}

The present invention relates to a rotation control apparatus of a solar cell module according to a change in seasonal solar altitude, and more particularly, it is possible to implement a device capable of adjusting the slope of the solar panel according to the south middle altitude of the seasonal sun most efficiently in a simple configuration. And it is related to the rotation control device of the solar cell module according to the change in the solar altitude of the season to increase the power generation efficiency of the solar panel by being able to spread the low cost.

Humanity on earth is now facing two problems that must be solved. The first is the depletion of fossil energy such as petroleum and coal used by mankind, and the second is the implementation of the climate change convention to prevent global warming due to the increased use of fossil energy.

If fossil energy, which humans thought it could use forever, continues to be used in the same amount as it is now, oil will be exhausted in 40 years, coal in 210 years, natural gas in 65 years and uranium in 50 years. In order to solve such a difficult problem, clean alternative energy, called 'future energy' or 'green energy', has been in the spotlight. Accordingly, countries have invested heavily in the development and distribution of alternative energy.

Alternative energy may be sunlight, solar heat, biomass, wind power control, geothermal, fuel cells, hydrogen energy, waste energy, etc., but the present invention will focus on using sunlight.

The sun has a surface temperature of 6,000 degrees Celsius and a central temperature of about 15 million degrees Celsius, which produces tremendous amounts of heat and light, reaching a whopping 9.2 X 1022 kcal, but the earth is about 150 million kilometers from the sun. Therefore, the amount of solar radiation reaching the earth (solar constant) is only about 2 cal.

This solar radiation is not only a source of energy for our daily lives, but also a driving force for various meteorological phenomena and currents in the sea. Other solar energy sources include solar cells, solar hot water equipment, and solar housing. , Solar furnaces, solar generators and so on.

As such, the most important factor for increasing efficiency in solar water systems such as solar hot water heaters, solar houses, solar furnaces, solar generators, etc. should be able to receive solar heat or sunlight for a long time.

That is, the sun moves along the orbit during the period from sunrise to sunset, so when the solar-powered device is fixed, the sun cannot be received under optimal conditions, thereby degrading the efficiency of the system. .

Therefore, it is not only widely known in the academic field that tracking solar heat-collecting devices along the sun's trajectory can increase the efficiency of the system by 30-60% by allowing solar heat to be taken under optimal conditions for a long time. A solar tracker was proposed.

In particular, because the Earth rotates and orbits, the location of the sun observed in each region changes every day, the altitude of the sun changes every day, and the current tracking device that tracks the movement from east to west along the sun is more efficient than the stationary fixed type. As high as 10-15%, some systems have been developed to track the sun against changes in the sun's position by rotation.

However, systems that track solar altitude due to seasonal changes are rarely developed, and most solar power generations differ in the efficiency of generation during summer and winter in a fixed angle.

In some conventional facilities, the device is rotated by a motor or a hydraulic device according to the south-high altitude of the sun, and Korean Patent Laid-Open Publication No. 2001-25541 (2001.04.06: drives the solar position tracking device and the tracking device of solar-related facilities. In the case of the driving system, and the solar position tracking control method), the solar altitude calculation formula, the necessity of an additional device for data processing, and the error elimination process are presented to suggest a method for tracking and controlling the solar position.

In the case of the prior art, the introduction of complicated electrical control methods requires the production of electronic systems, porting costs, post-installation hardware and software defects and maintenance, and requires specialized personnel. More effective measures are needed.

The present invention can implement a device capable of adjusting the slope of the solar panel according to the south mid-high altitude of the seasonal sun in a simple configuration, and the low-cost diffusion can increase the power generation efficiency of the solar panel It is a task.

The present invention rotates the solar panel 10 in accordance with the seasonal change in the solar altitude by driving the motor unit 30 in the control device 20 by the signal output from the solar altitude sensing device 100 for sensing the seasonal change in solar altitude In the rotation control device of the solar cell module according to the seasonal change in solar altitude to increase the power generation efficiency, the solar altitude sensing device 100 is formed with a space inside and a body 51 made of a semi-circle on the upper side is provided In the upper hemispherical shape of the body 51, first to fifth sense installation parts 52a to 52e having first to fifth solar inflow grooves 53a to 53e are formed at equal intervals. An assembly 50 formed with first to fifth light sensors 54a to 54e for outputting an electrical signal when sunlight having a predetermined illuminance is received in the fifth solar inflow grooves 53a to 53e, and the assembly To engage the inner side of the 50 A body 71 having a coupling hole 77 is provided, and the first to fifth proximity sensors 72 to 76 are provided on one side of the body 71 at predetermined intervals. And a hinge 63 introduced into the coupling hole 77 is installed at one end, and is always vertical to the ground by a load and presses the first to fifth proximity sensors 72 to 76. A fan-shaped body 61 is provided, and horizontal maintenance weights are formed in the lower center portion of the body 61 in which a cutting groove 62 for releasing the pressure of the first to fifth proximity sensors 72 to 76 is formed. 60 and a cover 80 installed on the other side of the assembly 50 to prevent exposure of the proximity sensor unit 70 and the horizontal holding weight 60.

In the present invention, the control device 20 is connected to the first to fifth optical sensors 54a to 54e in parallel, and is provided at each output end of the first to fifth optical sensors 54a to 54e. The first to fifth relays RY1 to RY5 are connected, and the seventh and eighth relays RY8 and RY10 and the first and fifth are connected to parallel connection ends of the first to fifth optical sensors 54a to 54e. Proximity sensors 72 and 76 are respectively connected in parallel, and second and fourth proximity sensors 73 and 75 are connected to the other ends of the seventh and eighth relays RY8 and RY10, respectively. One end of the third proximity sensor 74 is connected to the sixth relay switch RSW6, and the other end of the first and fifth proximity sensors 72 and 76 is connected to the ninth relay RY9. An eleventh relay switch RSW11 and a tenth relay RY10 are connected in series to the parallel connection ends of the first to fifth optical sensors 54a to 54e, and are connected to the first to tenth relays RY1 to RY10. The first, second, fourth, seventh, and eighth relay switches (RSW1), (RSW2), (RSW4), (RSW7), and (RSW8) are controlled by the motor (31). It is characterized in that the connection is made to the magnet switch (MSW1) (MSW2) for controlling.

As described above, the present invention can be implemented with a simple configuration of a device that can most effectively adjust the inclination of the solar panel according to the south-high altitude of the seasonal sun, it is possible to spread the low cost to improve the efficiency of solar panel Height is effective.

1 is a view showing the inclination angle of the solar panel according to the south mid-altitude of the sun in the region of 37.5 degrees north latitude of Korea.
Figure 2 is a block diagram of a rotation control device of the solar cell module according to the change in solar altitude by season.
Figure 3 is a perspective view of the solar altitude sensing device in the rotation control device of the solar cell module according to the seasonal solar altitude change of the present invention.
Figure 4a and 4b is an exploded perspective view of the solar altitude sensing device in the rotation control device of the solar cell module according to the seasonal solar altitude change of the present invention.
5 is an internal front view of a state in which the cover is removed in the rotation control apparatus of the solar cell module according to the seasonal solar altitude change of the present invention.
Figure 6 is a plan view of a rotation control device of a solar cell module according to the seasonal change in solar altitude of the present invention.
7 is a circuit diagram of a control device in the rotational control device of the solar cell module according to the seasonal change in solar altitude of the present invention.

Hereinafter, a rotation control apparatus of a solar cell module according to seasonal solar altitude change according to the present invention will be described in detail with reference to FIGS. 1 to 7.

Figure 1 shows the inclination angle of the solar panel according to the south middle altitude of the sun in the region of 37.5 degrees north latitude of Korea, the south middle altitude (h) of the sun according to the latitude is as follows.

h = 90˚-latitude + declination of the fat

Declination is + 23.5˚ in the lower extremity, -23.5˚ in the winter solstice, and 0˚ in the vernal equinox and autumn equinox. Therefore, in Korea, where the latitude is about 37.5˚, the seasonal south-mid elevation is as follows.

Spring equinox (Spring, March): 90˚-37.5˚ + 0 = 52.5˚

Lower Summer (June): 90˚-37.5˚ + 23.5˚ = 76˚

Autumn (September, September): 90˚-35˚ + 0˚ = 52.5˚

Winter Solstice (Winter, December): 90˚-37.5˚ -23.5˚ = 29˚

Therefore, the height of the lower half of winter, winter, and sun is 47 degrees away, so the solar panel is at right angles to the sun's light to receive the sun's light best, and 90˚-76˚ = 14˚ when it is inclined from the ground. It is 90˚-29˚ = 61˚ in winter solstice, and 90˚-52.5˚ = 37.5˚ in spring and autumn.

In other words, in Korea, which corresponds to 37.5 degrees north latitude, the inclination angle of the solar panel from the ground can be fixed at 14 degrees when it is winter, 61 degrees when it is lower, and 37.5 degrees when it is the spring and autumn.

2 is a configuration diagram of a rotation control device of the solar cell module according to the change in the solar altitude of the season, Figure 3 is a perspective view of the solar altitude sensing device in the rotation control device of the solar cell module according to the seasonal change in solar altitude, 4A and 4B are exploded perspective views of a solar altitude sensing device in a rotation control apparatus of a solar cell module according to seasonal solar altitude change of the present invention, and FIG. 5 is a rotation of the solar cell module according to seasonal solar altitude change of the present invention. 6 is a plan view of a rotation control device of a solar cell module according to seasonal solar elevation change of the present invention, and FIG. 7 is a solar cell according to seasonal solar elevation change of the present invention. The circuit diagram of the control device in the rotation control device of the module.

That is, one side of the solar panel 10 is provided with a solar altitude sensing device 100 for sensing the south-mid height of the seasonal sun and outputs an electrical signal, the control device for outputting the signal from the solar altitude sensing device 100 Received at 20 to drive the motor unit 30 is rotated to maintain the solar panel 10 optimally with seasonal solar altitude.

The solar altitude sensing device 100 includes an assembly 50, a proximity sensor unit 70, a horizontal holding weight 60, and a cover 80.

The assembly 50 of the solar altitude sensing device 100 is formed with a space therein and has a body 51 formed in a semicircular shape on the upper side, and the first to fifth solar inflows are provided in the upper hemispherical shape of the body 51. The first to fifth sense installation portions 52a to 52e having grooves 53a to 53e are formed at equal intervals, and the first to fifth solar inflow grooves 53a to 53e have sunlight of constant illuminance. When received, the first to fifth optical sensors 54a to 54e for outputting electrical signals are provided.

The proximity sensor unit 70 is provided with a body 71 is formed with a coupling hole 77 for coupling to the inner surface of the assembly 50, the first side to the fifth close to one side of the body 71 Sensors 72 to 76 are configured to be installed at regular intervals.

The horizontal maintenance weight 60 is the hinge 63 introduced into the coupling hole 77 is installed at one end and is always maintained perpendicular to the ground by the load and the first to fifth proximity sensor 72 ~ A fan-shaped body 61 for pressing the 76 is provided, and an incision groove 62 for releasing the pressurization of the first to fifth proximity sensors 72 to 76 is formed at the lower center portion of the body 61. Has become a configuration.

The cover 80 is combined with the assembly 50 to form the same shape as the inner space of the assembly 50 to prevent exposure of the proximity sensor unit 70 and the horizontal holding weight 60.

The control device 20 has first to fifth optical sensors 54a to 54e connected in parallel, and the first to fifth relays are connected to the output terminals of the first to fifth optical sensors 54a to 54e. RY1 to RY5 are connected, and the seventh and eighth relays RY8 (RY10) and the first and fifth proximity sensors 72 and 76 are connected to the parallel connection ends of the first to fifth optical sensors 54a to 54e. Are connected in parallel, respectively.

In addition, second and fourth proximity sensors 73 and 75 are connected to the other end of the seventh and eighth relays RY8 and RY10, and one end of the third proximity sensor 74 is sixth. The relay switch RSW6 is connected, and a ninth relay RY9 is connected to the other end of the first and fifth proximity sensors 72 and 76.

The eleventh relay switch RSW11 and the tenth relay RY10 are connected in series to the parallel connection ends of the first to fifth optical sensors 54a to 54e, and are connected to the first to tenth relays RY1 to RY10. The first, second, fourth, seventh, and eighth relay switches RSW1, RSW2, RSW4, RSW7, and RSW8 that are controlled by the magnet switch MSW1 and MSW2 that control the motor 31 are controlled. Is connected to the configuration.

10: solar panel 20: control device
30: motor unit 31: motor
50: assembly 51: body
52a to 52e: first to fifth sense installation unit
53a ~ 53e: 1st to 5th solar inflow groove
54a to 54e: first to fifth optical sensors
60: horizontal holding weight 61: body
62: incision groove 63: hinge
70: proximity sensor unit 71: body
72 to 76: first to fifth proximity sensor 77: coupling hole
100: solar altitude sensing device
RY1 to RY10: First to tenth relays
RSW1 to RSW11: first to eleventh relay switches
MSW1, MSW2: Magnetic Switch

Claims (2)

By driving the motor unit 30 in the control device 20 by a signal output from the solar altitude sensing device 100 sensing the seasonal solar altitude change, the solar panel 10 is rotated according to the seasonal solar altitude change to generate power generation efficiency. In the rotational control device of the solar cell module according to the seasonal change in solar altitude to increase,
The solar altitude sensing device 100,
The interior 51 is formed as a space and the upper side is provided with a body 51 consisting of a semi-circle, the upper hemispherical shape of the body 51, the first to fifth sense in which the first to fifth solar inflow grooves (53a ~ 53e) is formed Installation parts 52a to 52e are formed at equal intervals, and the first to fifth light beams output electrical signals when sunlight having a constant illuminance is received in the first to fifth solar inflow grooves 53a to 53e. An assembly 50 in which sensors 54a to 54e are installed;
Body 71 is provided with a coupling hole 77 for coupling to the inner surface of the assembly 50, the first to fifth proximity sensors 72 to 76 on one side of the body 71 Proximity sensor unit 70 is formed at a predetermined interval,
The hinge 63 introduced into the coupling hole 77 is installed at one end portion, and is always in a vertical state by a load, and has a fan shape for pressing the first to fifth proximity sensors 72 to 76. The body 61 is provided, the horizontal maintenance weight 60 is formed in the lower central portion of the body 61 is formed with a cutting groove 62 for releasing the pressure of the first to fifth proximity sensors 72 to 76 Wow,
Rotating the solar cell module according to the seasonal change in solar altitude, characterized in that the cover is provided on the other side of the assembly 50 to prevent the exposure of the proximity sensor unit 70 and the horizontal maintenance weight (60). Control unit. The method of claim 1, wherein the control device 20,
The first to fifth optical sensors 54a to 54e are connected in parallel,
First to fifth relays RY1 to RY5 are connected to each output terminal of the first to fifth optical sensors 54a to 54e.
The seventh and eighth relays RY8 and RY10 and the first and fifth proximity sensors 72 and 76 are connected in parallel to the parallel connection ends of the first to fifth optical sensors 54a to 54e, respectively.
Second and fourth proximity sensors 73 and 75 are connected to the other ends of the seventh and eighth relays RY8 and RY10, respectively.
One side end of the third proximity sensor 74 is connected to the sixth relay switch (RSW6),
The other end of the first and fifth proximity sensors 72 and 76 is connected to a ninth relay RY9,
An eleventh relay switch RSW11 and a tenth relay RY10 are connected in series to the parallel connection ends of the first to fifth optical sensors 54a to 54e.
The first, second, fourth, seventh, and eighth relay switches RSW1, RSW2, RSW4, RSW7, and RSW8, which are interrupted by the first to tenth relays RY1 to RY10, may be motorized. 31) The rotation control device of the solar cell module according to the seasonal change in solar altitude, characterized in that it is connected to the magnet switch (MSW1) (MSW2) for controlling.

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