KR20230012163A - Double-sided photovoltaic power generation system installed in salt field - Google Patents

Abstract

The present invention comprises: at least two inclined double-sided light-receiving solar panels spaced apart from each other by a predetermined interval; a frame installed on the bottom of a salt pond and supporting each of the double-sided light-receiving solar panels; and a reflection plate located between adjacent solar panels and configured to move up and down by buoyance of salt water according to a water level of the salt pond by using the frame as a guide. Due to this, it is possible to immediately respond to a change in the water level of the salt pond to enable constant power generation regardless of presence or absence of salt water, turbidity of salt water, or a salt concentration.

Description

Salt type double-sided photovoltaic power generation system {Double-sided photovoltaic power generation system installed in salt field}

The present invention relates to a salt type solar power generation system.

Salt farms have location conditions with abundant sunlight and wind for salt production, and are optimal for photovoltaic power generation, so many photovoltaic power generation facilities are being installed.

For example, in Korea Patent Publication (10-2020-0124979, hereinafter referred to as "prior art"), the solar panel is composed of two types of upper solar panel and lower solar panel, and the upper solar panel blocks direct sunlight. It is installed in the receiving direction, and the lower solar panel is installed to absorb the light (reflected light) reflected by the salt water as much as possible. In addition, during the salt production period, the angle is determined by considering the angle of light reflected from salt water, and the angle of the lower solar panel is adjusted when the salinity is lower than the reference value. As a result, during the period when the salt farm is not operated, solar power generation is increased instead of salt production, and during the period when the salt farm is operated, solar power generation is increased by absorbing not only direct sunlight but also reflected light from salt water.

However, while the salt farm is operating, the water level of the salt farm continues to change, and the turbidity and salt concentration of salt water also continuously change. It is very difficult to continuously adjust the angle of the lower solar panel in response to this. In addition, since there is no reflected light by the salt water during the period when the salt farm is not operated, the power generation efficiency is significantly reduced.

Korea Patent Publication (10-2020-0124979)

An object of the present invention is to provide a salt-type double-sided photovoltaic power generation system that can solve the above problems.

The salt-type double-sided photovoltaic power generation system for achieving the above object,

at least two inclined double-sided light-receiving solar panels spaced apart from each other;

a frame installed on the bottom of the salt pond and supporting each of the double-sided light-receiving solar panels; and

It is located between adjacent solar panels and includes a reflector that moves up and down by the buoyancy of salt water according to the water level of the salt pond using the frame as a guide.

Since the present invention uses a double-sided photovoltaic solar panel, it is possible to generate power not only from the front solar panel but also from sunlight reflected to the rear solar panel by the reflector, resulting in high power generation efficiency.

In the present invention, since sunlight is reflected to the rear surface of the double-sided light-receiving solar panel by the reflector regardless of the presence or absence of salt water, salt water turbidity, and salt concentration, power generation efficiency is high.

In the present invention, even during a period when the salt farm is not operated, sunlight can be reflected to the rear solar panel by the reflector, so the power generation efficiency is still high.

In the present invention, since the reflector automatically moves up and down according to the water level of the salt pond by buoyancy, the angle of sunlight reflected by the reflector is automatically adjusted according to the water level of the salt pond. Due to this, it is possible to respond immediately to changes in the water level of the salt farm, and constant power generation is possible regardless of the presence or absence of salt water, turbidity of salt water, and salt concentration.

According to the present invention, by folding the reflector and adjusting the angle of sunlight reflected by the reflector, it is possible to increase the rear power generation amount.

1 is a view showing a salt-type double-sided photovoltaic power generation system according to a first embodiment of the present invention.
2 is a view showing a state in which the salt pond level rises and the reflector rises.
FIG. 3 is a plan view of the reflector shown in FIG. 1 .
4 is a side view of the reflector shown in FIG. 1;
5 is a view showing a salt-type double-sided photovoltaic power generation system according to a second embodiment.
FIG. 6 is a plan view of the reflector shown in FIG. 5 .
FIG. 7 is a view showing a state in which the reflector shown in FIG. 6 is folded upward.

Hereinafter, a salt-type double-sided photovoltaic power generation system according to a first embodiment of the present invention will be described in detail. Reference numeral A denotes a salt farm, B denotes salt water, and C denotes sunlight.

As shown in FIG. 1, the salt-type double-sided receiving solar power generation system 1 according to the first embodiment of the present invention is composed of double-sided receiving solar panels 11, a frame 12, and a reflector 13. do.

[Double-sided receiving solar panel (11)]

The double-sided light-receiving solar panel 11 is a solar cell that generates power from both sides. The double-sided light-receiving solar panels 11 are composed of at least two. The double-sided light-receiving solar panels 11 are spaced apart at regular intervals in the horizontal direction. The number of double-sided light-receiving solar panels 11 and the distance between them may vary depending on the target amount of power generation, the area of the salt field A, and the incident angle of sunlight. Since the double-sided photovoltaic solar panel 11 capable of generating power from both sides is used, not only the front solar panel but also sunlight reflected by the reflector 13 to the rear solar panel can generate electricity.

[frame(12)]

The frame 12 is installed on the bottom of the salt pond and supports each of the double-sided light-receiving solar panels 11 . Frame 12 may vary in number and shape.

solar tracker

The direction of the double-sided light-receiving solar panel 11 can be adjusted according to the position of the sun, and for this purpose, a sun tracking device or the like may be installed at a joint between the double-sided light-receiving solar panel 11 and the frame 12 .

Adjusting the inclination angle of the double-sided light-receiving solar panel (11)

On the other hand, a sensor (ultrasonic sensor, laser sensor, etc.) capable of measuring the rising height of the reflecting plate 13 and a device capable of adjusting the inclination angle of the double-sided light-receiving solar panel 11 according to the rising height of the reflecting plate 13 are further developed. can be put These devices can be variously configured with known technologies such as motors, frames, ball screws, and air cylinders.

Due to these sensors and devices, the angle of inclination of each of the double-sided light-receiving solar panels 11 can be adjusted in real time according to the rising height of the reflector 13 to an angle at which reflected light can be maximally received.

For example, when the reflector 13 rises and approaches the double-sided light-receiving solar panel 11, the inclination angle of the double-sided light-receiving solar panel 11 is made gentle, and the reflector 13 descends so that the double-sided light-receiving solar panel 11 and If it is farther away, the inclination angle of the double-sided photovoltaic solar panel 11 can be increased. Of course, the method for adjusting the inclination angle of the double-sided light-receiving solar panel 11 may vary.

[Reflector (13)]

The reflector 13 is positioned between adjacent solar panels 11 . The reflector 13 moves up and down by the buoyancy of the salt water according to the water level of the salt pond using the frame 12 as a guide. Due to the reflector 13, sunlight can be reflected to the rear surface of the double-sided photovoltaic panel regardless of the presence or absence of salt water, turbidity of salt water, or salt concentration.

Therefore, as in the prior art, during the salt production period, it is not necessary to determine the angle in consideration of the reflected light angle for salt water, and to adjust the angle of the lower solar panel when the salinity is lower than the reference value.

reflective layer

A reflective layer is formed on the upper surface of the reflector 13 . To form the reflective layer, a water-based paint containing titanium oxide (TiO ₂ ) and glass beads 13b is applied to the upper surface of the reflective plate 13 . Titanium oxide (TiO ₂ ) diffusely reflects more than 85% of sunlight (L) in a wavelength range of 380 to 1100 nm, increasing the amount of power generation of the double-sided photovoltaic solar panel 11 by more than 30%. The glass beads 13b increase the diffuse reflectance of the reflective layer.

In order to avoid complicating the drawing, illustration of the reflective layer is omitted in FIG. 3, and only the glass beads 13b are shown in FIG. 4.

opening 13a

As shown in FIG. 3 , openings 13a are formed at regular intervals at the corners of the reflector 13 . The opening 13a is inserted into the frame 12. Due to the opening 13a having one side open, it is possible to easily remove the reflecting plate 13 from the frame 12 or insert the opening 13a into the frame 12 by lifting the reflecting plate 13 at an angle. The number and spacing of the openings 13a may vary.

As shown in FIGS. 1 and 2 , the reflector 13 moves up and down by the buoyancy of the salt water according to the water levels H1 and H2 of the salt pond using the frame 12 as a guide. Due to this, the reflection angle of sunlight is automatically adjusted according to the water level of the salt pond.

Since salt water has a density of 1.024 to 1.030 g/cm 3 , the density of the reflector 13 must be smaller than that of the salt water in order for the reflector 13 to float. To this end, the reflector 13 is made of a plastic material having a lower density than salt water.

polyethylene reflector

For example, the reflector 13 is made of polyethylene having a density of 0.88-0.96 g/cm 3 , which is less dense than saline water.

Glass fiber reinforced plastic reflector

Meanwhile, in order to increase the strength and corrosion resistance of the reflector 13, the reflector 13 may be made of glass fiber reinforced plastic in which polyethylene is used as a matrix and glass fibers are dispersed on the matrix.

Glass and carbon fiber composite reinforced plastic reflector

Meanwhile, in order to reduce friction with the frame 12 when the reflector 13 moves up and down, carbon fibers having self-lubricating properties may be disposed only on the inner circumferential surface of the opening 13a.

In this case, the reflector 13 may be made of glass and carbon fiber composite reinforced plastic in which polyethylene is used as a matrix, glass fibers are dispersed on the matrix, and carbon fibers are disposed only on the inner circumferential surface of the opening 13a.

Of course, carbon fibers having properties superior to those of glass fibers may be dispersed on the matrix instead of glass fibers, but carbon fibers are disposed only on the inner circumferential surface of the opening 13a where self-lubrication is essential due to the increase in cost.

Hereinafter, a salt-type double-sided photovoltaic power generation system according to a second embodiment of the present invention will be described in detail.

As shown in FIG. 5, the salt-type double-sided photovoltaic power generation system 2 according to the second embodiment of the present invention is the same as the first embodiment except that the reflector 23 can be folded up and down. Do. The same reference numerals are attached to the same components.

Hereinafter, the reflector 23 differentiated from the first embodiment will be described.

As shown in FIG. 6 , openings 23a are formed at regular intervals at the corners of the reflector 23 .

Since the function of the opening 23a is the same as that of the opening 13a in the first embodiment, its description is omitted.

[Reflector (23)]

The reflector 23 is made of plastic (polyethylene), glass fiber reinforced plastic, glass and carbon fiber composite reinforced plastic, which can float in salt water. Since the details have been described above, the description thereof will be omitted.

Folding part (23b)

A folded portion 23b is formed in the center of the reflector 23 . The reflector 23 may be folded up and down around the folded portion 23b. For this reason, it is possible to manually adjust the sunlight reflection angle of the reflector 23 by folding the reflector 23 up and down.

As shown in Fig. 7, the folded portion 23b is composed of a rack 23d on a pinion 23c. Due to this, the folded state may be maintained as it is. That is, since the operator can fold and unfold the reflector 23 only when appropriate force is applied, the self-folding or unfolding of the reflector 23 can be prevented. The force of folding or unfolding the reflector 23 is appropriately adjusted to the depth at which the mount of the pinion 23c enters the valley of the rack 23d.

The deeper the depth, the more force the mountains go over the valleys, so more force goes into folding or unfolding the reflector 23. It takes less force to unfold.

If the second embodiment is used, the solar reflection angle is automatically adjusted while the reflector 23 rises up and down according to the water level of the salt pond, and the angle of the reflector 23 can be further manually adjusted, so that the solar reflection angle It is possible to further increase the power generation efficiency by finely adjusting the degree.

Adjusting the inclination angle of the double-sided light-receiving solar panel (11)

In the second embodiment, as in the first embodiment, a sensor capable of measuring the rising height of the reflector 13 on the frame 12 and the angle of the double-sided light-receiving solar panel 11 according to the rising height of the reflector 13 You can put more devices that can adjust the . As a result, the inclination angle of each of the double-sided light-receiving solar panels 11 is adjusted in real time to an angle at which the reflected light can be maximally received according to the rising height of the reflector 23 and the solar reflection angle of the reflector 23, thereby generating electricity. Efficiency can be further increased.

How to detach the frame 12 of the reflector 23

On the other hand, if the second embodiment is used, the reflector 23 can be easily removed from the frame 12 by folding the reflector 23, and the reflector 23 is placed between the frames 12 in a folded state. After positioning and unfolding, the opening 23a can be easily inserted into the frame 12. Therefore, installation of the reflector 13 is easier than in the first embodiment.

That is, when a worker is working on collecting salt collected at the bottom of the salt farm, the reflector 13 can be quickly removed from the frame 12 so as not to interfere with the work, and after the work is over, the frame 12 can be quickly removed. It is possible to install the reflector 13 on.

1,2: Salt-type double-sided photovoltaic power generation system
11: double-sided light-receiving solar panel 12: frame
13,23 Reflector 13a,23a Opening
A: salt farm B: salt water
C: sunlight

Claims (5)

at least two inclined double-sided light-receiving solar panels spaced apart from each other;
a frame installed on the bottom of the salt pond and supporting each of the double-sided light-receiving solar panels; and
A salt-type double-sided photovoltaic power generation system, characterized in that it includes a reflector that is positioned between neighboring solar panels and moves up and down by the buoyancy of salt water according to the water level of the salt pond using the frame as a guide. The method of claim 1, wherein the reflector is made of plastic having a lower density than salt water, and a reflective layer is formed on an upper surface of the reflector,
The reflective layer is a salt-type double-sided photovoltaic power generation system, characterized in that formed by applying a water-based paint containing titanium oxide (TiO ₂ ) and glass beads to the upper surface of the reflective plate. The salt-type double-sided photovoltaic power generation system according to claim 2, wherein the reflector is made of polyethylene. The salt-type double-sided photovoltaic power generation system according to claim 3, wherein glass fibers are dispersed in the reflector. The salt-type double-sided photovoltaic power generation system according to claim 1, wherein a folded portion is formed in the center of the reflector so that the reflector can be folded up and down around the folded portion.

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