KR20130098586A - Buoyant type solar power generation apparatus - Google Patents

Abstract

The present invention includes a plurality of supports fixed to the ground spaced apart a considerable distance; One or more fixing wires connected between the support and the support; A plurality of first buoyancy members coupled to the fixed wire and having a buoyancy force; At least one solar cell module coupled to and supported by the fixing wire; It relates to a floating photovoltaic device comprising a. According to the present invention, it is possible to provide a floating photovoltaic device having a simple structure that can easily install a solar cell module in the water or underwater.

Description

Floating Solar Power Plant {BUOYANT TYPE SOLAR POWER GENERATION APPARATUS}

The present invention relates to a photovoltaic device installed in a pond, a lake, a river or the sea, and more particularly, the position of the solar cell module or the position of the solar cell module due to weather deterioration such as a typhoon or a strong wind, the titration of the solar cell module Floating solar which can prevent the damage of solar cell module by adjusting temperature and angle of solar cell module, maintain proper temperature of solar cell module, maximize solar power incident on solar cell module and maximize power generation efficiency It relates to a photovoltaic device.

The present invention relates to a photovoltaic device installed in a pond, a lake, or the sea.

As a background technology of the present invention, as disclosed in Korean Patent Registration No. 10-1042728, various heavy support frames and supporting structures are used to enable the solar cell module to be supported by typhoons or strong winds. Structure.

In addition, it is impossible to adjust the position of the solar cell module or the surface of the water and the structure of the solar cell module and the surface is impossible to adjust the angle.

Such a conventional floating solar power generation device has a problem that an excessive cost is required for its installation as a structure in which an excessive structure is to be used.

In addition, there is a problem that the solar cell module can be easily damaged due to bad weather.

In addition, there is a limit to the angle control of the solar cell module, there is a problem that the power generation efficiency of the solar cell module is reduced as a structure that can not maintain the proper temperature of the solar cell module.

In addition, gas, such as air, exists in the terminal box constituting the solar cell module, and the gas outside the terminal box enters into the air as the volume of the gas repeats expansion and contraction due to the difference in temperature between day and night. Moisture that has been accumulated in the terminal box is easily generated short-circuit or electrical corrosion in the terminal box is a cause of failure and shorten the life of the solar cell module.

In addition, the material constituting the surface of the solar cell module is covered with tempered glass having a greater specific gravity than water, and the edge of the solar cell module is reinforced with a metallic material having a specific gravity greater than water for the purpose of reinforcing the structural rigidity of the solar cell module. Since the structure is heavier than water, there is a problem in that the solar cell module has to work carefully to prevent the solar cell module from sinking and being lost during installation or maintenance work.

An object of the present invention devised to solve the above problems is to simplify the installation structure so that the buoyancy by the buoyancy member is provided to the fixed wire to which the solar cell module is coupled so that the solar cell module can be easily installed on the surface or underwater. It is to provide a floating photovoltaic device.

In addition, another object of the present invention is to adjust the tension of the fixing wire to which the solar cell module is coupled by the tension regulator by the expansion and contraction of the fixed wire due to the water level change and temperature change according to various weather changes or of the solar cell module In order to provide a floating photovoltaic device that appropriate tension can be applied to the solar cell module in response to the weight and the like.

In addition, another object of the present invention to provide a floating photovoltaic device that is connected to one end of the fixed wire to which the solar cell module is coupled to the water flow tensioner to maintain the tension of the fixed wire without a separate power or equipment. to be.

In addition, another object of the present invention includes a buoyancy support connected to the support by the first support wire, a second support wire connected between the buoyancy support and the buoyancy support and coupled to the solar cell module is easy to install and solar cells This is to provide a floating solar power generator that can stably install the module.

In addition, another object of the present invention consists of a plurality of compartments each of which can be adjusted buoyancy independently of the inside of the buoyancy support to adjust the position of the solar cell module and the surface of the water or underwater, such as typhoons or strong winds Prevents damage to the solar cell module by adjusting the position of the solar cell module in water or water, the proper temperature of the solar cell module, and the angle of the solar cell module due to bad weather, and maintains the proper temperature of the solar cell module. It is to provide a floating photovoltaic device that maximizes the solar light incident on the battery module to maximize the power generation efficiency.

In addition, another object of the present invention is to fill the inside of the terminal box with an insulating material to remove the gas such as air present in the terminal box to prevent the accumulation of moisture in the terminal box in advance to prevent electrical corrosion or It is to provide a floating photovoltaic device that prevents leakage due to moisture accumulation and maintains the performance of the terminal box continuously.

In addition, according to the present invention by attaching an auxiliary float floating in the water on the bottom or side of the solar cell module to provide a solar cell module in which part or all of the solar cell module floats in water when installation or maintenance work It prevents the solar cell module from sinking below the water surface and prevents it from being lost. It also provides a structure that absorbs collision energy applied between the solar cell modules to prevent damage to the solar cell module. It is to provide a solar cell module that can be tilted.

According to a feature of the present invention for achieving the above object, the present invention comprises a plurality of supports fixed to the ground spaced apart a considerable distance; One or more fixing wires connected between the support and the support; A plurality of first buoyancy members coupled to the fixed wire and having a buoyancy force; At least one solar cell module coupled to and supported by the fixing wire; .

At this time, the fixing wire is characterized in that a plurality of second buoyancy member having buoyancy is coupled in the longitudinal direction of the fixing wire.

In addition, it is characterized in that it further comprises a tension regulator coupled to one side of each of the fixing wire is connected to the support to wound or unwind the fixing wire and adjust the tension of the fixing wire.

In addition, the interior of the first buoyancy member is composed of a plurality of compartments that are spaces closed to each other, each of the plurality of compartments, the pump for allowing the outside water to flow into the inside or out the water to the outside; It is characterized in that the air inlet is provided so that the air inside the outside or the outside air flows into the inside.

According to another feature of the present invention for achieving the object as described above, the present invention comprises: at least one support fixed to the ground; At least one fixing wire having one end connected to the support; A flowing tension unit coupled to the other end of the fixing wire and formed radially bent from one side to the other side of the fixing wire; A plurality of first buoyancy members coupled to the fixed wire and having a buoyancy force; At least one solar cell module coupled to the fixed wire; .

At this time, the fixing wire is characterized in that a plurality of second buoyancy member having buoyancy is coupled in the longitudinal direction of the fixing wire.

According to another feature of the present invention for achieving the above object, the present invention comprises a plurality of supports fixed to the ground spaced apart a considerable distance; A plurality of buoyancy supports arranged to be spaced apart a considerable distance from the position between the supports; One side is connected to the support and the other side is the first support wire connected to the buoyancy support; A plurality of second support wires connected between the buoyancy support and the buoyancy support; And a plurality of solar cell modules supported by the plurality of second support wires. .

At this time, one end and the other end of each of the plurality of second support wires is characterized in that the tension is provided by being connected to the weight.

In addition, at least one of the plurality of buoyancy support is provided with a control rod capable of adjusting the height, at least one of the plurality of second support wires is characterized in that connected to the control rod to adjust the height.

In addition, the buoyancy support inside is composed of a plurality of compartments that are spaces closed to each other, each of the plurality of compartments, the pump to let the outside water into or out of the water inside, and the air inside Is characterized in that it is provided with an air outlet for outflow or the outside air flows into the inside.

In addition, the inside of the terminal box included in the solar cell module is characterized in that it is filled with an insulating material (充 塡).

At least one auxiliary buoyancy body having buoyancy is attached to a bottom or side of the solar cell module.

At least one auxiliary float having buoyancy is attached to a bottom or side of the solar cell module.

According to the present invention as described above, it is possible to provide a floating photovoltaic device having a simple structure that can easily install a solar cell module in the water or underwater.

In addition, according to the present invention can provide a floating photovoltaic device that can be applied to the solar cell module with an appropriate tension in response to various weather changes or the weight of the solar cell module.

In addition, according to the present invention can provide a floating photovoltaic device that can maintain the tension of the fixing wire to which the solar cell module is coupled without a separate power or equipment.

In addition, according to the present invention can provide a floating photovoltaic device that is easy to install and stably install the solar cell module.

According to the present invention, the solar cell module may be damaged by adjusting the position of the solar cell module in the water or the water due to a bad weather such as typhoon or strong wind, adjusting the proper temperature of the solar cell module and the angle of the solar cell module. It is possible to provide a floating photovoltaic device that can prevent, maintain the proper temperature of the solar cell module, and maximize the solar light incident on the solar cell module to maximize the power generation efficiency.

In addition, according to the present invention it is possible to prevent the accumulation of moisture generated in the terminal box attached to the solar cell module in advance to prevent the electrical leakage or electrical leakage in the terminal box to maintain the performance of the terminal box continuously Floating photovoltaic device can be provided.

In addition, according to the present invention by attaching the auxiliary buoyancy body floating on the bottom or side of the solar cell module to prevent the solar cell module sinks below the water surface during installation or maintenance work, and applied to the solar cell module It is possible to provide a solar cell module in which the damage caused by the crash is prevented and the solar cell module is inclined according to the incident angle of sunlight.

1 to 3 is a block diagram showing the configuration of a floating solar cell apparatus according to a first embodiment of the present invention.
Figure 4 is a block diagram showing the configuration of a floating photovoltaic device according to a second embodiment of the present invention.
5 is a configuration diagram showing the configuration of a floating solar cell apparatus according to a third embodiment of the present invention.
6 is an exemplary view for showing that the buoyancy support is connected to the support 20 fixed to the ground.
FIG. 7 is a view for illustrating a configuration in which two pairs of second support wires 35 are installed in the buoyancy support 70.
8 is an exemplary view of the configuration of the adjusting rod (80).
9 is an exemplary view showing the configuration of the buoyancy support.
10 is a perspective view illustrating the bottom of the solar cell module.
11A and 11B are photographs showing the actual inside of a general terminal box.

The details of other embodiments are included in the detailed description and drawings.

Advantages and features of the present invention and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings.

The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, the present invention will be described with reference to the drawings for explaining the floating solar cell apparatus according to embodiments of the present invention.

1 to 3 is a block diagram showing the configuration of a floating solar cell apparatus according to a first embodiment of the present invention.

1 to 3, the floating photovoltaic device according to the first embodiment of the present invention is connected between the support 20 and the plurality of support 20 is fixed to the ground at a considerable distance apart At least one fixed wire 31 is coupled to, and the plurality of first buoyancy member (40a) coupled to the fixed wire 31 having a buoyancy and one or more solar cell module 10 is coupled to and supported by the fixed wire.

The ground means an underwater surface which is a bottom surface of a pond, a lake, a river or the sea, or an land surface on the water surface.

The support 20 is installed to be fixed at one point and the other point of the ground spaced apart a considerable distance.

At this time, the support 20 may be fixed to one or two or more at one point and the other point of the ground.

The support 20 should be installed so as to be firmly fixed on the ground, for this purpose, a heavy weight that does not sink to the ground (EARTH ANCHOR), reinforced concrete structure or underwater ground as the support 20 And the like can be used.

At this time, the installation of the support using the earth anchor, perforated to the bottom rock of the ground and inserting steel wire to inject cement milk, and then cement is cured and hardened and fixed to the ground by wrapping around the band of steel and applying tension Means that.

The support 20 serves as a support to ensure that the photovoltaic device according to the present invention is stably positioned at a predetermined place from the flow of fluid including wind or running water.

That is, the fixing wire 31 is connected to the support 20, so that the solar module 10 coupled to the fixing wire 31 can be stably supported.

In this case, an additional support 21 may be additionally installed at a point between one point and the other point of the ground. That is, the additional support 21 may be fixed to the ground between the support 20 is fixed to one point and the other point of the ground in the longitudinal direction of the fixing wire 31. This is to allow the fixing wire 31 to be more stably positioned. The fixing wire 31 is additionally connected to the additional support 21 by the auxiliary wire 32 so that the fixing wire 31 is more secure. This is to be able to be located in a stable place.

Both ends of the fixing wire 31 are coupled to the support 20 to be fixed to the ground. In other words, the fixing wire 31 is connected between the support 20 and the support 20.

The solar cell module 10 is coupled to the fixing wire 31, the position is fixed by the support 20 and is provided with buoyancy by the first buoyancy member 40a described later, so that the solar cell module is on the water surface. Can be located in a fixed place.

At this time, the fixing wire 31 may be composed of one or two or more. In particular, when the solar cell module is arranged in a plurality of rows on the fixing wire 31 or when the solar cell module 10 coupled to the fixing wire 31 needs to be more stably supported, or the like. The fixing wire 31 can be installed in the appropriate number of strands.

At this time, the fixing wire 31 is preferably made of a corrosion-resistant material that does not corrode in water or seawater as a linear member such as a rope or wire having a sufficient tensile force.

In addition, as described above, by further connecting the fixing wire 31 with the additional support 21 by the auxiliary wire 32, the position of the fixing wire 31 can be more stably fixed.

The additional support 21 and the auxiliary wire 32 are only different from the support 20 and the fixing wire 31 and its installation position or coupling position, respectively, the shape or the material corresponds to the same configuration.

The first buoyancy member (40a) is a buoyancy body that is coupled to the fixed wire 31 as a hollow hollow structure. That is, the first buoyancy member 40a provides buoyancy to allow the fixing wire 31 to which the solar cell module 10 is coupled to float on the water surface.

In this case, the first buoyancy member 40a may be coupled to both sides of a portion where the solar cell module 10 is coupled to the fixing wire 31. However, according to the length of the fixed wire 31 or the number or weight of the solar cell modules 10 coupled to the fixed wire 31, the first buoyancy member 40a may be a portion of the solar cell module 10 coupled thereto. It may be additionally installed between the sides and the solar cell module 10.

The first buoyancy member 40a may be formed in various shapes having buoyancy due to internal spaces formed therein, and the fixing wire 31 may be coupled to be seated on the first buoyancy member 40a.

At this time, the inner space of the first buoyancy member (40a) is preferably made of a plurality of compartments sealed to each other.

At this time, each of the compartments inside the first buoyancy member (40a), a pump for introducing external water into or out of the water inside, and the air inside each compartment according to the operation of the pump outside It is preferable that an air inlet connected to an air pipe consisting of a pipe or a tube is provided such that the upper end always protrudes above the water so that the air flows out or the outside air flows into the inside.

That is, the interior of the first buoyancy member (40a) is composed of a plurality of compartments, each compartment is provided with a pump to introduce external water into the interior or the internal water into the outside, and at the same time has an air inlet The inner air is introduced into the inside or the outside air is introduced into the inside, so that the buoyancy of the first buoyancy member 40a can be adjusted.

By adjusting the buoyancy of the first buoyancy member 40a, the fixed wire 31 and the solar cell module 10 coupled to the fixed wire 31 can adjust the vertical position between the water surface and the water.

Since the specific structure of the compartment inside the first buoyancy member 40a is the same as the buoyancy support 70 of the third embodiment of the present invention, a detailed description thereof will be provided in the description of the buoyancy support 70. It will be described later.

The solar cell module 10 is coupled on the fixed wire 31 as a means for converting solar energy into electrical energy.

In this case, when the fixing wire 31 is composed of one, only one side of the solar cell module 10 is coupled to and supported on the fixing wire 31, and when the fixing wire 31 is formed of a plurality of solar cell modules ( One side and the other side of the 10 may be coupled to the fixing wire 31 together to be supported.

The configuration in which the solar cell module 10 is coupled to the processing wire 31 may be combined by various existing coupling connection methods, and a detailed description thereof will be omitted since it is already known.

A plurality of second buoyancy members 40b having buoyancy may be coupled to the fixing wire 31 in the longitudinal direction of the fixing wire 31 (see FIGS. 2 and 3).

That is, the second buoyancy member 40b is installed in the longitudinal direction on the fixing wire 31 to which the solar cell module 10 is coupled.

At this time, the bottom surface of the solar cell module 10 may be coupled to the second buoyancy member (40b).

The self-weight of the fixed wire 31 by the second buoyancy member 40b and the weight of the solar cell module 10 coupled to the fixed wire 31 may compensate the sagging of the fixed wire 31 in water. To help.

The second buoyancy member 40b provides individual buoyancy to each of the solar cell modules 10 coupled to the fixing wire 31 so that the solar cell module 10 can rise more stably on the water surface.

At this time, the interior of the second buoyancy member (40b) may be composed of a plurality of compartments, each compartment is provided with a pump and an air inlet, therein to have a buoyancy corresponding to the buoyancy of the first buoyancy member (40a) The amount of water to air filled can be controlled. The description thereof will be described later in the description of the buoyancy support 74 forming the third embodiment of the present invention together with the first buoyancy member 40a.

As shown in FIG. 3, the floating photovoltaic device according to the first embodiment of the present invention includes a roller that winds or unwinds the fixing wire 31 at any one side or the other side of the fixing wire 31. The tension regulator 50 may further include a function.

In the state in which one end of the fixing wire 31 is fixedly connected to the support 20, only the other end of the fixing wire 31 is wound or released by the tension controller 50 so that the tension of the fixing wire 31 is adjusted. Can be.

At this time, the tension regulator 50 is connected to the support 20 by a connecting wire 33, the fixing wire 31 is wound or released by the tension regulator 50, the tension regulator ( 50).

That is, by configuring the fixing wire 31 to be connected to the support 20 through the tension regulator 50, the reservoir or river water level, changes in sea level, flow of the flow or wind strength or maintenance needs Accordingly, the tension of the fixing wire 31 can be properly adjusted by adjusting the tension controller 50. In addition, when the buoyancy of the first buoyancy member (40a) is adjusted so that the position of the first buoyancy member (40a) fluctuates up and down between the surface and the water, by adjusting the tension regulator 50 to adjust the fixing wire ( 31) to maintain the tension.

When the tension controller 50 is a manual type, a chain block (CHAIN BLOCK) for adjusting the tension is preferably used by pulling the chain coupled with the fixing wire 31, and electrically, the fixing wire 31 is connected. It is preferable to adjust the tension of the fixing wire 31 by forward rotation or reverse rotation using an electric winch.

Figure 4 is a block diagram showing the configuration of a floating photovoltaic device according to a second embodiment of the present invention.

As shown in FIG. 4, the floating photovoltaic device according to the first embodiment of the present invention includes one or more supports 20 fixed to the ground, and one or more fixing wires having one end connected to the support 20. 31), a water flow tensioner 60 coupled to the other end of the fixing wire 31 and bent radially only one side, and a plurality of first buoyancy members 40a coupled to the fixing wire 31 and having buoyancy; At least one solar cell module 10 coupled to the fixing wire 31 is included.

That is, the second embodiment of the present invention is a configuration in which only one end of the fixing wire 31 is connected to the support 20 and the other end is connected to the water flow tensioner 60, which is distinguished from the first embodiment in this configuration. do.

Therefore, hereinafter, the description of the same configuration as that of the first embodiment will be omitted, and only different configurations will be described.

In the second embodiment of the present invention, as shown in FIG. 4, one end of the fixing wire 31 is fixed to the support 20, and the other end thereof is connected to the water flow tensioner 60 rather than the support 20. It is characterized by.

The flow tensioner 60 is formed such that the resistance to the flow in one direction is greater than the resistance to the flow in the other direction.

In other words, the water flow tensioner 60 is formed in the form of an umbrella or curved V (V) form to the gap (U) shape. That is, the water tension device 60 is formed radially bent from one side to the center, the material of the water tension device 60 is a metal material having excellent corrosion resistance even in water or using a thick cloth of synthetic resin material which is light and tough and strong corrosion resistance. It is preferable.

One end of the fixing wire 31 is connected to the support 20 and the other end is connected to the water flow tensioner (60). At this time, the other end of the fixed wire 31 and the water flow tensioner 60 is a fixed wire connected to the support 20 by the resistance force generated in the water flow tensioner 60 due to the flow of the other end of the fixed wire 31 ( 31 to act away from one end (see FIG. 4).

That is, the resistive force generated in the flowing tensioner 60 is used as the tension required by the fixing wire 31.

The flowing tensioner 60 may replace a separate structure or power for the tension of the fixing wire 31, there is an effect that can simplify the structure of the underwater solar power device.

In the floating photovoltaic device according to the second embodiment of the present invention, the first buoyancy member 40a, the second buoyancy member 40b, the support 20, and the additional support 21 constituting the first embodiment are provided. And the configuration for the fixing wire 31 or the like may be applied as it is (except that one end of the fixing wire is connected to the flowing tensioner unlike in the first embodiment), and the description thereof will be described in detail in the first embodiment. It is the same as one and will be omitted.

5 is a configuration diagram showing the configuration of a floating solar cell apparatus according to a third embodiment of the present invention.

As shown in FIG. 5, the floating photovoltaic device according to the third embodiment of the present invention has a plurality of supports 20 fixed to the ground at a considerable distance from each other, and corresponds to a position between the supports 20. A plurality of buoyancy support 70 disposed to be spaced apart, one side is connected to the support 20 and the other side is the first support wire 34 is connected to the buoyancy support 70 and the buoyancy support 70 ) And a plurality of second support wires 35 connected between the buoyancy support 70 and a plurality of solar cell modules 10 supported by the plurality of second support wires 35.

Since the support 20 corresponds to the same configuration as the support 20 in the first embodiment, description thereof will be omitted.

The buoyancy support 70 is a buoyancy body such as the first buoyancy member 40a in the first embodiment to provide buoyancy for allowing the solar cell module 10 to float on the surface or in the water. Means.

The buoyancy support 70 is coupled to the first support wire 34 and is connected to the support 20. That is, one side of the first support wire 34 is connected to the support 20 and the other side is coupled to the buoyancy support 70.

At this time, the buoyancy support 70 is connected by the second support wire 35 to be spaced apart by a predetermined distance. That is, the second support wire 35 receives buoyancy by connecting between the buoyancy support 70 and the buoyancy support 70 and serves to fix the solar cell module.

In this case, the second support wires 35 are installed in pairs of two, and the solar cell module 10 is coupled to one side and the other side between two pairs of second support wires 35. In this case, two or more pairs of second support wires 35 may be installed, and in this case, the solar cell module 10 may be arranged in two or more rows.

However, an additional second support wire 35 may be further installed between the pair of second support wires 35 to more safely support the solar cell module 10.

One end and the other end of the second support wire 35 may be provided with a tension by being connected to a weight 90 having a predetermined weight.

That is, in a state in which the second support wire 35 is connected between the buoyancy support 70 and the buoyancy support 70, both ends are connected to the weight 90, and the weight 90 is received in the water. Tension is generated in the second support wire 35 by gravity.

The weight 90 is connected to be disposed in the water by the buoyancy of the buoyancy support 70, is a means for maintaining a constant tension on the second support wire (35).

Therefore, the weight 90 is a material having a specific gravity greater than water, and an object having a mass capable of providing a constant tension to the second support wire 35 by gravity. At this time, the weight (90) should be connected to the buoyancy support (70) with an appropriate length so that it is always located in the water without being placed on the ground.

In particular, it should be made of a strong corrosion-resistant material that does not corrode even in sea water, etc., it is preferable to be composed of a corrosion-resistant metal or concrete material.

At this time, the connection of the second support wire 35 and the buoyancy support 70 is not only can be connected using a connecting ring, etc., it is natural that various conventional connection means can be applied.

6 is an exemplary view for showing that the buoyancy support 70 is connected to the support 20 fixed to the ground (2).

In this case, as shown in FIG. 6, both sides of the buoyancy support 70 may be further connected to the ground by the auxiliary wires 36 for the stable arrangement of the buoyancy support 70.

FIG. 7 is a view for illustrating a configuration in which two pairs of second support wires 35 are installed in the buoyancy support 70.

As shown in FIG. 7, the second support wire 35 is connected between the buoyancy support 70 and the buoyancy support 70 by a connecting ring 81, and one end and the other end thereof are connected to the weight 90 so as to be tensioned. Will be maintained.

The second support wire 35 is a means in which two strands form a pair and the solar cell module 10 is coupled and supported therebetween, and may be installed in a plurality of pairs.

When two pairs of second support wires 35 are installed, as shown in FIG. 7, four strands of second support wires 35 are installed, and a solar cell is provided between each pair of second support wires 35. The modules 10 can be arranged in two rows and combined.

Floating photovoltaic device according to a third embodiment of the present invention may be installed on the buoyancy support 70, the adjustment rod 80 to adjust the vertical height of the second support wire 35 (Fig. 5) And FIG. 7).

The adjusting rod 80 adjusts the vertical height of any one of the pair of second support wires 35 to form an angle of the solar cell module 10 (that is, an angle formed by the solar cell module and the water surface or the horizon). Means to control.

That is, the adjustment rod 80 is installed on the buoyancy support 70, and one strand of the pair of second support wires 35 is connected to the upper and lower positions by the adjustment rod 80. By connecting the rear end portion to the weight 90, the angle of the solar cell module 10 coupled between the pair of second support wires 35 may be adjusted.

The control rod 80 may maximize the power generation efficiency of the solar cell module by adjusting the angle of the solar cell module 10 according to the change of season or the altitude of the sun according to the morning and afternoon.

8 is an exemplary view of the configuration of the adjusting rod (80).

As shown in FIG. 8, the adjustment rod 80 includes a base 82 coupled to the buoyancy support 70 and a lower tube 83 connected to the base 82 and the lower tube 83. Inserted from the upper side and includes a top tube 84 is adjusted to protrude upward from the lower tube (83).

In this case, a through hole is formed in the upper end of the upper tube 84 to allow the second support wire 35 to pass therethrough, and a plurality of adjustment holes 85 are provided in the upper tube 84 and the lower tube 83. ) Are formed symmetrically.

In order to allow the upper tube 84 to protrude upward of the lower tube 83 by a set height, the adjusting pin 86 penetrates the adjusting hole 85 of the lower tube 83 and the upper tube 84. By fitting to adjust the overall height of the adjustment rod 80 is also configured to adjust the height of the second support wire 35 through the through hole of the upper tube (84). As a result, the angle of the solar cell module 10 coupled to the second support wire 35 is adjusted.

At this time, the adjustment rod 80 may be used as a manual adjustment rod as shown in Figure 7, as well as a power control (not shown) and the electric control rod can be used to adjust the vertical length up and down by the power unit. The electric control rod may be used in various ways, such as a cylinder type electric control rod, a detailed description thereof will be omitted because it is well known in the art.

9 is an exemplary view showing the configuration of the buoyancy support.

The buoyancy support 70 constituting the third embodiment of the present invention may not only be formed in a hollow cylinder shape, but may also be composed of a plurality of compartments 71 in which interiors are isolated from each other, as shown in FIG. 9. have. As described above, the same may be applied to the case of the first buoyancy member 40a or the like constituting the first embodiment of the present invention.

At this time, the interior of the buoyancy support 70 is composed of compartments 71 which are independent spaces separated from each other by the partition wall, each of the compartments 71 to the water inside each compartment into the compartment interior space or the water inside the compartment It may be provided with a pump 72 that can be discharged to the outside.

At this time, the pump 72 is coupled to the water pipe 73 to allow the water outside the compartment 71 to flow into the compartment or vice versa.

In addition, each compartment 71 may be formed with an air inlet (74) to allow the air inside the outside or the outside air flows into the inside.

At this time, the air outlet portion 74 is connected to the air pipe 75 consisting of a pipe or tube, etc., the upper end of the air pipe 75 is always installed to protrude above the water surface is disposed in the air.

At this time, it is preferable that an opening door 76 is installed at the upper end of the air inlet 74 or the air pipe 75 so as to be opened upon inflow or outflow of air and is normally closed.

The opening and closing door may not only be installed in a manual manner, but also by the driving motor and the driving motor, the opening and closing door may be installed in an electric manner to open or close the upper end of the air entrance 74 or the air pipe 75. It may be. That is, the opening and closing door 76 may be installed so as to be opened and closed by using a valve by a manual or electric method. In this case, a detailed description of the opening or closing door of the electric method or manual method will be omitted since it is well known in the art.

The pump and the air inlet and outlet are installed so that the inflow or outflow of water from the compartments 71 or the inflow or outflow of air is independently performed for each compartment.

That is, by generating the differential of buoyancy for each compartment, the buoyancy support 70 itself can be inclined to one side to adjust the angle of the solar cell module 10.

In addition, by simultaneously increasing or decreasing the buoyancy of each compartment 71, the entire buoyancy support 70 may be located at a predetermined depth below the surface of the water or float above the surface of the water.

This is to adjust the angle of the solar cell module, such as the control rod 80 to maintain the power generation efficiency of the solar cell module to the maximum, and also the possibility of damage to the solar cell module due to the impact of typhoons or strong winds, etc. In order to facilitate the management of the solar cell module 10 by adjusting the buoyancy of the buoyancy support 70 so that the solar cell module 10 is located under the water surface.

In addition, even when the temperature of the solar cell module itself rises as well as preventing damage from typhoons or strong winds, the buoyancy of the buoyancy support 70 is reduced so that the solar cell module 10 is kept under the water surface. Adjust the temperature to lower the temperature of the solar cell module, when the solar cell module 10 is located under the water surface to generate power when the power generation efficiency of the solar cell module is lowered due to deterioration of water quality of the buoyancy support 70 It raises the buoyancy to expose the solar cell module to the surface.

The configuration of the buoyancy support 70 may be equally applied to the first buoyancy member 40a to the second buoyancy member 40b.

By rising or falling of the buoyancy support 70, the weight 90 will also be raised or lowered as well.

The first buoyancy member 40a or the first buoyancy member 40a and the second buoyancy member 40b constituting the first embodiment of the present invention is composed of a plurality of compartments, each of which has a pump and air When the entrance and the like are provided, and the interior of the buoyancy support 70 constituting the second embodiment of the present invention is composed of a plurality of compartments 71 and a pump 72 and an air inlet 74 in each compartment 71. (Including the air pipe 75 and the opening and closing door 76), the operation of the pump and the air entrance (especially when the above-described opening and closing door of the electric system) is controlled automatically, according to the main surface environment The position of the solar cell module 10 may be adjusted. Hereinafter, only the buoyancy support 70 will be described as an example, but this configuration may be equally applied to the first buoyancy member 40a and the second buoyancy member 40b of the first embodiment.

For this operation, the configuration that can be located on the water surface of the configuration of the floating photovoltaic device according to the present invention (for example, the adjusting rod 80 or the second support wire 35 or the solar cell module of the third embodiment) (10) and the like are provided with a wind speed sensor for measuring the wind speed.

In addition, a pressure sensor for measuring the pressure applied to the solar cell module 10 may be further installed in the solar cell module 10, and an angle sensor for measuring the angle of the solar cell module 10 may be further installed. Can be.

At this time, the floating photovoltaic device according to the present invention includes a control unit for controlling the operation of the pump or the door.

That is, when it is necessary to arrange the entire solar cell module 10 below the water surface, the controller controls the pump 72 so that a predetermined amount of water flows into all the compartments 71 of all the buoyancy supports 70. When the solar cell module 10 rises above the water surface, the pump is operated in reverse so that water inside the compartment flows out.

In addition, when it is necessary to adjust the angle of the solar cell module 10, the control unit is the angle so that the solar cell module can be inclined at a predetermined angle by the buoyancy difference of each compartment 71 constituting the buoyancy support 70. The pump 72 of the compartment is operated.

In this case, the controller opens the opening and closing door 76 when the pump 72 is operated to allow the external water to flow into the compartment or the internal water to the outside, and the pump 72 is not operated. There is a control so that the closing door 76 is closed. Since the opening and closing operation of the opening and closing door 76 for the operation of the pump 72 is applied in the same manner below, the description thereof will be omitted.

The controller may be connected to the wind speed sensor and / or the water pressure sensor and / or the angle sensor, and the wind speed, the water pressure, the angle value measured by the wind speed sensor and / or the water pressure sensor, and / or the angle sensor, and the preset appropriate wind speed value. And a microprocessor for comparing the proper hydraulic pressure value and the proper angle value, respectively.

That is, when the wind speed value measured by the wind speed sensor is larger than the appropriate wind speed value preset in the microprocessor, the controller operates a pump in each compartment inside the buoyancy support 70 to draw external water into each compartment. Inflow to and control so that the buoyancy of the buoyancy support 70 is reduced. When the buoyancy of the buoyancy support 70 is lowered down to the surface of the water, the second support wire 35 and the solar cell module 10 coupled to the second support wire 35 are also lowered below the water surface. .

In this case, when the proper pressure value preset in the microprocessor and the pressure value measured by the pressure sensor are equal to each other, the controller stops the operation of the pump so that the buoyancy of the buoyancy support 70 is no longer reduced.

That is, when it is necessary to be positioned below the surface of the water to protect the solar cell module 10 from typhoons or strong winds, the buoyancy of the buoyancy support 70 is adjusted to reduce the buoyancy of the buoyancy support, so that the solar cell module is below the water surface. Can be controlled so as to be disposed at a proper position (that is, a position having a proper hydraulic pressure).

In addition, after a typhoon or strong wind disappears, or after a predetermined time set by the microprocessor, the control unit operates the pump of each compartment in reverse to allow the water inside each compartment to flow out to the outside and the buoyancy support 70 Restore buoyancy). When the buoyancy of the buoyancy support 70 is restored accordingly, the buoyancy support 70 rises in the water direction, and at the same time, the second support wire 35 and the solar cell module also rise.

In this case, the controller controls the opening / closing operation of the opening / closing door so that air may flow into or out of each compartment or compartment through the air inlet and outlet while the pump 72 is operated.

In addition, when the proper angle value of the solar cell module plane set in advance in the microprocessor and the angle value measured by the angle sensor exceeds a predetermined error range set in the microprocessor, the control unit is an angle value of the solar cell module plane And pumps of each compartment so that a difference in buoyancy of each compartment 71 is generated by operating a pump of some compartments 71 of the buoyancy support 70 so that the proper angle value is within an error range. Activate

At this time, the pump of each compartment is controlled so that the buoyancy support 70 is inclined so that the difference between the proper angle value and the angle value measured by the angle sensor is reduced. That is, by controlling the buoyancy of each compartment of the buoyancy support 70 by controlling one side of the buoyancy support 70 to be lowered below the surface of the water, the proper angle value and the angle value measured by the angle sensor are within the error range. The pumps in each compartment are operated to be present.

In this case, the appropriate angle value is preferably set in advance by date and time in the microprocessor.

The solar cell module may further include a temperature sensor for measuring the temperature of the solar cell module, in this case, the microprocessor is set in advance an appropriate temperature range of the solar cell module.

At this time, if the temperature value measured by the temperature sensor exceeds a predetermined temperature range set in advance in the microprocessor, the controller operates the pump of each compartment of the buoyancy support 70 to reduce the buoyancy of the buoyancy support The solar cell module may be positioned at a position having a constant proper pressure value under the water surface.

At this time, the floating photovoltaic device according to the present invention may further include a communication module.

The communication module receives a control signal through wired / wireless communication from a management center capable of managing a device, and the control unit is connected to the communication module to control the buoyancy support 70 according to the control signal received from the communication module. It is possible to control the operation of the opening and closing doors of the pump or air inlet provided in each compartment.

The solar cell module 10 constituting the floating photovoltaic device according to the present invention includes a terminal box.

11A and 11B are actual photographs of terminal boxes generally used.

The terminal box 11 includes wires 12 for drawing power generated from the solar cell to the outside. In addition, the connection conductor for drawing the power produced in the solar cell, and the bypass diode is also composed of a terminal block for connecting the power drawing wire.

At this time, the terminal box constituting the floating photovoltaic device according to the present invention, the basic configuration is the same as the existing terminal box, it is characterized in that it is filled with an insulating material so that air or gas is not contained therein.

That is, the inside of the terminal box 11 is filled with an insulating material such as a silicone resin or an epoxy resin to prevent air from entering and entering the terminal box 11, thereby preventing moisture accumulation in the terminal box. It is possible to prevent the short circuit caused by electrical corrosion or moisture accumulation in the terminal box 11 to prevent the to maintain the performance of the terminal box.

10 is a perspective view illustrating the bottom of the solar cell module.

A plurality of auxiliary floating body 15 may be coupled to the bottom or side surface of the solar cell module constituting the floating photovoltaic device according to the present invention.

At this time, the auxiliary floaters 15 are coupled to the bottom or side of the solar cell module, and the solar cell module is inclined on the water surface in the direction that the most sunlight can be incident on the solar cell module.

That is, according to the present invention by attaching the auxiliary buoyancy body 15 floating on the bottom or side of the solar cell module to prevent the solar cell module sinks below the water surface during installation or maintenance work, or When a collision occurs between adjacent solar cell modules arranged in close proximity to each other, such as waves generated by strong winds or tsunamis, etc., first collide with the auxiliary float 15 attached to the side of the solar cell module. It can absorb energy to prevent damage of solar cell module.

In addition, according to the present invention by varying the size of one or more auxiliary floats 15 attached to the bottom surface of the solar cell module (that is, by varying the buoyancy of each auxiliary float) (for example, solar cell module The upper buoyancy of the large, the lower buoyancy of the () is to be adjusted so that the solar cell module is inclined in accordance with the angle of incidence of sunlight in the water can maximize the power generation efficiency of the solar cell module.

In order to tilt the plane of the solar cell module as described above, the part of the solar cell module that must be positioned at a high position is coupled to a large auxiliary float so that a large buoyancy can be applied, Small auxiliary floats are combined to allow for smaller buoyancy. By the auxiliary floaters 15, the solar cell module is inclined in the direction of incidence of sunlight naturally in the water and the power generation efficiency of the solar cell module is improved.

By generating buoyancy in the solar cell module itself by the auxiliary floating body 15, when the installation or maintenance work for the solar cell module on the water surface, the solar cell module itself floats in water to facilitate the operation. It can be done.

At this time, the auxiliary floating body 15 is preferably a porous synthetic resin material that is light and resistant to corrosion, such as a rubber bag containing air or an air bag made of a synthetic resin material or styrofoam.

In addition, the same wire may be used for the fixing wire, the first supporting wire, the second supporting wire, the connecting wire and the auxiliary wire, and the like is only distinguished in the connection position, function, and the like.

The solar cell module constituting the floating photovoltaic device according to the present invention, when the wave is generated and the water fluctuates up, down, left and right, it flexes flexibly according to the wave caused by the wave, In order to prevent the battery module from being broken or cracked, it is preferable to be a flexible solar cell module.

In addition, the floating photovoltaic device according to the present invention prevents a collision accident with a ship operating near the photovoltaic device at night or in foggy weather, and the ship is close to the floating photovoltaic device. In order to inform, it is preferable that an electric warning light and / or an electric alarm sound generator which is fixed to a buoyancy support or a variable buoyancy support and protrudes above the water surface is installed.

In addition, the floating photovoltaic device according to the present invention is installed on the buoyancy support or the fixed wire to the connection panel (not shown) for collecting the power produced in each solar cell module in one place, collected in the connection panel It is preferable that a power cable connected to the land consuming power is suspended from one side of the fixed wire.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the foregoing detailed description, and all changes or modifications derived from the meaning and scope of the claims and the equivalents thereof are included in the scope of the present invention Should be interpreted.

10: solar cell module 11: terminal box
12: wire 15: auxiliary float
20: support 21: additional support
31: fixed wire 32: auxiliary wire
33: connection wire 34: first support wire
35: second support wire 36: auxiliary wire
40a: first buoyancy member 40b: second buoyancy member
50: tension regulator 60: flow tensioner
70: Buoyancy Support 71: Compartment
72: pump 73: water pipe
74: air entrance 75: air pipe
76: opening and closing door 80: adjusting rod
81: link 82: base
83: lower tube 84: upper tube
85: adjusting hole 86: adjusting pin
90: weight

Claims (12)

A plurality of supports fixed to the ground at a considerable distance from each other;
One or more fixing wires connected between the support and the support;
A plurality of first buoyancy members coupled to the fixed wire and having buoyancy; And
At least one solar cell module coupled to and supported by the fixing wire; Floating photovoltaic device comprising a.
The method of claim 1,
Floating photovoltaic device characterized in that a plurality of second buoyancy member having buoyancy is coupled to the fixed wire in the longitudinal direction of the fixed wire.
The method of claim 1,
And a tension regulator coupled to one side of each of the fixing wires, the tension regulator being connected to the support to wind or loosen the fixing wires and adjust the tension of the fixing wires.
The method of claim 1,
The interior of the first buoyancy member is composed of a plurality of compartments which are spaces closed to each other,
Each of the plurality of compartments,
Floating type, characterized in that it is provided with a pump to allow the outside water to flow into the inside or out the water inside, and an air inlet for allowing the air inside or the outside air flows into the inside Solar power device.
At least one support fixed to the ground;
At least one fixing wire having one end connected to the support;
A flowing tension unit coupled to the other end of the fixing wire and formed radially bent from one side to the other side of the fixing wire;
A plurality of first buoyancy members coupled to the fixed wire and having buoyancy; And
At least one solar cell module coupled to the fixed wire; Floating photovoltaic device comprising a.
The method of claim 5, wherein
Floating photovoltaic device characterized in that a plurality of second buoyancy member having buoyancy is coupled to the fixed wire in the longitudinal direction of the fixed wire.
A plurality of supports fixed to the ground at a considerable distance from each other;
A plurality of buoyancy supports arranged to be spaced apart a considerable distance from the position between the supports;
One side is connected to the support and the other side is the first support wire connected to the buoyancy support;
A plurality of second support wires connected between the buoyancy support and the buoyancy support; And
A plurality of solar cell modules supported by the plurality of second support wires; Floating photovoltaic device comprising a.
The method of claim 7, wherein
One end and the other end of each of the plurality of second support wires is connected to the weight weight floating solar power generating device characterized in that the tension is provided.
The method of claim 7, wherein
At least one of the plurality of buoyancy support is provided with a control rod that can adjust the height,
At least one of the plurality of second support wires is a floating photovoltaic device, characterized in that connected to the adjusting rod to adjust the height.
The method of claim 7, wherein
The interior of the buoyancy support is composed of a plurality of compartments that are spaces closed to each other,
Each of the plurality of compartments,
Floating solar light, characterized in that it is provided with a pump for introducing external water into or out of the water inside, and an air inlet for allowing the air inside to flow out or the outside air into the inside Power generation device.
11. The method according to any one of claims 1 to 10,
Floating photovoltaic device, characterized in that the inside of the terminal box included in the solar cell module is filled with an insulating material (充 塡).
11. The method according to any one of claims 1 to 10,
Floating photovoltaic device, characterized in that at least one auxiliary float having a buoyancy is attached to the bottom or side of the solar cell module.

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