KR102322806B1 - Photovoltaic power generating apparatus capable of preventing ice formation - Google Patents

Abstract

The present invention relates to a solar power generator capable of preventing freezing. A photovoltaic power generation device capable of preventing freezing includes a photovoltaic panel in which photovoltaic cells are disposed on the upper surface; a drip tray member fastened to one side of the solar panel in the longitudinal direction of the solar panel and provided with a drip tray groove having a discharge hole; a discharge pipe provided with a discharge path communicating with the discharge hole and mounted on the drip tray member; and a heater wired to at least a portion of the discharge pipe.

Description

Photovoltaic power generating apparatus capable of preventing ice formation

The present invention relates to a photovoltaic power generation device capable of preventing icing, and more particularly, to a solar power generating device capable of preventing icing from forming.

In general, solar power generation produces power using a solar cell that generates photovoltaic power by the photoelectric effect when sunlight is irradiated.

Solar power generation is used as a new renewable energy as an alternative energy due to problems such as depletion of fossil fuels and environmental pollution.

The photovoltaic device basically includes a panel made of photovoltaic cells, and a storage battery and a power converter are added.

The solar panel is made so that it can be efficiently installed on the site by calculating the amount of sunlight so that it can collect sunlight on a flat large-scale site or mountainous terrain.

Recently, the land price rises and it is difficult to secure idle land, so it is facing many difficulties in installing solar power generation devices.

Korean Patent Application Laid-Open No. 10-2010-0116358 (Title of the Invention: Photovoltaic power generation device using a plastic house and its installation method) has a vertical frame 111 and a horizontal frame 112 connecting the vertical frame 111 ), the main frame 110 consisting of a plastic house 100 to form a frame; A plurality of photovoltaic modules 210 for collecting sunlight, and a plurality of support frames 220 are installed under the photovoltaic module 210 to support the photovoltaic module 210, but the support frame ( 220) is bound to the center of the vertical frame 111, the lower portion of the foundation stone 230 is installed, the photovoltaic power generation unit 200 is buried underground; It is installed on the top of the horizontal frame 112, and a pair is installed left and right around the support frame 220 to be bound with the main frame 110 and the support frame 220, and vinyl fixing grooves on both sides of the 310) is formed, and one side of the vinyl 10 is bound to a vinyl fixture 320 fitted into the vinyl fixing groove 310, and a rope binding pin 330 is installed at both ends of the rope 20, respectively. A photovoltaic power generation device using a plastic house is disclosed, comprising a; a vinyl mounting bracket 300 fixed to the upper and lower portions of the vinyl fixing groove 310, respectively.

However, the photovoltaic power generation device using a plastic house according to the prior art implements the photovoltaic power generation device by forming a frame on the upper part of the plastic house. The resulting icicles fall, causing a problem that damages the greenhouse.

Korean Patent Application Laid-Open No. 10-2010-0116358 (Title of the invention: Solar power generation device using a plastic house and its installation method)

The technical problem to be achieved by the present invention is to provide a solar power generation device capable of preventing freezing that can prevent the formation of icicles.

The problems to be solved by the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

A photovoltaic device capable of preventing freezing of the present invention for achieving the above technical problem includes: a photovoltaic panel in which photovoltaic cells are disposed on an upper surface; a drip tray member fastened to one side of the solar panel in the longitudinal direction of the solar panel and provided with a drip tray groove having a discharge hole; a discharge pipe provided with a discharge path communicating with the discharge hole and mounted on the drip tray member; and a heater wired to at least a portion of the discharge pipe.

The heater may be located in the distal region of the discharge pipe.

It may further include a cover member surrounding the heater.

The heater is built-in and may further include a coupling pipe body coupled to the discharge pipe.

The coupling tube body may be provided with a close contact jaw coupled to the end of the discharge pipe, and the side wall of the coupling tube body and the outer peripheral surface of the end of the discharge pipe may be screwed together.

The coupling tube body may be provided with a close contact jaw coupled to the end of the discharge pipe, and the side wall of the coupling tube body and the inner wall of the discharge pipe end of the discharge pipe may be screwed together.

A partial region of the coupling pipe body may protrude toward a central region of the discharge path of the discharge pipe, and the heater may be wired to a partial region of the protruding coupling pipe body.

a temperature sensor mounted on one of the solar panel, the water receiving member, and the discharge pipe to measure an external temperature of the solar power generation device; a heater driving unit for driving the heater; and a control module configured to drive the heater by transmitting a control signal to the heater driving unit when the external temperature measured by the temperature sensor is less than or equal to a set temperature.

Further comprising a wireless communication module receiving a heater driving signal for driving the heater from the external device wirelessly, wherein the heater driving signal transmitted from the wireless communication module is transmitted to the control module to control the heater in the heater driving unit and, when the external device is a mobile terminal, the heater driving signal is transmitted to the wireless communication module by a heater driving command input by a user through a dedicated app installed on the mobile terminal, or the external device is a management server In this case, the heater driving signal may be transmitted to the wireless communication module by a heater driving command input by a server administrator in the management server.

According to the present invention, it is possible to prevent the formation of icicles in the photovoltaic power generation device by the configuration of the drip tray member, the discharge pipe, and the heater, and the effect of preventing damage to the plastic house by dropping liquid water from the discharge pipe to the plastic house there is

In other words, due to the development of technology to fundamentally block the damage caused by icicles, it is possible to generate profits by generating electricity from sunlight by installing a solar power generator in the open area between the greenhouses.

In addition, in the present invention, the heater driving signal is wirelessly transmitted from the mobile terminal or the management server, so that the heater can be easily driven, and there is an advantage in that the administrator and unnecessary power consumption are not consumed.

1 is a perspective view of a solar power generation device capable of preventing freezing according to an embodiment of the present invention.
2 is an exploded perspective view of a photovoltaic device capable of preventing freezing according to an embodiment of the present invention.
3 is a perspective view of a discharge pipe of a solar power generation device capable of preventing freezing according to an embodiment of the present invention.
4 is a conceptual view illustrating a state in which the solar power generation device capable of preventing freezing according to an embodiment of the present invention is installed in the outdoor area between the plastic houses.
5A and 5B are partial cross-sectional views for explaining a method in which a heater is built in an exhaust pipe of a solar power generation device capable of preventing freezing according to an embodiment of the present invention.
6 is a partial cross-sectional view of a state in which the first coupling tube body having a built-in heater is coupled to the discharge tube of the solar power generation device capable of preventing freezing according to an embodiment of the present invention.
7 is a partial cross-sectional view of a state in which a second coupling pipe body having a built-in heater is coupled to the discharge pipe of the solar power generation device capable of preventing freezing according to an embodiment of the present invention.
8 is a block diagram of a solar power generation device capable of preventing freezing according to an embodiment of the present invention.

Advantages and features of the present invention and methods of achieving them may become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only the present embodiment serves to complete the disclosure of the present invention and those of ordinary skill in the art to which the present invention belongs. It is provided to fully inform the person of the scope of the invention, and the present invention is only defined by the claims.

Like reference numerals refer to like elements throughout.

1 is a perspective view of a solar power generation device capable of preventing freezing according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of a solar power generation device capable of preventing freezing according to an embodiment of the present invention, and FIG. 3 is A perspective view of a discharge pipe of a solar power generation device capable of preventing freezing according to an embodiment of the present invention, and FIG. 4 is a state in which a solar power generation device capable of preventing freezing according to an embodiment of the present invention is installed in the outdoor area between the plastic house It is a conceptual diagram showing

Referring to FIG. 1 , a photovoltaic power generation device capable of preventing freezing according to an embodiment of the present invention is configured to include a solar panel 110 , a drip tray member 120 , a discharge pipe 130 , and a heater 131 . .

The photovoltaic panel 110 is provided with photovoltaic cells arranged in a grid shape along columns and rows to generate power by sunlight.

Photovoltaic cells are disposed on the upper surface of the photovoltaic panel 110 to absorb sunlight to produce electric power, and a support pillar 115 is installed on the lower surface of the photovoltaic panel 110 . Therefore, by installing a solar panel at the foot of a paddy field, a field, and a mountain by supporting it with the support pillar 115, electricity is generated from the sunlight in the idle land to generate a profit.

The solar panel 110 is fixed by the support pillars 115 to generate solar power in all seasons. In order to increase the amount of power generation, the solar power generation cells are opposite to the direction in which the sunlight is irradiated (south-facing direction) to increase the amount of solar power generation. The solar panel 110 is installed to be inclined to collect light.

At this time, in the present invention, when snow melts on the solar panel 110 and flows to one side of the inclined solar panel 110 when snow falls, the melted snow water is received from the drip tray member 120 to receive the sun It is configured to be discharged downward in one direction of the light panel 110 .

That is, the drip tray member 120 is installed in the longitudinal direction of one side of the solar panel 110, and a drip tray groove 121 through which melted snow or rainwater can be accommodated and flowed is formed. Here, when the solar panel 110 is inclined from one side to the other side and the other side is defined as the upper side and one side is defined as the lower side, melted snow or rainwater flows from the other side to the one side.

Therefore, when the gutter member 120 is fastened to one side of the solar panel 110 , melted snow or rainwater flowing along the upper surface of the solar panel 110 falls into the gutter groove 121 .

And when the drip tray groove 121 is also inclined from one side to the other side to lower the position, the melted snow or rainwater falling from the solar panel 110 flows to the other side of the drip tray groove 121 at a relatively low position. will lose At this time, if the discharge pipe 130 is mounted on the other side of the drip tray groove 121 , it is possible to discharge the melted snow or rainwater to the outside through the discharge pipe 130 .

On the other hand, when the external temperature of the solar panel 110 is below zero, the melted snow or rainwater freezes at the end of the discharge pipe 130 to form icicles, and the icicles gradually grow according to climate conditions and ambient temperature. The tip is sharp.

When the large and sharp icicles fall off, useful installations such as houses located under the discharge pipe 130 are damaged.

Therefore, in the present invention, the heater 131 is built in the discharge pipe 130 to prevent icicles from being formed in the discharge pipe 130 so that the discharged water does not freeze.

That is, as shown in FIG. 2 , the solar panel 110 has photovoltaic cells exposed on the upper surface, the support pillar 115 is installed on the bottom surface, and the drip tray groove 121 is provided on the drip tray member 120 . is formed The drip tray member 120 is fastened to one side of the solar panel 110 . At this time, various fastening means can be used.

In addition, a discharge hole is formed on the other side of the drip tray groove 121 in a relatively low position at an angle, and the discharge pipe 130 is provided with a discharge path coupled with the discharge hole of the drip tray groove 121 to communicate with the drip tray groove. It is mounted on the other side of (121). The discharge pipe 130 has a built-in heater 131 such as a hot wire, and as shown in FIG. 3 , the heater 131 is built in the distal end of the discharge pipe 130 to prevent icicles from occurring.

And, in the present invention, the heater 131 built in the end of the discharge pipe 130 can be configured by extending the wiring so that the heater 131 is embedded in the discharge pipe 130 along the discharge path of the discharge pipe 130, and the discharge pipe ( Another heater 131 driven independently of the built-in heater 131 is built into the drip tray member 120 so that the snow and melted snow falling from the solar panel 110 are frozen due to the external temperature and the drip tray It may be configured to prevent failure of the member 120 to function. As a result, snow and melted snow falling from the solar panel 110 do not freeze and become a fluid water state, and quickly flow along the drip tray groove 121 and are discharged to the outside through the discharge pipe 130 .

For example, when the photovoltaic power generation device capable of preventing freezing of the present invention is installed in the middle of the plastic house, icicles in the photovoltaic power generation device by the configuration of the water receiving member 120, the discharge pipe 130, and the heater 131 Formation can be prevented, and liquid water from the discharge pipe 130 falls into the plastic house, thereby preventing damage to the plastic house.

On the other hand, solar power generation is to maximize income by maximizing income by using idle land as much as possible.

However, at sub-zero temperatures, icicles are formed in the photovoltaic device, and when the icicles fall, the useful installation under the photovoltaic device is damaged. It was not thought of at all, and it had not even been attempted.

Accordingly, the inventor of the present invention can develop a technology for fundamentally blocking the damage caused by icicles as a result of repeated multifaceted research to solve the problems associated with installing solar power generation devices among many greenhouses nationwide. there was.

Therefore, in the present invention, as shown in FIG. 4 , the first to fourth photovoltaic power generation devices 101 , 102 , 103 , 104 are installed in the open field corresponding to both sides of the first and second plastic houses 201 and 202 , respectively.

Here, the solar panel 110 is disposed to face the south and inclined so as to receive sunlight well, and the solar panel 110 is located at a relatively low position by the inclination of the solar panel 110 . ), the drip tray member 120 and the discharge pipe 130 are fastened to one side.

Since there is a heater 131 in the discharge pipe 130 , snow and snow melt water flowing down from the solar panel 110 falls into the drip tray groove 121 of the drip tray member 120 and flows from the drip tray groove 121 to the discharge pipe 130 . ), as the water of the unfrozen liquid falls through, there is no damage to the plastic house.

That is, the discharge path of the discharge pipe 130 of the second and fourth solar power generation devices 102 and 104 of FIG. 4 faces the first and second vinyl houses 201 and 202, but the liquid water falls from the discharge path, so that no It does not damage the greenhouse.

Therefore, the solar power generation device of the present invention can fundamentally prevent damage caused by icicles and can be installed in the open field between the plastic houses, so that the owner of the plastic house or the owner of the land in which the greenhouse is installed can generate profits from solar power generation. There are advantages that can be

5A and 5B are partial cross-sectional views for explaining a method in which a heater is built in a discharge pipe of a solar power generation device capable of preventing freezing according to an embodiment of the present invention, and FIG. 6 is an icing according to an embodiment of the present invention. It is a partial cross-sectional view of a state in which the first coupling tube body with a built-in heater is coupled to the discharge tube of the solar power generation device that can be prevented, and FIG. 7 is a heater on the discharge pipe of the solar power generation device capable of preventing freezing according to an embodiment of the present invention. It is a partial cross-sectional view of a state in which the built-in second coupling tube body is coupled.

In the present invention, in order to embed the heater in the discharge pipe 130, a heater 151, which is a heating wire, is wired at the end of the discharge pipe 130 as shown in FIG. It can be configured by fixing to the end of the.

In addition, as shown in FIG. 5B , the cover member 152 having a built-in heater 151 may be fixed to the distal end of the discharge pipe 130 . In this case, the heater 151 is embedded in the cover member like a core.

And, in the present invention, the exhaust pipe 130 may be configured by combining a coupling pipe body having a built-in heater 151 therein. The coupling tube body has a tubular shape provided with a passage communicating with the discharge passage of the discharge tube 130 .

This coupling pipe body was developed in consideration of the ease of coupling with the end of the discharge pipe 130 and preventing the occurrence of icicles, and in the present invention, two types of coupling pipe bodies are applied.

First, for ease of coupling, the coupling tube body is provided with a 'L'-shaped close contact jaw coupled to the end of the discharge pipe 130, and the side wall of the contact jaw of the coupling tube body and the outer peripheral surface of the end of the discharge pipe 130 or the discharge pipe 130 end The coupling force between the coupling pipe body and the discharge pipe 130 is increased due to the structural feature in which the inner wall is screw-coupled to the discharge path.

To this end, the coupling structure of FIG. 6 is a structure in which the side wall 161a of the close contact jaw 161 of the first coupling pipe body 160 and the outer peripheral surface of the distal end of the discharge pipe 130 are screwed, and the discharge path 135 of the discharge pipe 130 ) can be configured to be the same as the inner diameter I2 of the passage 165 of the first coupling pipe 160 , and the outer diameter D2 of the first coupling pipe 160 is the discharge pipe 130 . It can be configured to be larger than the outer diameter D1.

In addition, in the coupling structure of FIG. 7 , similarly to the coupling structure of FIG. 6 , the side wall 171a of the close contact jaw 171 of the second coupling pipe 170 and the inner wall of the distal end of the discharge pipe 130 are screwed together, and the discharge pipe The inner diameter I1 of the discharge path 135 of the 130 can be configured to be larger than the inner diameter I3 of the passage of the second coupling pipe body 170, and the outer diameter D3 of the second coupling pipe body 170 is set to the discharge pipe It can be configured in the same way as the outer diameter (D1) of (130).

And, in order to prevent the occurrence of icicles, the heater 131 is wired adjacent to the passage of the coupling pipe communicating with the discharge path 135 of the discharge pipe 130 and configured to be embedded in the coupling pipe body. 135), heat is applied to the melted snow water from the shortest distance so that it is quickly discharged to the outside through the passage of the coupling body, so that icicles do not occur.

To this end, in the coupling structure of FIG. 6 , the heater ( 131) is placed.

Here, the inner diameter of the passage of the first coupling tube 160 from one area of the passage of the first coupling tube 160 in contact with the discharge passage 135 of the discharge tube 130 to the other area can be implemented in a shape that is gradually narrowed. .

In this case, the inner wall of the passage of the first coupling tube body 160 is inclined in the direction of the central region of the passage, and the passage of the inclined first coupling tube body 160 has a larger contact area with the melted snow, so that the heater 131 more rapidly. ) can be transferred to the melted snow water to prevent the occurrence of icicles, and at the same time, melted snow can slide on the inclined inner wall of the passage of the first coupling tube 160 and quickly escape to the outside. let there be

And, in the coupling structure of FIG. 7 , when the side wall 171a of the close contact jaw 171 of the second coupling pipe 170 and the inner wall of the distal end of the discharge pipe 130 are screwed together, a partial region of the second coupling pipe body 170 is The bar protrudes in the direction of the central area of the discharge path 135 of the discharge pipe 130 , and the heater 131 is wired and embedded in a partial area of the protruding second coupling pipe body 170 .

Therefore, in this coupling structure, the contact area of the melted water becomes larger, so that more heat can be applied to the melted water, such as thin ice, and heat is supplied to the discharge path 135 of the discharge pipe 130 to further suppress the occurrence of icicles. have.

8 is a block diagram of a solar power generation device capable of preventing freezing according to an embodiment of the present invention.

The solar power generation device 100 capable of preventing freezing according to an embodiment of the present invention may have an additional configuration associated with the heater 131 .

That is, the additional configuration includes a temperature sensor 133 , a heater driving unit 132 , a control module 181 , and a wireless communication module 182 .

The temperature sensor 133 is mounted on one of the solar panel 110 , the drip tray member 120 , and the discharge pipe 130 to measure the external temperature of the solar power generation device 100 .

The control module 181 drives the heater 131 by transmitting a control signal to the heater driving unit 132 when the external temperature measured by the temperature sensor 133 is below the set temperature. Here, the set temperature may be a sub-zero temperature at which water begins to freeze, but may be set to a temperature within the range of -0.1 to -1°C.

The wireless communication module 182 wirelessly receives a heater driving signal from an external device and transmits it to the control module 181 to cause the heater driving unit 132 to drive the heater 131 , and the external device is connected to the portable terminal 310 . ), the heater driving signal is transmitted using the first wireless communication network 301 , and when the external device is the management server 510 , the heater driving signal is transmitted using the second wireless communication network 501 .

The mobile terminal 310 is configured to allow the user to input a command to drive the heater 131 at a desired time through a dedicated app, and in this case, the first wireless communication network 301 enables objects to communicate with each other. It may be a dedicated network for the Internet of Things (loT). Accordingly, the operator who has installed the solar power generation device 100 can easily drive the heater 131 in the portable terminal 310 that he or she carries.

In addition, the management server 510 can quickly drive the heater 131 through the second wireless communication network when the server administrator inputs a command to drive the heater 131 , and the management server 510 is connected to the Korea Meteorological Administration through the Internet network. Alternatively, it is configured to interwork with weather information provided by a broadcasting station, and when weather information such as snowy weather information or sub-zero temperature in an area where the solar power generation device 100 is installed is provided to the management server 510, the management server 510 transmits a control signal to drive the heater 131 to the wireless communication module 182 of the solar power generation device 100 through the second wireless communication network 501 .

That is, when the external device is the mobile terminal 310, the heater driving signal is transmitted to the wireless communication module 182 by the heater driving command input by the user through the dedicated app installed on the mobile terminal 310, and the external device is managed In the case of the server 510 , the heater driving signal is transmitted to the wireless communication module 182 by the heater driving command input by the server administrator from the management server 510 .

Therefore, the heater 131 of the photovoltaic device is automatically driven by interlocking with weather information even if the manager and the operator do not have to manage it in a special and separate time, thereby providing convenience and not consuming unnecessary power.

In the above, embodiments of the present invention have been described with reference to the accompanying drawings, but those of ordinary skill in the art to which the present invention pertains may realize that the present invention may be embodied in other specific forms without changing the technical spirit or essential features thereof. You will understand that you can. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

100, 101, 102, 103, 104: solar power generation device
115: support column 120: drip tray member
121: drip groove 130: discharge pipe
131,151: Heater 132: Heater driving part
133: temperature sensor 152: cover member
160, 170: coupling tube body 161, 171: tight jaw
181: control module 182: wireless communication module
201,202: vinyl house 310: mobile terminal
510: management server

Claims (9)

A photovoltaic panel in which photovoltaic cells are disposed on the upper surface;
a drip tray member fastened to one side of the solar panel in the longitudinal direction of the solar panel and provided with a drip tray groove having a discharge hole;
a discharge pipe provided with a discharge path communicating with the discharge hole and mounted on the drip tray member; and
a heater positioned at an end region of the discharge pipe;
Including a coupling pipe body in which the heater is built and coupled to the discharge pipe,
The coupling tube body is provided with a close contact jaw coupled to the end of the discharge pipe, the side wall of the coupling tube body and the inner wall of the discharge pipe end of the discharge pipe are screwed together,
A partial region of the coupling pipe body protrudes in the direction of the central region of the discharge path of the discharge pipe, and the heater is wired and built in a partial area of the protruding coupling pipe body,
The water receiving member is a solar power generation device capable of preventing freezing in which another heater driven independently of the heater built into the coupling tube body is built-in. delete delete delete delete delete delete According to claim 1,
a temperature sensor mounted on one of the solar panel, the water receiving member, and the discharge pipe to measure an external temperature of the solar power generation device;
a heater driving unit for driving the heater; and
A solar power generation device capable of preventing freezing further comprising a; when the external temperature measured by the temperature sensor is less than or equal to a set temperature, a control module for driving the heater by transmitting a control signal to the heater driving unit. 9. The method of claim 8,
Further comprising a wireless communication module receiving a heater driving signal for driving the heater from an external device wirelessly,
The heater driving signal transmitted from the wireless communication module is transmitted to the control module to drive the heater in the heater driving unit,
When the external device is a mobile terminal, the heater driving signal is transmitted to the wireless communication module by a heater driving command input by a user through a dedicated app installed on the mobile terminal, or when the external device is a management server, the management An anti-icing solar power generation device configured to transmit the heater driving signal to the wireless communication module in response to a heater driving command input by a server administrator in the server.

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