KR102164245B1 - Gasket and junction box for solar power generating system having the same - Google Patents

Abstract

The solar connection panel according to the present invention,
An outer material including a left wall and a right wall, and a floor connecting the left and right walls between the left and right walls; A first intrinsic material formed on an upper surface of the floor and having a height not protruding above the left and right walls; A second inner material formed on a lower surface of the floor and having a height not protruding above the left and right walls; A gasket composed of a corrosion inhibitor coated on a surface of the outer material, a surface of the first inner material, and a surface of the second inner material;
It characterized in that it comprises a heat sink coated with a corrosion inhibitor.

Description

Gasket and solar panel including the same {GASKET AND JUNCTION BOX FOR SOLAR POWER GENERATING SYSTEM HAVING THE SAME}

The present invention relates to a gasket and a solar connection panel including the same.

As shown in Figure 1, the solar power generation system is a solar cell module that generates power from sunlight, an inverter that converts DC power into AC power and transmits it to a home or power plant, and DC power generated from the solar cell module. It consists of a solar connection panel (1) supplied to the inverter, a system monitoring the solar connection panel (1), and an energy storage system that stores electricity by being connected to the inverter.

As shown in FIG. 2, the solar connection panel 1 is composed of an enclosure 11, internal parts installed inside the enclosure 11, and a monitor 19 installed in the front of the enclosure 11.

The internal components include RTU (12) that transmits solar-related integrated information to the monitoring system, heat sink (13) that suppresses diode temperature rise, and diode that blocks repetitive reverse and reverse power and circulating power between circuits in a parallel circuit. (14), a string module (15) that measures information necessary for solar and power generation facilities such as voltage, current, and power for each channel in real time, a surge protector (16) that protects solar facilities from lightning and overvoltage, DC It consists of a breaker, a fuse holder 18 that protects the device from short-circuit current and overcurrent.

In order to protect the internal parts of the solar panel from dust, moisture, and salt, a gasket 11c is installed between the door 11a and the body 11b of the enclosure 11. The gasket 11c is made of a rubber material.

A groove 11bb into which a gasket is inserted is formed along the rim of the body 11b. When the gasket 11c is inserted into the groove 11bb and the door 11a is closed, the rim 11aa of the door 11a presses the gasket 11c to seal the enclosure 11.

On the other hand, in recent years, many solar power generation systems have been installed in the sea providing a wider installation area than plains and forests.

In the sea, the wind including salt is continuously blowing, which easily corrodes the rubber gasket (11c). When the gasket (11c) is corroded in this way, a gap is created in the gasket (11c), and dust, moisture, and salt are introduced into the enclosure (11) through the gap. Dust, moisture, and salt cause internal parts to break down and short-circuit, causing fire.

Korean Patent Publication (10-2017-0114383)

It is an object of the present invention to provide a gasket capable of solving the above-described problems and a solar panel including the same.

A gasket for achieving the above object,

An outer material including a left wall and a right wall, and a floor connecting the left and right walls between the left and right walls;

A first intrinsic material formed on an upper surface of the floor and having a height not protruding above the left and right walls;

A second inner material formed on a lower surface of the floor and having a height not protruding above the left and right walls; And

It characterized in that it comprises a corrosion inhibitor coated on the surface of the outer material, the surface of the first inner material and the surface of the second inner material.

In addition, the above purpose,

An outer material including a left wall and a right wall, and a floor connecting the left and right walls between the left and right walls; A first intrinsic material formed on an upper surface of the floor and having a height not protruding above the left and right walls; A second inner material formed on a lower surface of the floor and having a height not protruding above the left and right walls; A gasket composed of a corrosion inhibitor coated on a surface of the outer material, a surface of the first inner material, and a surface of the second inner material;

It is achieved by a solar connection board, characterized in that it comprises a heat sink coated with a corrosion inhibitor.

When the solar panel according to the present invention is used, while the door of the enclosure is closed, the outer material protruding from the first inner material and the second inner material is first compressed, and then the first inner material and the non-protruding outer material The second intrinsic is compressed secondarily. Accordingly, it is possible to prevent dust, moisture, and salt from penetrating into the outer material firstly, and secondly, the first inner material and the second inner material may prevent dust, moisture, and salt from penetrating into the inner case.

The present invention prevents corrosion of the gasket itself by adding a corrosion inhibitor to the structure of the gasket described above.

The present invention delays the corrosion of the gasket itself by mixing a carbon fiber fabric or a short carbon fiber in the outer material of the gasket, the first inner material and the second inner material described above.

Therefore, when the present invention is used, dust, moisture, and salt are fundamentally blocked from entering the interior of the solar panel, and the internal parts are sufficiently protected even if the solar panel is installed in the plains, forests and seas.

1 is a view showing a solar power generation system including a general solar connection panel.
FIG. 2 is a view showing the solar connection panel shown in FIG. 1.
3 is a view showing a gasket having a square shape according to an embodiment of the present invention.
4 is a view showing a gasket having a circular shape according to an embodiment of the present invention.
5 is a view showing the cross section VV shown in FIG. 3, FIG. 5(a) is a view showing a state of a gasket before being compressed by a door frame, and FIG. 5(b) is a view showing a state of a gasket compressed by a door frame. It is a figure shown.
6 is a view showing the gasket according to the first modified example, FIG. 6(a) is a view showing the state of the gasket before being compressed by the door frame, and FIG. 6(b) is a view showing the state of the gasket compressed by the door frame. It is a figure shown.
7 is a view showing a gasket according to a second modified example.
8 is a view showing a gasket according to a third modified example.

Hereinafter, a gasket according to an embodiment of the present invention will be described in detail.

The gaskets 100 and 101 according to an embodiment of the present invention may have a square shape as shown in FIG. 3 or a circular shape as shown in FIG. 4. Of course, the shape of the gasket can vary.

Hereinafter, a gasket 100 having a square shape will be described.

As shown in FIG. 5, the gasket 100 is composed of an outer material 110, a first inner material 120, a second inner material 130, and an anti-corrosion material 140.

The outer material 110 is composed of a left wall 111, a right wall 112, and a floor 113.

The left wall 111 is formed on the left edge of the gasket 100. The right wall 112 is formed on the right edge of the gasket 100. The floor 113 connects the inner middle of the left wall 111 and the inner middle of the right wall 112.

The first inner material 120 and the second inner material 130 have the same shape, and are arranged vertically symmetrically around the floor 113.

The first inner material 120 is formed on the upper surface of the bottom 113. The first inner material 120 has a height H that does not protrude above the left wall 111 and the right wall 112. The first inner material 120 is composed of a mountain 121 and a protrusion 122. Mountains 121 and valleys 122 are formed alternately. In this embodiment, the number of mountains 121 is 4, and the number of valleys 122 is 4. Of course, the number of mountains and valleys can vary.

The second inner material 130 is formed on the lower surface of the bottom 113. The second inner material 130 has a height that does not protrude above the left and right walls 111 and 112. The second inner material 130 is composed of a mountain 131 and a protrusion 132. Mountains 131 and valleys 132 are formed alternately. In this embodiment, the number of mountains 131 is 4, and the number of valleys 132 is 4. Of course, the number of mountains and valleys can vary.

The outer material 110, the first inner material 120, and the second inner material 130 are made of a rubber material.

Corrosion preventing material 140 is coated on the surface of the outer material 110, the surface of the first inner material 120 and the surface of the second inner material 130, the outer material 110, the first inner material 120, 2 It prevents the inner material 130 from being corroded. The corrosion inhibitor 140 is composed of carbon nanotubes or graphene having corrosion resistance. The corrosion-preventing material 140 is spray-sprayed and coated on the surface of the outer material 11 and the surface of the first inner material 12 and the second inner material 13, or coated with a brush. The anticorrosion material 140 may be coated on the heat sink 13 to prevent corrosion of the heat sink 13.

Hereinafter, the operation of the gasket 100 will be described.

When the door of the enclosure is closed and the edge of the door compresses the gasket 100, the outer material protruding from the first inner material and the second inner material is first compressed, and then the first inner material and the first inner material that do not protrude from the outer material are compressed. 2 Intrinsic is compressed secondarily. Therefore, firstly, the outer material prevents dust, moisture, and salt from penetrating into the enclosure, and secondly, the first inner material and the second inner material prevent dust, moisture, and salt from penetrating into the outer case.

In this embodiment, the number of mountains and valleys is 4, but if the number of mountains and valleys is further increased, the ability to prevent penetration of dust, moisture, and salt can be further increased. Due to the structure of the gasket of this embodiment, it is possible to sufficiently maintain the sealed structure of the enclosure. In addition, by adding a corrosion inhibitor to the structure of the gasket to prevent corrosion of the gasket 100 itself, it is possible to maintain the performance of the gasket.

Hereinafter, a gasket according to the first modified example will be described.

As shown in Figure 6, the gasket 100' according to the first modified example is shown in Figure 5, except that the amount of the corrosion inhibitor coated on the acid is greater than the amount of the corrosion inhibitor coated on the bone. It is the same as the gasket 100.

In this way, the reasons for the different amounts of corrosion inhibitors in the valleys and mountains are as follows.

When the door of the enclosure is closed and the gasket 100 ′ is pressed, the mountains 121 and 131 of the inner material 120 and 130 are compressed next to the outer material 110. When the acids 121 and 131 are compressed, the corrosion inhibitor 140 coated on the acids 121 and 131 spreads, so that the density of the corrosion inhibitor 140 in the acid portion may decrease. Corrosion may occur in a portion where the density of the corrosion inhibitor 140 is small. In order to prevent this, in the gasket 100 ′ according to the first modification, as shown in FIG. 6 (a), the corrosion inhibitor 140 is coated on the acids 121 and 131 thicker than the valleys 122 and 132. To this end, the corrosion inhibitor 140 is sprayed on the acids 121 and 131 several times, or applied several times with a brush. When the corrosion inhibitor 140 is thickly coated on the acids 121 and 131, even if the acids 121 and 131 are crushed and the corrosion inhibitor 140 spreads, as shown in FIG. 6(b), the corrosion inhibitor 140 The density can be maintained at a density sufficient to prevent corrosion.

Other configurations and actions of the gasket 100' are the same as those of the gasket 100 shown in FIG. 5, and thus detailed descriptions are omitted.

Hereinafter, a gasket according to the second modified example will be described.

As shown in FIG. 7, the gasket 200 according to the second modified example is composed of an outer material 210, a first inner material 220, a second inner material 230, and an anti-corrosion material 240.

The outer material 210 is composed of a left wall 211, a right wall 212, and a floor 213.

The first inner material 220 is composed of a mountain 221 and a protrusion 222. The second inner material 230 is composed of a mountain 231 and a protrusion 232.

The outer material 210, the first inner material 220, and the second inner material 220 are composed of a matrix rubber material (R) and a carbon fiber fabric (FB). Carbon fiber fabric (FB) is made by woven carbon fibers horizontally and vertically. Due to this carbon fiber fabric (FB), even if salt penetrates through the corrosion inhibitor 240, due to the carbon fibers woven in the horizontal and vertical directions, the outer material 210, the first inner material 220, the second Corrosion of the inner material 220 can be delayed as much as possible, and the strength of the gasket 200 is reinforced due to the carbon fiber fabric (FB).

Corrosion preventing material 240 is coated on the surface of the outer material 210, the surface of the first inner material 220 and the surface of the second inner material 230, the outer material 210 and the first inner material 220 2 It prevents the inner material 230 from being corroded.

Other configurations and actions of the gasket 200 are the same as those of the gasket 100 shown in FIG. 5, and thus detailed descriptions thereof will be omitted.

Hereinafter, a gasket according to the third modified example will be described.

As shown in FIG. 8, the gasket 300 according to the third modified example is composed of an outer material 310, a first inner material 320, a second inner material 330, and a corrosion inhibitor 340.

The outer material 310 is composed of a left wall 311, a right wall 312, and a floor 313.

The first inner material 320 is composed of a mountain 321 and a protrusion 322. The second inner material 330 is composed of a mountain 331 and a protrusion 332.

The outer material 310, the first inner material 320, and the second inner material 320 are composed of a matrix rubber material (R) and carbon fibers (Cf). Carbon fibers (Cf) are randomly mixed in the matrix rubber material (R) Due to the randomly mixed carbon fibers (Cf), even if salt penetrates through the corrosion inhibitor 340, the outer material 310, the first Corrosion of the inner material 320 and the second inner material 320 may be delayed as much as possible. In addition, the strength of the gasket 200 is reinforced due to the carbon fiber (Cf). The carbon fiber (Cf) is short of 1 to 2 mm, and may be mixed with the molten matrix rubber material (R), extruded and cured to form the gasket 300.

Corrosion preventing material 340 is coated on the surface of the outer material 310, the surface of the first inner material 320 and the surface of the second inner material 330, the outer material 310 and the first inner material 320 2 Prevents the inner material 330 from being corroded.

Other configurations and actions of the gasket 300 are the same as those of the gasket 100 shown in FIG. 5, and thus detailed descriptions thereof will be omitted.

A solar connection panel according to an embodiment of the present invention selectively includes the gaskets 100, 101, 100', 200, 300 described above, and includes a heat sink 13 coated with a corrosion inhibitor. Except for this, since it is the same as the conventional solar panel 1 shown in FIGS. 1 and 2, detailed descriptions are omitted.

1: solar panel 100,101,100',200,300: gasket
110,210,310: external material
120,220,320: first immanence
130,230,330: second immanence

Claims (7)

delete delete delete delete delete delete In the solar connection panel of the solar power system installed on the sea level,
The solar connection panel includes an enclosure composed of a door and a body, internal parts installed inside the enclosure, and a gasket inserted into a groove formed along an edge of the body,
The gasket,
An outer material including a left wall, a right wall, and a floor connecting the left wall and the right wall between the left and right walls;
A first intrinsic material formed on the upper surface of the floor, having a height that does not protrude above the left and right walls, and composed of mountains and valleys;
A second intrinsic material formed on a lower surface of the floor and having a height that does not protrude above the left and right walls, and composed of mountains and valleys; And
It includes a corrosion inhibitor coated on the surface of the outer material, the surface of the first inner material and the surface of the second inner material,
When the door of the enclosure is closed and the edge of the door compresses the gasket, the outer material protruding from the first inner material and the second inner material is first compressed, and then the first inner material that does not protrude from the outer material 1 intrinsic material and the second intrinsic material are secondarily compressed,
Primaryly, the outer material prevents salt from penetrating into the enclosure,
Secondly, the first inner material and the second inner material to prevent salt from penetrating into the interior of the enclosure in a double layer.

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