KR20150118554A - Roof solar battery module embedded type roof panel - Google Patents

Abstract

The present invention comprises a body frame installed to the upper part of a building, a solar battery panel which is installed to the body frame and generates electricity by incident sunlight, a combination frame which is combined with the body frame to fix the solar battery panel to the body frame, and a heating part which is installed to the combination frame and heats snow stacked on the body frame or the solar battery panel. A roof panel having a solar battery has a heater for melting snow stacked on the upper part of the solar battery. Thereby, it can be prevented that the generation efficiency of the solar battery is reduced by the snow.

Description

[0001] The present invention relates to a roof panel having a solar cell,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a roof panel provided with a solar cell, and more particularly, to a roof panel provided on a top of a building and provided with a solar cell having a built-in solar cell therein.

Alternative energy has been actively developed and used as a means of solving this problem as the damage caused by natural disasters increases due to global warming caused by massive use of fossil fuels and environmental destruction. Among them, solar energy collection devices that are pollution-free and economical are attracting attention.

There are two main areas for collecting and using solar energy. One is the solar heat field used for heating or hot water supply by collecting the solar heat. The other is using the photoelectric effect (photoelectric effect) when solar light enters the solar cell composed of silicon semiconductor. To generate electricity. In the early days, researches and commercialization of solar heat, which mainly uses solar heating as heating and hot water, has been conducted. Recently, research and commercialization of the solar power generation field has been actively promoted due to the development of solar cell related technology.

Korean Patent Registration No. 10-0867655 discloses a solar cell module for a roof panel. The roof panel solar cell module includes a main body mounted on a roof; A temperature sensor provided on the solar panel to measure a temperature and a cooling fluid flowing between the solar panel and a bottom surface of the main body to force the solar panel, And cooling means for cooling.

However, the roof panel solar cell module has a disadvantage in that when the snow is accumulated on the outer surface, the electricity generation rate of the solar cell is lowered due to accumulated snow.

It is an object of the present invention to provide a roof panel provided with a solar cell in which a heater is cooled to melt snow accumulated on a solar cell.

According to an aspect of the present invention, there is provided a roof panel comprising a body frame mounted on an upper part of a building, a solar cell panel mounted on the body frame and generating electricity through incident solar light, A joining frame coupled to the body frame to fix the solar panel to the body frame, and a heating unit installed on the joining frame and generating heat to melt the snow piled on the body frame or the solar cell panel.

The body frame may include a main plate on which the solar cell panel is installed and an inflow blocking portion formed on the main plate to block rainwater or snow from entering the space between the outer side of the building and the main plate.

Wherein the inflow blocking portion includes a first engaging member extending forward from an edge of the front end of the main plate and protruding upward so as to form an engaging groove on a lower surface thereof and a rear end extending rearward from a rear end edge of the main plate, And a second engaging member protruding upward with respect to the main plate so as to be inserted into the engaging groove of the first engaging member of the adjoining body frame.

The inflow blocking portion includes a first engaging member extending along the right edge of the first engaging member, the main plate, and the second engaging member and protruding upward from the main plate, And a second latching member extending along the left edge of the coupling member and protruding downward with respect to the main plate so as to be engaged with the first latching member of the body frame adjacent to the left side.

Wherein the solar cell panel is located on a lower surface of the main plate so that an upper surface of the solar cell panel is exposed to the outside through a through hole formed in the main plate, the coupling frame includes a contact plate contacting the lower surface of the solar cell panel, The heating unit may include a first heating wire installed on the contact plate to generate heat and a second heating wire installed on an inner side surface of the engagement groove of the first joining member to generate heat.

The contact plate is formed with an insertion slot extending along a top edge thereof so that the first heating element can be inserted.

The main plate is protruded upward at a position adjacent to the through hole so as to prevent the snow stacked on one side from slipping toward the solar cell panel, and a blocking protrusion is formed extending along one side edge of the through hole .

The first engaging member protrudes upward on the outer circumferential surface so as to reinforce the strength, and a reinforcing protrusion extending a predetermined length along the front-rear direction is formed.

The roof panel provided with the solar cell according to the present invention has an advantage of preventing the power generation efficiency of the solar cell from being reduced due to the snow because it melts the snow accumulated on the upper side of the solar cell by the heater.

1 is a perspective view of a building having a roof panel provided with a solar cell according to an embodiment of the present invention,
FIG. 2 is an exploded perspective view of a roof panel provided with the solar cell of FIG. 1,
3 is a cross-sectional view of a roof panel provided with the solar cell of FIG.

Hereinafter, a roof panel provided with a solar cell according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 3 show a roof panel 100 provided with a solar cell according to the present invention.

Referring to the drawings, a plurality of roof panels 100 provided with solar cells are fixed to a plurality of support bars 16 fixed to an upper portion of a building 15. A plurality of rows of roof panels 100 provided with a plurality of solar cells are arranged in the vertical direction along the left-right direction.

A roof panel 100 provided with a solar cell according to the present invention includes a body frame 200 installed on an upper part of a building 15 and a body frame 200 installed on the body frame 200 to generate electricity through incident sunlight A coupling frame 400 coupled to the body frame 200 to fix the solar cell panel 300 to the body frame 200, And a heating unit 500 installed to heat the body frame 200 or the solar cell panel 300 to melt snow.

The body frame 200 includes a main plate 210 on which the solar cell panel 300 is installed and a main frame 210 on which the rainwater in the space between the outer surface of the building 15 and the main plate 210 Or an inflow blocking portion 220 for blocking inflow of snow.

The main plate 210 is formed in a plate shape having a predetermined thickness and has a through hole 211 penetrating through the solar cell panel 300 in the up and down direction so that the top surface of the solar cell panel 300 is exposed to the outside. The through-hole 211 is preferably formed in a rectangular shape corresponding to the area of the solar cell panel 300. In addition, a plurality of coupling holes 213 are formed on the upper side of the main plate 210 to allow the fixing bolts to pass therethrough. The fixing bolt inserted into the coupling hole 213 is screwed to the supporting bar 16 fixed to the top of the building 15 to fix the main plate 210 to the ridges.

The main plate 210 is formed with an interference member 212 at the edge of the through hole 211 so as to grasp the edge of the solar cell panel 300 installed on the bottom surface. The interference member 212 extends along the edge of the through hole 211 and protrudes toward the center of the through hole 211. The interference member 212 grasps the top edge of the solar cell panel 300 to prevent the solar cell panel 300 from being separated through the through-hole 211.

The main plate 210 is disposed at a position spaced to the right with respect to the through hole 211 so as to prevent the snow stacked on the upper side with respect to the through hole 211 from sliding toward the solar cell panel 300 side A blocking protrusion 214 is formed. The blocking protrusion 214 protrudes upward from the upper surface of the main plate 210 and extends in the front-rear direction along the right edge of the through-hole 211. Since the blocking protrusion 214 is provided on the main plate 210 adjacent to the through hole 211 as described above, the slipped eye along the main plate 210 is blocked by the blocking protrusion 214 and the through hole 211 ) Is blocked. The stopper protrusion 214 protrudes from the main plate 210 to reinforce the strength of the main plate 210.

The inflow blocking portion 220 includes a first engaging member 230 formed on the front edge of the main plate 210, a second engaging member 240 formed on the rear edge of the main plate 210, And a second latching member 260 formed at a left edge of the main plate 210. The latching member 260 is formed at the left edge of the main plate 210. [

The first engaging member 230 extends forward from the front end edge of the main plate 210 and is formed to be convex upward so as to form a latching groove 231 on the lower surface. The first engaging member 230 extends in a length corresponding to the width of the main plate 210 in the left-right direction.

In addition, the first engaging member 230 is protruded upward on the outer circumferential surface so as to reinforce the strength, and the reinforcing protrusion 232 extending a predetermined length along the front-rear direction is formed. The reinforcing protrusion 232 is formed at a position adjacent to the right edge of the first engaging member 230.

The first joining member 230 is provided with a mounting slot for mounting the second heating element 502 of the heating part 500, which will be described later, on the lower surface corresponding to the locking groove 231. The installation slot is a predetermined depth extending upward from the lower surface of the second engagement member 240 and includes a first unit slot 234 extending in the left and right direction by a predetermined length and a second unit slot 234 extending forward from the first unit slot 234 A second unit slot 235 extending in the left and right direction by a predetermined length is connected to the left end of the first and second unit slots 234 and 235 at the lower surface of the second coupling member 240 in the spaced apart position, And a third unit slot (not shown) formed to be curved convexly to the left. At this time, a protrusion 236 is formed on the upper outer circumferential surface of the first engagement member 230 corresponding to the installation slot so as to protrude upward to form the installation slot.

The second coupling member 240 extends rearward from the rear end edge of the main frame 210 so as to be inserted into the coupling groove 231 of the first coupling member 230 of the rear body frame 200 As shown in Fig. The second coupling member 240 is preferably curved so as to have a predetermined curvature. The second joining member 240 is inserted into the engagement groove 231 of the adjacent roof panel 100 when the plurality of roof panels 100 are coupled to form rainwater between the first joining member 230 and the main plate 210 Blocks the inflow of snow.

The first engaging member 250 includes a first protrusion 251 extending along the right edge of the first engaging member 230 and projecting upward from the first engaging member 230, A second protrusion 252 extending along the right edge of the main plate 210 and projecting upward from the main plate 210 and a second protrusion 252 extending along the right edge of the second coupling member 240, And a third protrusion 253 protruding from the second protrusion 253.

The first protrusion 251 is curved so as to be convex upward along the outer circumferential surface of the first coupling member 230 and the third protrusion 253 is curved to have a curvature corresponding to that of the second coupling member 240 . In addition, it is preferable that the first to third stone presses 251, 252, and 253 are integrally formed.

The second engaging member 260 includes a fourth protrusion 261 extending along the left edge of the first engaging member 230 and protruding downward from the first engaging member 230, A fifth protrusion 262 extending along the left edge of the main plate 210 and projecting downward from the main plate 210 and a second protrusion 262 extending along the left edge of the second engagement member 240 and extending downward from the second engagement member 240 And a sixth protrusion 263 protruding from the second protrusion 263.

The fourth protrusion 261 is curved so as to be convex upward along the outer circumferential surface of the first coupling member 230 and the sixth protrusion 263 is also curved with a curvature corresponding to the second coupling member 240 . Further, it is preferable that the fourth to sixth stone presses 261, 262, 263 are integrally formed.

Since the second latching member 260 is protruded downward with respect to the first coupling member 230, the main plate 210 and the second coupling member 240, the second latching member 260 of the roof panel 100, 1 engaging member 250 so as to block rainwater or snow from flowing into the body frames 200.

The solar cell panel 300 includes a coupling plate 301 coupled to a lower portion of the main plate 210 so that a top edge thereof contacts the interference member 212, And a plurality of solar cells 302 that generate electricity by light.

The coupling plate 301 is formed in a plate shape having a predetermined thickness and is formed to have an area corresponding to the through hole 211. The coupling plate 301 is preferably formed of a metallic material having excellent thermal conductivity so that heat generated from the solar cell 302 can be dissipated easily to the outside.

The solar cell 302 is provided on the upper surface of the coupling plate 301 so as to be exposed to the outside through the through hole 211. The N (negative) semiconductor and the P (positive) Lt; RTI ID = 0.0 > PN junction < / RTI > The solar cell 302 of the PN junction structure generates power by using the characteristic that the positive (+) and the electron (-) move in the semiconductor by the sunlight. The electricity generated from the solar cell 302 is supplied to a battery (not shown) to charge the rechargeable battery.

The joining frame 400 includes a contact plate 410 contacting the lower surface of the solar cell panel 300 and a fixing member 420 fixing the contact plate 410 to the main plate 210.

The contact plate 410 is formed in a plate shape having a predetermined thickness and is formed to have an area larger than the area of the coupling plate 301. The contact plate 410 is formed with a ventilation hole 411 penetrating in the vertical direction at a central portion so that a lower surface of the coupling plate 301 can be partially exposed. At this time, it is preferable that the ventilation hole 411 is formed to have an area smaller than the area of the coupling plate 301.

The contact plate 410 is formed with an insertion slot 412 extending along the upper edge of the heating plate 500 so that the first heating wire 501 of the heating unit 500 will be inserted. The insertion slot 412 is extended downward to a predetermined depth from the upper surface of the contact plate 410. When the main plate 210 is fixed to the main plate 210, As shown in Fig.

The contact plate 410 configured as described above is formed of a metallic material having excellent thermal conductivity so that the heat generated from the solar cell panel 300 can easily be dissipated or the heat generated from the heating unit 500 can be easily transferred. .

The fixing member 420 includes a screw portion extending in the vertical direction and threaded on the outer circumferential surface so as to be threadably engaged with the contact plate 410 through the main plate, And a head portion formed to have a cross-sectional area. A plurality of fixing members 420 are coupled to the main plate 210 and the contact plate 410 to fix the contact plate 410 to the main plate 210.

The heating unit 500 includes a first heating element 501 installed on the contact plate 410 and generating heat and a second heating element 501 disposed on the inner side of the coupling groove 231 of the first coupling member 230, And a power supply unit 503 connected to the first and second heating wires 501 and 502 to supply power to the first and second heating wires 501 and 502.

The first heating element 501 is inserted into the insertion slot 412 of the contact plate 410 and is arranged along the edge of the contact plate 410 along the insertion slot 412. The first heating element 501 generates heat by the power supplied from the power supply part 503. The second heating element 502 is inserted into a mounting slot formed on the inner surface of the first mating member 230 and arranged on the first mating member 230 along the mounting slot.

When the snow is accumulated on the upper surface of the main plate 210, the operator supplies power to the first and second heating wires 501 and 502 through the power supply unit 503 to generate heat of the first and second heating wires 501 and 502, It dissolves. The roof panel 100 provided with the solar cell according to the present invention configured as described above has an advantage of preventing the power generation efficiency of the solar cell from being reduced due to snow because it melts snow accumulated on the upper side of the solar cell by a heater have. The roof panel 100 provided with the solar cell according to the present invention is provided with an inflow blocking portion 220 to block rainwater or snow from entering the space between the outer surface of the building 15 and the main plate 210 Electronic equipment or the first and second heating wires 501 and 502 provided under the solar panel 300 are prevented from being defective due to rain or snow.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

100: Roof panel with solar cell
200: Body frame
210: main plate
220:
230: first coupling member
240: second coupling member
250: first latching member
260: second latching member
300: Solar panel
301: engaging plate
302: Solar cell
40: Coupling frame
410: Contact plate
420: Fixing member
500: heating section
501: first heating element
502: the second heating element
503: Power supply

Claims (8)

A body frame installed at an upper portion of the building;
A solar cell panel installed in the body frame and generating electricity through incident sunlight;
A coupling frame coupled to the body frame to fix the solar panel to the body frame;
And a heater installed in the coupling frame to generate heat to melt snow accumulated on the body frame or the solar cell panel.
The method according to claim 1,
The body frame
A main plate on which the solar cell panel is installed,
And an inflow blocking portion formed on the main plate to block rainwater or snow from entering the space between the outer side of the building and the main plate.
3. The method of claim 2,
The inflow-
A first engaging member extending forward from an edge of the front end of the main plate and protruding upward to form an engaging groove on a lower surface thereof;
And a second engaging member extending rearward from a rear end edge of the main plate and protruding upward with respect to the main plate so as to be inserted into the engaging groove of the first engaging member of the body frame adjacent to the rear side A roof panel with solar cells.
The method of claim 3,
The inflow-
A first engaging member extending along the right edge of the first engaging member, the main plate, and the second engaging member and protruding upward from the main plate,
A second engaging member extending along the left edge of the first engaging member, the main plate and the second engaging member and protruding downward with respect to the main plate so as to be engaged with the first engaging member of the body frame adjacent to the left, And a roof panel provided with the solar cell.
The method of claim 3,
Wherein the solar cell panel is located on a lower surface of the main plate so that an upper surface thereof is exposed to the outside through a through hole formed in the main plate,
The joining frame includes a contact plate contacting the lower surface of the solar cell panel and a fixing unit fixing the contact plate to the main plate,
Wherein the heating unit includes a first heating wire installed on the contact plate and generating heat, and a second heating wire installed on an inner side surface of the engagement groove of the first joining member to generate heat.
6. The method of claim 5,
Wherein the contact plate is formed with an insertion slot extending along a top edge thereof so that the first heating element can be inserted therein.
The method according to claim 6,
The main plate is protruded upward at a position adjacent to the through hole so as to prevent the snow stacked on one side from slipping toward the solar cell panel, and a blocking protrusion is formed extending along one side edge of the through hole Wherein the roof panel is provided with a solar cell.
8. The method of claim 7,
Wherein the first engaging member protrudes upward on the outer circumferential surface so as to reinforce strength and has a reinforcing protrusion extending a predetermined length along the forward and backward directions.

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