KR102555749B1 - Support structure and construction method for solar pannel - Google Patents

Abstract

The present invention relates to a solar panel support structure and construction method. One aspect of a solar panel support structure according to an embodiment of the present invention is a solar panel support structure for supporting a solar panel on an outer wall of a building: a solar panel, a junction fixed to the rear surface of the solar panel a panel unit including a box and a support frame to which the solar panel is fixed; and upper and lower brackets fixed to the outer wall to be spaced apart from each other in a vertical direction and supporting the panel unit; After the solar panel is fixed to the support frame to manufacture the panel unit, the panel unit is supported by the upper and lower brackets.

Description

Solar panel support structure and construction method {SUPPORT STRUCTURE AND CONSTRUCTION METHOD FOR SOLAR PANNEL}

The present invention relates to a solar panel support structure and construction method.

Solar panels are generally placed on rooftops, roofs, or grounds of buildings for efficient power generation by sunlight. For example, the solar panel is fixed to the frame at an angle inclined in the horizontal direction or in consideration of the altitude of the sun. Recently, as interest in new and renewable energy increases, solar panels are sometimes installed on the outer walls of high-rise buildings.

However, according to the solar panel support structure and construction method according to the prior art, the following problems occur.

First, in the case of installing the solar panel by simply fixing it to the frame as in the prior art, the solar panel must be fixed to the frame again after fixing the frame to the outer wall of the building. Therefore, according to the prior art, since the field work is relatively increased when fixing the solar panel, in particular, in the case of a high-rise building, there is a concern that the work time and cost for fixing the solar panel are excessively increased.

In addition, conventionally, since the solar panel is completely fixed to the frame, it is impossible to repair or replace the solar panel, or the entire solar panel and frame must be replaced, which is inconvenient. In particular, when solar panels are installed in high-rise buildings according to the prior art, not only the difficulty of work for replacing the solar panels and frames unnecessarily increases, but also increases time and cost.

And, conventionally, the size of the frame for fixing it is determined corresponding to the size of the solar panel. Therefore, according to the prior art, it is inconvenient to manufacture a frame having a size corresponding to the size of the solar panel, respectively.

Furthermore, when the solar panel is fixed to the outer wall of the building, not only cooling of the solar panel is impossible, but also rainwater flows downward along the solar panel and/or the frame. Therefore, according to the prior art, it is not easy to secure operational reliability and safety of the solar panel.

Republic of Korea Patent Registration No. 1103167 (Name: Building-integrated Solar Power Generation Device)

The present invention is to solve the problems described above, and an object of the present invention is to provide a solar panel support structure and construction method configured to enable simpler construction.

Another object of the present invention is to provide a solar panel support structure and construction method configured to enable easier maintenance and repair.

Another object of the present invention is to provide a solar panel support structure and construction method configured to more simply adjust the size according to the size of the solar panel.

Another object of the present invention is to provide a solar panel support structure and construction method configured to secure operation reliability and stability of the solar panel.

One aspect of a solar panel support structure according to an embodiment of the present invention for achieving the above object is a solar panel support structure for supporting a solar panel on an outer wall of a building: a solar panel, the sunlight a panel unit including a junction box fixed to a rear surface of the panel and a support frame to which the solar panel is fixed; and upper and lower brackets fixed to the outer wall to be spaced apart from each other in a vertical direction and supporting the panel unit; After the solar panel is fixed to the support frame to manufacture the panel unit, the panel unit is supported by the upper and lower brackets.

In one aspect of the embodiment of the present invention, in a state where the upper end of the support frame is caught on the upper bracket, when the support frame rotates around the upper end and then moves downward, the lower end of the support frame is attached to the lower bracket By being seated, the panel unit is supported by the upper and lower brackets.

In one aspect of the embodiment of the present invention, in a state in which the panel unit is supported by the upper and lower brackets, the solar panel fixed to the support frame is inclined downward at a predetermined angle from the upper end toward the lower end .

In one aspect of the embodiment of the present invention, the support frame is hung on the upper bracket, the upper frame coupled to the upper end of the solar panel; a lower frame seated on the lower bracket and coupled to a lower end of the solar panel; and a plurality of intermediate frames disposed between the upper and lower frames to connect the two, and fixed to a predetermined position by sliding between the upper and lower frames. Including, the number of the intermediate frame is variable according to the width of the upper and lower frames.

In one aspect of the embodiment of the present invention, the support frame is hung on the upper bracket, the upper frame coupled to the upper end of the solar panel; a lower frame seated on the lower bracket and coupled to a lower end of the solar panel; and a plurality of intermediate frames disposed between the upper and lower frames to connect the two, and fixed to a predetermined position by sliding between the upper and lower frames. The width of each of the intermediate frames is set regardless of the width of the upper and lower frames in a range where the sum of the widths of the plurality of intermediate frames is equal to the width of the upper and lower frames, and The height is set according to the distance between the upper and lower frames on which the intermediate frame is disposed.

In one aspect of the embodiment of the present invention, the upper frame has a predetermined length and width, the upper frame body is hung on the upper bracket; and a pair of upper coupling ribs each extending downwardly from the front surface of the upper frame body and defining an upper coupling groove to which the upper end of the solar panel is coupled therebetween. The lower frame includes a lower frame body having a predetermined length and width and having a lower end seated on the lower bracket; and a pair of lower coupling ribs each extending obliquely upward from the front surface of the lower frame body to face the upper coupling rib and defining a lower coupling groove to which the lower end of the solar panel is coupled therebetween. Including, the lower coupling groove is located in the front compared to the upper coupling groove.

In one aspect of the embodiment of the present invention, a water guide groove for guiding water flowing from top to bottom in a horizontal direction is formed on the front surface of the upper frame body corresponding to the upper side of the upper coupling rib.

In one aspect of the embodiment of the present invention, the lower frame further includes a connecting portion that extends forward from the front surface of the lower frame body, has the lower coupling rib at its front end, and has a plurality of ventilation holes.

In one aspect of the embodiment of the present invention, the connecting portion is formed to be curved with a predetermined curvature toward the front end provided with the lower coupling rib at one end extending from the front surface of the lower frame body.

In one aspect of the embodiment of the present invention, the lower frame is provided with a water transfer prevention rib for preventing water flowing along the solar panel from being transferred to the connection part.

In one aspect of the embodiment of the present invention, the water transfer prevention rib extends downward from the front end of the connecting portion.

In one aspect of the embodiment of the present invention, an upper insertion groove and a lower insertion groove are formed at the lower end of the upper frame and at the upper end of the lower frame, respectively, and at the upper and lower ends of the middle frame, insert into the upper and lower insertion grooves, respectively Upper and lower insertion protrusions are provided, respectively.

In one aspect of the embodiment of the present invention, the intermediate frame includes a first intermediate frame formed in a plate shape having a preset length and width; and a second intermediate frame formed in a plate shape having a predetermined length and width and having a plurality of ventilation holes. Including, the first and second intermediate frames are alternately disposed in the horizontal direction.

In one aspect of the embodiment of the present invention, a harness fixing holder for fixing a harness electrically connected to the junction box is provided on the first intermediate frame.

In one aspect of the solar panel construction method according to an embodiment of the present invention, in the solar panel construction method for supporting the solar panel on the outer wall of a building: the solar panel to which the junction box is fixed to the back surface is a support frame a unit manufacturing step in which a panel unit is manufactured by being fixed to the unit; A bracket fixing step in which upper and lower brackets are fixed to the outer wall so as to be spaced apart from each other in a vertical direction; and a unit support step in which the panel unit is supported by the upper and lower brackets. includes

In one aspect of the embodiment of the present invention, the unit manufacturing step, the upper and lower frames are connected by a plurality of intermediate frames frame manufacturing step of manufacturing a support frame; and a panel fixing step of fixing the solar panel to the support frame. includes

In one aspect of the embodiment of the present invention, in the frame manufacturing step, the upper and lower insertion protrusions of any one of the intermediate frames are inserted into and fixed to the upper insertion groove of the upper frame and the lower insertion groove of the lower frame, respectively In, the upper and lower insertion protrusions of the rest of the intermediate frame are inserted into the upper insertion groove and the lower insertion groove of the upper frame, and then slid and fixed to a predetermined position in order along them, thereby manufacturing the support frame.

In one aspect of the embodiment of the present invention, in the panel fixing step, the solar panel is fixed to the support frame so as to be disposed inclined downward at a predetermined angle from the upper end toward the lower end.

In one aspect of the embodiment of the present invention, in the panel fixing step, after the upper and lower ends of the solar panel are coupled to the upper and lower coupling grooves of the support frame, respectively, the solar panel and the upper and lower frames sealant is fixed by

In one aspect of the embodiment of the present invention, in the unit supporting step, in a state where the upper end of the support frame is caught on the upper bracket, the panel unit rotates about the upper end so that the lower end is positioned in the state of the lower bracket When moving downward in the down state, the lower end of the support frame is seated on the lower bracket, so that the panel unit is supported by the upper and lower brackets.

According to the solar panel support structure and construction method according to the embodiment of the present invention, the following effects can be expected.

First, according to an embodiment of the present invention, a panel unit in which a solar panel and a support frame are pre-assembled is supported by two brackets fixed to an outer wall of a building without using separate fasteners. Therefore, according to an embodiment of the present invention, it is possible to simply construct a solar panel by minimizing on-site work.

In addition, in an embodiment of the present invention, only a panel unit including a solar panel that needs to be replaced or repaired can be separated from the bracket. Therefore, according to the embodiment of the present invention, it is possible to simply maintain and repair the solar panel.

In the embodiment of the present invention, the height of the support frame is substantially changed according to the height of the support plate constituting the support frame. Therefore, according to an embodiment of the present invention, it is possible to simply vary the size of the support frame to correspond to the size of the solar panel.

In addition, in the embodiment of the present invention, air for cooling the solar panel and the junction box may be introduced into the interior of the panel unit, that is, the space between the solar panel and the support frame through the ventilation holes formed in the support frame. there is. In addition, in the embodiment of the present invention, the transmission of rainwater from the upper panel unit or the transmission of rainwater to the lower panel unit may be blocked by the rainwater guide groove and the rainwater guide rib provided in the support frame. Therefore, according to an embodiment of the present invention, overheating of the solar panel or/and the junction box is prevented, thereby ensuring operational reliability and preventing deterioration in safety due to inflow of rainwater.

1 is a perspective view showing a solar panel support structure according to an embodiment of the present invention;
Figure 2 is a longitudinal cross-sectional view showing an embodiment of the present invention.
Figure 3 is a flow chart showing a solar panel construction method according to an embodiment of the present invention.

Hereinafter, a solar panel support structure according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a solar panel support structure according to an embodiment of the present invention, and FIG. 2 is a longitudinal cross-sectional view showing an embodiment of the present invention.

1 and 2, the solar panel support structure according to this embodiment is for supporting the solar panel 1100 on the outer wall W of the building, and includes a panel unit 1000 and upper and lower brackets. (2000A) includes (2000B). The panel unit 1000 includes the solar panel 1100, a junction box 1200 fixed to a rear surface of the solar panel 1100, and a support frame 1300 to which the solar panel 1100 is fixed. include The upper and lower brackets 2000A and 2000B are fixed to the outer wall W to be spaced apart from each other in the vertical direction, and the panel unit 1000 is supported by the upper and lower brackets 2000A and 2000B. , the panel unit 1000 is supported on the outer wall (W).

In particular, in the present embodiment, in a state where the upper end of the support frame 1300 is caught on the upper bracket 2100, the panel unit 1000 pivots around the upper end so that the lower end is the lower bracket 2000B. When moving downward from the position in the state of , the lower end of the support frame 1300 is seated on the lower bracket 2000B, so that the panel unit 1000 is attached to the upper and lower brackets 2000A and 2000B. supported In addition, in this embodiment, the solar panel 1100, in a state in which it is fixed to the support frame 1300, is disposed inclined downward at a predetermined angle from the upper end toward the lower end.

More specifically, the solar panel 1100 generates electric power by converting sunlight, that is, light energy, into electric energy using a photovoltaic effect. The junction box 1200 is to transfer the power generated by the solar panel 1100 to an inverter (not shown). The junction box 1200 is fixed to the rear surface of the solar panel 1100 . For example, the solar panel 1100 is connected to the support frame 1300 by a sealant (not shown) in a state in which upper and lower ends are coupled to upper and lower coupling grooves 2100B and 2200A, which will be described later. can be completely fixed.

Meanwhile, the support frame 1300 includes an upper frame 1310, a lower frame 1320, and an intermediate frame 1330. Substantially, the support frame 1300 is formed by assembling the upper frame 1310 , the lower frame 1320 and the middle frame 1330 .

The upper frame 1310 is hung on the upper bracket 2100 in a state in which the upper end of the solar panel 1100 is coupled. In this embodiment, the upper frame 1310 includes an upper frame body 1311 and a pair of upper coupling ribs 1313.

The upper frame body 1311 may be formed in a plate shape having a preset length and width. The top of the upper frame 1310 is substantially caught on the upper bracket 2100 .

An upper insertion groove 1311A is formed in the upper frame body 1311. The upper insertion groove 1311A is defined by recessing the lower central portion of the upper frame body 1311 upward, and is an upper insertion protrusion (to be described later) to connect the upper frame 1310 and the middle frame 1330 ( 1331A) is inserted.

In addition, a water guide groove 1311B is formed in the upper frame body 1311. The water guide groove 1311B serves to guide water flowing from top to bottom along the front surface of the upper frame body 1311 in a horizontal direction. To this end, the water guide groove 1311B may be defined by long depressions in the horizontal direction of a front part of the upper frame body 1311 corresponding to the upper side of the upper coupling rib 1313.

The upper coupling rib 1313 defines an upper coupling groove 1313A to which the upper end of the solar panel 1100 is coupled therebetween. To this end, the upper coupling ribs 1313 each extend downwardly from the front surface of the upper frame body 1311 .

Meanwhile, the lower frame 1320 is seated on the lower bracket 2000B in a state in which the lower end of the solar panel 1100 is coupled. The lower frame 1320 may include a lower frame body 1321, a pair of lower coupling ribs 1323, and a connection portion 1325.

The lower frame body 1321 may be formed in a plate shape having a preset length and width. A lower insertion groove 1321A is formed in the lower frame body 1321. The lower insertion groove 1321A is formed by recessing the upper center portion of the lower frame body 1321 downward, and a lower insertion protrusion 1331B, which will be described later, is inserted into the lower insertion groove 1321A.

The lower coupling ribs 1323 each extend upwardly to face the upper coupling rib 1313 from the front surface of the lower frame body 1321 . And between the lower coupling ribs 1323, a lower coupling groove 1323A to which the lower end of the solar panel 1100 is coupled is defined. In particular, in this embodiment, the lower coupling groove (1323A) is located in the front compared to the upper coupling groove (1313A). Accordingly, the solar panel 1100 may be inclinedly supported on the support frame 1300 at a preset angle.

The connecting portion 1325 extends forward from the front surface of the lower frame body 1321 . And the lower coupling rib 1323 is provided at the front end of the connection part 1325. Substantially, the lower coupling rib 1323 will be positioned relatively forward compared to the upper coupling rib 1313 by the length of the connecting portion 1325 .

In particular, in this embodiment, the connecting portion 1325 is formed to be curved with a predetermined curvature from one end extending from the front surface of the lower frame body 1321 toward the front end where the lower coupling rib 1323 is provided. do. This is to prevent water from being transferred between the lower frame body 1321 and the lower coupling rib 1323 along the connecting portion 1325 . For example, the connecting portion 1325 may be curved such that its central portion is positioned upward relative to its one end and its tip.

In addition, in this embodiment, a plurality of ventilation holes 1325A are formed in the connecting portion 1325. The ventilation hole 1325A is a place where air is sucked into the interior of the panel unit 1000, that is, a space between the solar panel 1100 and the support frame 1300. Substantially, the solar panel 1100 or/and the junction box 1200 may be cooled by the air sucked into the panel unit 1000 through the ventilation hole 1325A.

In addition, a water transfer prevention rib 1327 is provided on the lower frame 1320 . The water transfer prevention rib 1327 serves to prevent water flowing along the solar panel 1100 from being transferred to the connection part 1325 . To this end, the water transfer prevention rib 1327 extends downward from the front end of the connection part 1325 .

Meanwhile, the intermediate frame 1330 is disposed between the upper and lower frames 1310 and 1320 to connect the two. In particular, in this embodiment, the height of the intermediate frame 1330 is determined according to the size of the solar panel 1100 . In other words, in a state where the upper and lower ends are coupled to the upper coupling groove 1313A and the lower coupling groove 1323A, in proportion to the projection of the solar panel 1100 in the horizontal direction, the intermediate The height of frame 1330 will be determined.

More specifically, the intermediate frame 1330 may be formed in a plate shape having a preset length and width. Upper and upper and lower insertion protrusions 1331A and 1331B are provided at the upper and lower ends of the intermediate frame 1330, respectively. The upper and lower insertion protrusions 1331A and 1331B extend upward and downward from the upper and lower ends of the intermediate frame 1330, respectively, and are inserted into the upper and lower insertion grooves 1311A and 1321A, respectively.

In particular, in this embodiment, the intermediate frame 1330 includes first and second intermediate frames 1331 and 1332 . The first and second intermediate frames 1331 and 1332 are each formed in a plate shape having a preset length and width. However, a plurality of ventilation holes 1332A through which air is sucked into the panel unit 1000 are formed in the second intermediate frame 1332 . Also, the first and second intermediate frames 1331 and 1332 are alternately disposed in a horizontal direction. This is to secure the rigidity of the support frame 1300 and to cool the solar panel 1100 or/and the junction box 1200 at the same time. In other words, the causticity of the panel unit 1000 is secured by the first intermediate frame 1331, and the ventilation hole 1332A is formed in the second intermediate frame 1332, through which the solar panel Cooling of 1100 or/and junction box 1200 is also possible. For example, the first intermediate frame 1331 is disposed at both ends of the upper and lower frames 1310 and 1320 in a horizontal direction, and the upper and lower frames corresponding to the first intermediate frame 1331 are disposed. The second intermediate frame 1332 may be disposed at the center of (1310) and (1320).

A holder 1331C for fixing a harness is provided on the first intermediate frame 1331. The harness fixing holder 1331C is for fixing the harness H electrically connected to the junction box 1200 . The harness H substantially fixed to the harness fixing holder 1331C may be connected to the inverter or to the junction box 1200 of another adjacent panel unit 1000.

Next, the upper and lower brackets 2000A and 2000B are vertical so that the panel unit 1000, substantially, the upper end of the support frame 1300 can be caught and the lower end of the support frame 1300 can be seated. are spaced apart from each other in the direction The upper and lower brackets 2000A and 2000B are configured identically, and are classified according to which part of the upper or lower part of the panel unit 1000 is supported for convenience. Therefore, hereinafter, the configuration of the upper and lower brackets 2000A and 2000B will be described by naming the same names. In this embodiment, the upper and lower brackets 2000A and 2000B each include a bracket body 2100 and a support rib 2200.

The bracket body 2100 may be formed in a plate shape having a predetermined area, for example, a rectangular plate shape. The bracket body 2100 is fixed to the outer wall (W) or a separate member fixed to the outer wall (W) by a fastener (S).

And, the support rib 2200 is provided on the front surface of the bracket body 2100 . The support rib 2200 is a hanging space 2000S1 where the upper end of the support frame 1300 is hung together with the front surface of the bracket body 2100 or a seating space 2000S2 where the lower end of the support frame 1300 is seated. ) is defined. To this end, the support rib 2200 includes a horizontal extension part 2210 and a vertical extension part 2220, respectively. The horizontal extension part 2210 extends from the front surface of the bracket body 2100 toward the front. At this time, the horizontal extension part 2210 may be orthogonal to the front surface of the bracket body 2100. The vertical extension part 2220 extends vertically from the front end of the horizontal extension part 2210 . In this case, the vertical extension part 2220 may be orthogonal to the front end of the horizontal extension part 2210, that is, parallel to the front surface of the bracket body 2100. In this embodiment, the lower end of the vertical extension 2220 is relatively longer than the upper end of the vertical extension 2220 based on the horizontal extension 2210 . Therefore, the seating space 2000S2 is provided between the front surface of the bracket body 2100 corresponding to the lower side of the horizontal extension part 2210, the bottom surface of the horizontal extension part 2210 and the back surface of the vertical extension part 2220. is defined, and the seating space ( 2000S2) is defined.

Also, in this embodiment, the upper and lower brackets 2000A and 2000B each include a pair of gasket members 2300. The gasket member 2300 is provided on the front surface of the bracket body 2100 corresponding to the upper and lower sides of the horizontal extension part 2210, respectively. The gasket member 2300 maintains airtightness between the panel unit 1000 and the upper and lower brackets 2000A and 2000B, and between the rear surface of the support frame 1300 and the front surface of the bracket body 2100. At the same time as this is secured, the impact between the two can be buffered.

Hereinafter, a solar panel construction method according to an embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

3 is a flowchart showing a solar panel construction method according to an embodiment of the present invention.

Referring to FIG. 3 , the solar panel construction method according to this embodiment includes a unit manufacturing step (S100), a bracket fixing step (S200), a unit supporting step (S300), and a unit connecting step (S400).

More specifically, in the unit manufacturing step (S100), the panel unit 1000 is manufactured. Substantially, in the unit manufacturing step (S100), the solar panel 1100 to which the junction box 1200 is fixed is fixed to the support frame 1300 to manufacture the panel unit 1000. In this embodiment, the unit manufacturing step (S100) includes a frame manufacturing step (S100) and a panel fixing step (S120).

In the frame manufacturing step (S110), the upper and lower frames 1310 and 1320 are connected by a plurality of intermediate frames 1330 to manufacture the support frame 1300. In the frame manufacturing step (S110), first, any one of the upper and lower insertion protrusions 1331A and 1331B of the intermediate frame 1330 is inserted into the upper insertion groove 1311A of the upper frame 1310 and the lower frame The lower insertion grooves 1321A of 1320 are respectively inserted and fixed. Next, in the frame manufacturing step (S110), the upper and lower insertion protrusions 1331A and 1331B of the intermediate frame 1330 are inserted into the upper insertion groove 1311A and the lower insertion groove of the upper frame 1310. After being inserted into (1321A), the support frame 1300 is produced by sequentially sliding and fixing to a predetermined position along it.

Substantially, after being fixed to one end of the upper and lower frames 1310 and 1320 of the first intermediate frame 1331 among the intermediate frames 1330 in the horizontal direction, one or more second intermediate frames 1330 The middle frame 1332 may be fixed by sliding between the upper and lower frames 1310 and 1320 . Finally, when the second intermediate frame 1332 is fixed, another first intermediate frame 1331 may be fixed to the other end of the upper and lower frames 1310 and 1320 in the horizontal direction.

In addition, in the frame manufacturing step (S110), the size of the solar panel 1100, substantially, as will be described later, the solar panel 1100 fixed to the support frame 1300 inclined at a predetermined angle The height of the intermediate frame 1330 is determined in proportion to the projection in the horizontal direction of .

Meanwhile, in the panel fixing step (S120), the solar panel 1100 is fixed to the support frame 1300. In particular, in the present embodiment, in the panel fixing step (S120), the solar panel 1100 is fixed to the support frame 1300 so as to be disposed inclined downward at a predetermined angle from the upper end toward the lower end. Also, in the panel fixing step (S120), the harness H electrically connected to the junction box 1200 is fixed to the harness fixing holder 1331C of the intermediate frame 1330. For example, in the panel fixing step (S120), after the upper and lower ends of the solar panel 1100 are coupled to the upper and lower coupling grooves 1313A and 1323A of the support frame 1300, respectively, the sun It may be fixed to the light panel 1100 and the upper and lower frames 1310 and 1320 by a sealant (not shown). At this time, the sealant is pre-injected into the upper and lower coupling grooves 1313A and 1323A, or after the upper and lower ends of the solar panel 1100 are coupled to the upper and lower coupling grooves 1313A and 1323A. may be injected.

Next, in the bracket fixing step (S200), the upper and lower brackets 2000A and 2000B are fixed to the outer wall W to be spaced apart from each other in the vertical direction. As described above, in the present embodiment, in the bracket fixing step (S200), the upper and lower brackets 2000A and 2000B are directly fixed to the outer wall W or separately fixed to the outer wall W. can be fixed in the absence of

In the unit supporting step (S300), the panel unit 1000 is supported by the upper and lower brackets 2000A and 2000B. In particular, in the present embodiment, in the unit support step (S300), in a state where the upper end of the support frame 1300 is caught on the upper bracket 2100, the panel unit 1000 rotates around the upper end, When the lower end moves downward from the position of the lower bracket 2000B, the lower end of the support frame 1300 is seated on the lower bracket 2000B, so that the panel unit 1000 moves to the upper and lower brackets 2000B. It is supported by the lower brackets 2000A and 2000B. Therefore, according to the present embodiment, the panel unit 1000 is supported by the upper and lower brackets 2000A and 2000B without using a separate fastener, so that the panel unit 1000 can be more easily installed. Support is possible, and at the same time, separation of the panel unit 1000 for maintenance and repair can be made more easily.

Finally, in the unit connection step (S400), the junction boxes 1200 of the plurality of panel units 1000 respectively supported by the upper and lower brackets 2000A and 2000B are electrically connected by a harness H. Connected. Of course, when only one panel unit 1000 is supported by the upper and lower brackets 2000A and 2000B, the panel unit connection step (S400) will be deleted.

Within the scope of the basic technical idea of the present invention, many other modifications are possible to those skilled in the art, and the scope of the present invention should be interpreted based on the appended claims. will be.

1000: panel unit 1100: solar panel
1200: junction box 1300: support frame
1310: upper frame 1320: lower frame
1330: middle frame 2000A, 2000B: bracket

Claims (20)

In the solar panel support structure for supporting the solar panel 1100 on the outer wall (W) of the building:
A panel unit 1000 including a solar panel 1100, a junction box 1200 fixed to a rear surface of the solar panel 1100, and a support frame 1300 to which the solar panel 1100 is fixed; and
upper and lower brackets 2000A and 2000B fixed to the outer wall W and spaced apart from each other in the vertical direction and supporting the panel unit 1000; including,
The support frame 1300,
An upper frame 1310 that is hung on the upper bracket 2000A and coupled to an upper end of the solar panel 1100;
a lower frame 1320 seated on the lower bracket 2000B and coupled to a lower end of the solar panel 1100; and
A plurality of intermediate frames 1330 disposed between the upper and lower frames 1310 and 1320 to connect the two, and sliding between the upper and lower frames 1310 and 1320 to be fixed at predetermined positions; including,
The upper and lower ends of the solar panel 1100 sliding in the horizontal direction with respect to the support frame 1300 are detachably coupled to the upper frame 1310 and the lower frame 1320, respectively, to be fixed to the support frame 1300. so that the panel unit 1000 is manufactured,
The upper and lower ends of the panel unit 1000 are positioned at the upper and lower brackets 2000A to prevent interference in separation from the upper and lower brackets 2000A and 2000B by other panel units 1000 adjacent to each other vertically. Solar panel support structure supported on (2000B).
According to claim 1,
In a state where the upper end of the support frame 1300 is caught on the upper bracket 2000A, when the support frame 1300 rotates around the upper end and moves downward, the lower end of the support frame 1300 moves downward. A solar panel support structure in which the panel unit 1000 is supported by the upper and lower brackets 2000A and 2000B by being seated on the lower bracket 2000B.
According to claim 1,
In a state in which the panel unit 1000 is supported by the upper and lower brackets 2000A and 2000B, the solar panel 1100 fixed to the support frame 1300 has a preset direction from the upper end toward the lower end. A solar panel support structure that is disposed at an angle downward.
According to claim 1,
The solar panel support structure in which the number of the intermediate frames 1330 is varied according to the widths of the upper and lower frames 1310 and 1320.
According to claim 1,
The width of each of the intermediate frames 1330 is the upper and lower frames 1310 ( 1320) is set regardless of the width,
The height of the intermediate frame 1330 is set according to the distance between the upper and lower frames 1310 and 1320 on which the intermediate frame 1320 is disposed.
According to claim 4 or 5,
The upper frame 1310,
an upper frame body 1311 having a preset length and width and having an upper end of which is hung on the upper bracket 2000A; and
A pair of upper coupling ribs 1313 each extending downwardly from the front surface of the upper frame body 1311 and defining an upper coupling groove 1313A to which the upper end of the solar panel 1100 is coupled therebetween; including,
The lower frame 1320,
a lower frame body 1321 having a predetermined length and width and having a lower end seated on the lower bracket 2000B; and
Defining a lower coupling groove 1323A extending upwardly from the front surface of the lower frame body 1321 to face the upper coupling rib 1313 and to which the lower end of the solar panel 1100 is coupled therebetween a pair of lower coupling ribs 1323; including,
The lower coupling groove (1323A) is a solar panel support structure positioned in front compared to the upper coupling groove (1313A).
According to claim 6,
A solar panel support structure in which a water guide groove 1311B is formed on the front surface of the upper frame body 1311 corresponding to the upper side of the upper coupling rib 1313 to guide water flowing from upper to lower direction in a horizontal direction. .
delete delete delete delete delete delete delete In the solar panel construction method for supporting the solar panel 1100 on the outer wall (W) of the building:
A unit manufacturing step (S100) of manufacturing the panel unit 1000 by fixing the solar panel 1100 to the back surface of which the junction box 1200 is fixed to the support frame 1300;
Bracket fixing step (S200) of fixing upper and lower brackets (2000A) (2000B) to the outer wall (W) spaced apart from each other in the vertical direction; and
a unit supporting step (S300) in which the panel unit 1000 is supported by the upper and lower brackets 2000A and 2000B; including,
In the unit manufacturing step (S100),
A frame manufacturing step (S110) in which the upper and lower frames 1310 and 1320 are connected by a plurality of intermediate frames 1330 to manufacture the support frame 1300; and
The upper and lower ends of the solar panel 1100 sliding in the horizontal direction with respect to the support frame 1300 are detachably coupled to the upper frame 1310 and the lower frame 1320, respectively, to be fixed to the support frame 1300. Panel fixing step (S120); including,
In the unit support step (S300),
The upper and lower ends of the panel unit 1000 are positioned at the upper and lower brackets 2000A to prevent interference in separation from the upper and lower brackets 2000A and 2000B by other panel units 1000 adjacent to each other vertically. Solar panel construction method supported by (2000B).
delete According to claim 15,
In the frame manufacturing step (S110),
The upper and lower insertion protrusions 1331A and 1331B of the intermediate frame 1330 are the upper insertion groove 1311A of the upper frame 1310 and the lower insertion groove 1321A of the lower frame 1320 In a state in which each is inserted and fixed, the remaining upper and lower insertion protrusions 1331A and 1331B of the intermediate frame 1330 are inserted into the upper insertion groove 1311A and the lower insertion groove 1321A of the upper frame 1310. After being inserted, the solar panel construction method in which the support frame 1300 is manufactured by sliding and fixing to a predetermined position in turn along it.
According to claim 15,
In the panel fixing step (S120),
The solar panel 1100 is fixed to the support frame 1300 so as to be disposed inclined downward at a predetermined angle from the top to the bottom.
According to claim 15,
In the panel fixing step (S120),
After the upper and lower ends of the solar panel 1100 are coupled to the upper and lower coupling grooves 1313A and 1323A of the support frame 1300, respectively, the solar panel 1100 and the upper and lower frames 1310 ) (1320) Solar panel construction method fixed by sealant.
According to claim 15,
In the unit support step (S300),
In a state where the upper end of the support frame 1300 is caught on the upper bracket 2000A, the panel unit 1000 rotates around the upper end so that the lower end is positioned in the state of the lower bracket 2000B When moving downward, the lower end of the support frame 1300 is seated on the lower bracket 2000B, so that the panel unit 1000 is supported by the upper and lower brackets 2000A and 2000B. Solar panel construction method .

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