KR102320611B1 - Cover structure that supports solar power generation while maintaining the sealing function by bonding the dome structure and the solar panel - Google Patents

Abstract

Disclosed is a cover structure for supporting solar power generating while maintaining a sealing function by bonding a dome structure and a solar panel. The cover structure comprises: a dome structure; a main frame (250) supported on the dome structure; a first tilting frame (210) arranged at one side of the upper end of the main frame (250), assembled to be able to rotate with respect to the main frame (250) and having a first solar panel (101) supported thereon; a second tilting frame (220) arranged at the other side of the upper end of the main frame (250), assemble to be able to rotate with respect to the main frame (250) and having a second solar panel (102) supported thereon; a first fixer (230) assembled to the first tilting frame (210) and pressurizing and fixing the first solar panel (101) to the first tilting frame (210); and a second fixer (240) assembled to the second tilting frame (220) and pressurizing and fixing the second solar panel (102) to the second tilting frame (220).

Description

COVER STRUCTURE THAT SUPPORTS SOLAR POWER GENERATION WHILE MAINTAINING THE SEALING FUNCTION BY BONDING THE DOME STRUCTURE AND THE SOLAR PANEL

The present invention relates to a cover structure, and more particularly, to a cover structure in which a dome structure and a solar panel are bonded to each other to support photovoltaic power generation while maintaining a sealing function.

In general, storage tanks for storing products such as crude oil or oil or requiring airtightness and chemical resistance, storage tanks for treating sewage and wastewater, concentration tanks for treating sewage, fermenters that generate odors by floating matter, etc. It is made of metal to prevent evaporation or corrosion, and to prevent odors and foreign substances from entering.

In particular, in buildings such as sewage treatment plants, enrichment tanks, and fermentation tanks, the spaces where odors and toxic gases are emitted prevent odors and toxic gases from leaking out and, at the same time, to minimize corrosion by toxic gases. A strong paint is applied to the surface, and internal and external structures are constructed using metal materials such as aluminum.

In addition, a cover structure is needed for the purpose of securing and protecting clear water from the inflow of yellow dust and fine dust or the penetration of larvae in waterworks offices and water purification plants.

In this case, the roof of the internal and external structures is made of an arch-shaped or dome-shaped roof in order to lighten the weight but increase the area.

As a prior art related to the roof structure of a building such as a sewage treatment plant, a waterworks plant, or a water purification plant, there is Republic of Korea Patent No. 10-1470325, the prior art relates to a 'roof installation structure for a sewage treatment plant using a solar panel', By placing solar panels on the roof of the treatment plant, the double effect of electricity production through solar power generation can be obtained.

However, in the prior art, the configuration of the fixing bracket for this is limited because the solar panel has to be disposed in an inclined shape at a certain angle, and the process of separating the solar panel for replacement and repair by directly fixing the solar panel is very cumbersome.

In addition, in the case of an arch-shaped or dome-shaped structure, since the roof is formed in a curved surface, there is a problem in that different types of frame structures must be installed according to the curvature.

Republic of Korea Patent Registration No. 10-1470325 Republic of Korea Patent No. 10-1796936

An object of the present invention is to provide a cover structure in which a dome structure and a solar panel are bonded to each other to prevent odors through a sealing function and to prevent inflow of external larvae, etc., and to support solar power generation.

An object of the present invention is to provide a cover structure capable of maximizing photovoltaic power generation efficiency by installing a photovoltaic panel installed on the cover structure to adjust the angle of the frame according to the curvature of the dome structure.

One aspect of the present invention for achieving the above object provides a cover structure that supports solar power generation while maintaining a sealing function by bonding a dome structure and a solar panel to each other.

The cover structure may include a dome structure; a main frame 250 supported on the dome structure; a first tilting frame 210 disposed at an upper end of the main frame 250 and rotatably assembled with respect to the main frame 250 and on which the first solar panel 101 is supported; a second tilting frame 220 disposed on the other side of the upper end of the main frame 250 and rotatably assembled with respect to the main frame 250 and on which the second solar panel 102 is supported; a first fixer 230 assembled to the first tilting frame 210 and pressing and fixing the first solar panel 101 to the first tilting frame 210; and a second fixer 240 assembled to the second tilting frame 220 and pressing and fixing the second solar panel 102 to the second tilting frame 220; A cover structure is provided.

a first tilting shaft connecting the first tilting frame and the main frame so that the first tilting frame is rotatable; and a second tilting shaft connecting the second tilting frame and the main frame so that the second tilting frame is rotatable.

When the first tilting frame and the second tilting frame contact each other, the first solar panel and the second solar panel may be arranged in a line.

The first fixer may be disposed to surround an upper edge of the first solar panel, and the second fixer may be disposed to surround an upper edge of the second solar panel.

A first fastening member that penetrates through the first fixer 230 and is fastened to the first tilting frame 210 and presses the first solar panel 101 to the first tilting frame 210 through a fastening force. (261); A second fastening member that penetrates through the second fixer 240 and is fastened to the second tilting frame 220 and presses the second solar panel 102 to the second tilting frame 220 through a fastening force. 262; a lower end of the first fixer may be spaced apart from an upper surface of the first tilting frame, and a lower end of the second fixer may be spaced apart from an upper surface of the second tilting frame.

First, according to the present invention, the dome structure and the solar panel are bonded to each other to prevent odors through the sealing function and to prevent the inflow of external larvae, etc., and to support solar power generation.

Second, according to the present invention, the solar panel installed so as to adjust the angle of the frame according to the curvature of the dome structure is installed on the cover structure, thereby maximizing the solar power generation efficiency.

Third, the present invention has the advantage that it can be installed in various types of dome structures because the tilting angle t is freely set according to the curvature of the dome structure.

Fourth, the present invention has an advantage that can easily solve the bending deformation formed in the first tilting assembly or the second tilting assembly through the first tilting axis and the second tilting axis.

Fifth, the present invention has an advantage in that the pressing force applied to the solar panel can be adjusted by adjusting the interval between the fixer and the tilting frame through the fastening member.

Sixth, the spacer according to the present invention can maintain the tilting angle t by pressing the first fixer and the second fixer, and through this, the first solar panel 101 and the second solar panel 102 . It has the advantage of maintaining the installation angle.

1 is a partial perspective view showing a cover structure supporting photovoltaic power generation while maintaining a sealing function by bonding a dome structure and a photovoltaic panel to each other according to a first embodiment of the present invention.
2 is a plan view showing the solar panels arranged in a plane in the cover structure according to the first embodiment of the present invention.
3 is a plan view showing the solar panels tilted and arranged in the cover structure according to the first embodiment of the present invention.
4 is a front view of the cover structure according to the first embodiment of the present invention.
FIG. 5 is a partially enlarged view of FIG. 4 .
FIG. 6 is a front cross-sectional view of FIG. 5 .
FIG. 7 is an exemplary view of tilting of FIG. 5 .
8 is a front view of a cover structure in which a dome structure and a photovoltaic panel are bonded to each other according to a second embodiment of the present invention to support photovoltaic power generation while maintaining a sealing function.
FIG. 9 is a partially enlarged view of FIG. 8 .
10 is a front view showing a cover structure supporting photovoltaic power generation while maintaining a sealing function by bonding a dome structure and a solar panel to each other according to a third embodiment of the present invention.
11 is a cross-sectional view of the spacer shown in FIG. 10 .
12 is a front view showing a cover structure supporting photovoltaic power generation while maintaining a sealing function by bonding a dome structure and a solar panel to each other according to a fourth embodiment of the present invention.
13 is a view showing a detailed structure according to the first embodiment in the dome structure of the shape shown in FIG. 12 .
14 is a view showing a detailed structure according to the second embodiment in the dome structure of the shape shown in FIG. 12 .
15 is a plan view illustrating a cover structure in which a dome structure and a photovoltaic panel are bonded to each other according to a fifth embodiment of the present invention to support photovoltaic power generation while maintaining a sealing function.

Advantages and features of the present invention and methods of achieving them will 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 these embodiments allow the disclosure of the present invention to be complete, and common knowledge in the art to which the present invention pertains It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout.

1 is a partial perspective view showing a cover structure supporting solar power generation while maintaining a sealing function by bonding a dome structure and a solar panel to each other according to a first embodiment of the present invention, and FIG. 2 is a first embodiment of the present invention A plan view showing photovoltaic panels arranged in a plane in the cover structure according to the embodiment, FIG. 3 is a plan view showing the photovoltaic panels tilted and arranged in the cover structure according to the first embodiment of the present invention, FIG. 4 is a front view of the cover structure according to the first embodiment of the present invention, FIG. 5 is a partially enlarged view of FIG. 4 , FIG. 6 is a front sectional view of FIG. 5 , and FIG. 7 is an exemplary tilting view of FIG. 5 .

The cover structure according to the present embodiment may be configured in a form in which the solar panel 100 is bonded to a structure having a curved surface, such as a dome structure 500 .

Here, the dome structure may correspond to a structure covering the upper part of an oil storage facility, an oil storage facility, a sewage treatment plant, a water storage facility or a water purification plant of a waterworks office, or other storage tanks.

In particular, the dome structure 500 constituting a part of the cover structure proposed in the present invention is configured to form a water channel in rainy weather, so that the dome structure that can remove the sediment generated during rain through the water channel can be targeted. , specifically, the waterway-type dome structure proposed in Korean Patent No. 10-2215809 may be targeted.

However, it is not necessarily interpreted as being limited thereto, and the dome structure according to the present invention may be broadly interpreted so as to be applicable to all other dome-shaped structures formed with various curvatures.

In the cover structure according to the present embodiment, the solar panel 100 is installed on the dome structure. Although the dome structure is partially flat, it is difficult to install a flat-panel solar panel because it has a curved overall shape.

The cover structure according to the present embodiment may correspond to the curved shape of the dome structure by installing the solar panels 100 to be tilted at a predetermined angle from each other.

In particular, since the cover structure can change the tilting angle according to the curvature of the dome structure, it can be installed in various types of dome structures.

In FIG. 1 , the photovoltaic panel is installed only in a part of the dome structure 500 to facilitate understanding of the installation of the photovoltaic panel, but the photovoltaic panel 100 is on the entire surface of the dome structure 500 unlike the one shown. ) can be connected and installed is interpreted as a self-evident matter.

Referring to FIG. 1 , the dome structure 500 may be configured to form a curved surface by repeatedly disposing triangular-shaped panels in contact with each other. In this case, the triangular-shaped panels may be coupled to each other using a gusset, a strut, and a batten. For example, the five triangular-shaped panels may form a curved surface in such a way that their faces are in contact with each other so that they share one vertex.

In this case, the shared vertex may be firmly fixed using a strut, a batten, and/or a gusset.

In the solar panel 100 according to an embodiment of the present invention, as shown in FIG. 1 , the center of the main frame 250 is located at the vertex shared by the triangular-shaped panels, and the main frame 250 includes two It can be installed so as to span the panels.

That is, the mainframe 250 on which the first solar panel 101 is supported and the mainframe 250 on which the second solar panel 102 is supported may be installed so as to span two adjacent panels, respectively. .

As another example, unlike that shown in FIG. 1 , the main frame 250 on which the first solar panel 101 is supported is installed so that the center is located at the vertex and spans the two panels, and the second aspect The main frame 250 on which the light panel 102 is supported may be installed such that the center is located on one edge where the two adjacent panels are in contact with each other, and is positioned over the two adjacent panels.

However, the above-described installation location or method is exemplary, and it may be installed so that the center of the main frame 250 is located at a vertex in the triangular-shaped panels or at one edge where two adjacent panels come into contact with each other. When the size of the panel 100 is large, it is obvious that a plurality of panels may be installed between the two main frames 250 .

Referring to FIG. 2 , the cover structure according to the present embodiment allows the solar panels 100 to be closely attached to each other to be installed in a flat form.

Referring to FIG. 3 , the cover structure according to the present embodiment may be installed such that the solar panels 100 are tilted at a predetermined angle.

The plurality of photovoltaic panels 100 have the same structure, and when a distinction is necessary, a prefix such as "first" or "second" will be added to distinguish them. The cover structure according to the present embodiment includes at least a first solar panel 101 and a second solar panel 102 .

The cover structure 200 according to the present embodiment, a dome structure (Dome); A main frame 250 supported by a dome structure and spaced apart from the dome structure 100, and disposed on one upper end of the main frame 250, the main frame 250 A first tilting frame 210 that is rotatably assembled with respect to the first solar panel 101 is supported, and is disposed on the other side of the upper end of the main frame 250 and is rotatable with respect to the main frame 250 . and a second tilting frame 220 on which the second solar panel 102 is supported and assembled to the first tilting frame 210, and the first solar panel 101 is mounted on the first tilting frame The first fixer 230 for pressing and fixing to the 210, and the second tilting frame 220 are assembled, and the second solar panel 102 is pressed and fixed to the second tilting frame 220. A second fixer 240 is included.

The first fixer 230 may be tilted together with the first tilting frame 210 , and the second fixer 240 may be tilted together with the second tilting frame 220 .

When viewed in a plan view, both ends of the first fixer 230 may be formed in an “a” shape to surround the edge of the solar panel 101 . Similarly, when viewed in a plan view, both ends of the second fixer 240 may be formed in an “a” shape to surround the edge of the solar panel 102 .

Both ends of the first fixer 230 and both ends of the second fixer 240 may be disposed to face each other.

It may further include a first fastening member 261 that penetrates through the first fixer 230 and is fastened to the first tilting frame 210 and presses the first solar panel 101 through a fastening force. .

It may further include a second fastening member 262 that penetrates through the second fixer 240 and is fastened to the second tilting frame 220 and presses the second solar panel 102 through a fastening force. .

It may further include a first buffer member 270 disposed between the first fixer 230 and the first solar panel 101 to reduce damage to the first solar panel 101 when the pressure is applied.

It may further include a second buffer member 280 disposed between the second fixer 240 and the second solar panel 102 to reduce damage to the second solar panel 102 when the pressure is applied.

Hereinafter, each configuration will be described in more detail as follows.

The main frame 250 is disposed between the dome structure (Dome) and the solar panel 100, and separates the solar panel 100 from the dome structure (Dome).

The main frame 250 includes a base 300 supported by a dome structure, and a support frame 252 disposed to protrude upward from the base 300 .

In this embodiment, the base 300 and the support frame 252 are integrally manufactured. Unlike the present embodiment, the base 300 and the support frame 252 may be separately manufactured and then assembled.

The base 300 is in close contact with the outer surface of the dome structure (Dome). The support frame 252 is preferably disposed perpendicular to the outer surface of the dome structure (Dome).

The first tilting frame 210 and the second tilting frame 220 are rotatably assembled to the support frame 252 .

The main frame 250 is disposed on the upper side of the support frame 252 and further includes a support assembly part 254 assembled with the first tilting frame 210 and the second tilting frame 220 .

A first tilting shaft 211 which is disposed to pass through the support assembly 254 and the first tilting frame 210 and provides a center of rotation of the first tilting frame 210 may be further disposed.

A second tilting shaft 221 which is disposed to pass through the support assembly 254 and the second tilting frame 220 and provides a center of rotation of the second tilting frame 220 may be further disposed.

The first tilting frame 210 and the second tilting frame 220 are symmetrical, the first tilting frame 210 is disposed on the left side, and the second tilting frame 220 is disposed on the right side.

The first tilting shaft 211 and the second tilting shaft 221 are disposed in the left and right directions.

The first tilting frame 210 is assembled to the support assembly 254 through the first tilting shaft 211 . The first tilting frame 210 may be rotated in the vertical direction about the first tilting axis 211 .

The second tilting frame 220 is assembled to the support assembly 254 through the second tilting shaft 221 . The second tilting frame 220 may be rotated in the vertical direction about the second tilting axis 221 .

When the solar panels 100 are horizontally disposed, the first tilting frame 210 and the second tilting frame 220 may be disposed to be in contact with each other.

When the solar panels 100 are tilted, the first tilting frame 210 and the second tilting frame 220 form a tilting angle t and are spaced apart from each other.

The first tilting frame 210 includes a first tilting coupling part 212 rotatably assembled with the first tilting shaft 211 and protruding from the first tilting coupling part 212 to one side, and the A first tilting support part 214 for supporting the first solar panel 101, and a first fastening groove 215 disposed on the first tilting coupling part 212 and fastened to the first fastening member 261 includes

The first tilting coupling portion 212 is disposed to extend in the vertical direction as a whole.

The first tilting support part 214 protrudes from the left end of the first tilting coupling part 212 to the left and extends. The first solar panel 101 is seated and supported on the upper surface 214a of the first tilting support 214 .

In this embodiment, the upper surface of the first tilting coupling portion 212 and the upper surface 214a of the first tilting support 214 form a continuous plane.

When the first tilting frame 210 and the second tilting frame 220 come into contact with each other, the upper surface 214a of the first tilting frame 210 and the upper surface 224a of the second tilting frame 220 A plurality of solar panels 100 may be disposed at the same height through this continuous plane.

The first fastening groove 215 is formed to be concave in the direction of the first tilting axis 211 from the upper surface of the first tilting coupling part 212 . Since the first fastening member 261 and the first tilting shaft 211 are arranged in a line, the eccentricity of the fastening force pressing the first solar panel 101 can be minimized.

The second tilting frame 220 includes a second tilting coupling part 222 that is rotatably assembled with the second tilting shaft 221, and the other side of the second tilting coupling part 222 (right side in this embodiment). The second tilting support part 224 and the second tilting support part 224 for supporting the second solar panel 102 and the second tilting coupling part 222 are arranged to protrude and extend to, and are fastened with the second fastening member 262 It includes a second fastening groove (225).

The second tilting coupling portion 222 is disposed to extend in the vertical direction as a whole.

The second tilting support part 224 protrudes and extends to the right from the right end of the second tilting coupling part 222 . The second solar panel 102 is seated and supported on the upper surface 224a of the second tilting support 224 .

In this embodiment, the upper surface of the second tilting coupling part 222 and the upper surface 224a of the second tilting support part 224 form a continuous plane.

The second fastening groove 225 is concavely formed in the direction of the second tilting axis 221 on the upper surface of the second tilting coupling part 222 . Since the second fastening member 262 and the second tilting shaft 221 are arranged in a line, the eccentricity of the fastening force pressing the second solar panel 102 can be minimized.

In this embodiment, the first fixer 230 and the second fixer 240 are symmetrical.

The first fixer 230 is assembled to the first tilting frame 210 through a first fastening member 261 . The first fixer 230 presses the first solar panel 101 to the first tilting frame 210 .

The pressing force of the first fixer 230 may be adjusted through the first fastening member 261 .

The first fixer 230 is formed to extend long in the vertical direction, and includes a first fastening body 232 through which the first fastening member 261 passes, and one side (viewing) of the first fastening body 232 . It protrudes to the left in the embodiment, and includes a first pressure body 234 for pressing the first solar panel 101.

The first fastening body 232 and the first pressing body 234 are disposed to cross each other, and in this embodiment are orthogonal to each other. The first fastening body 232 and the first pressing body 234 are formed to surround the upper edge of the first solar panel (101).

The first fastening body 232 is disposed between the first solar tube panel 101 and the second solar panel 102 .

The first fastening body 232 is disposed to be spaced apart from the first tilting support part 214 , and the first fastening body 232 and the first tilting support part 214 are spaced apart by the first fastening member 261 . can be adjusted to adjust the pressing force.

The first pressing body 234 is disposed on the upper side of the first solar panel 101 , and presses the first solar panel 101 with the first tilting support part 214 .

The first tilting support part 214 is formed to be longer than the first pressing body 234 . In this embodiment, the outer end of the first tilting support 214 and the outer end of the first pressing body 234 form a gap S, and the outer end of the first tilting support 214 is the first pressing It is disposed on the left more by S than the outer end of the body 234 .

By increasing the length of the first tilting support 214 and minimizing the length of the first pressing body 234, the upper surface of the solar panel 100 can be utilized to the maximum.

A first buffer member 270 may be further disposed between the first pressing body 234 and the first solar panel 101 . The first buffer member 270 is disposed to surround an upper edge of the first solar panel 101 .

Since the first buffer member 270 is disposed at the inner corner of the first fixer 230 , exposure to sunlight can be minimized. When the first buffer member 270 is exposed to the outside, it is easily hardened by sunlight, thereby losing elasticity and weakening the reliability of the support structure.

The first buffer member 270 is in contact with an upper surface of the solar panel 100 to provide an elastic force, and a first upper elastic body 271 is in contact with the side surface of the solar panel 100 to provide an elastic force. The first side elastic body 272 providing It includes a first fitting body (273) to be.

In this embodiment, the first upper elastic body 271 and the first side elastic body 272 are integrally formed. Unlike the present embodiment, the first upper elastic body 271 and the first side elastic body 272 may be separately manufactured. The first upper elastic body 271 and the first side elastic body 272 may be defined as a first buffer body.

The first fixer 230 is formed with a first fitting portion 233 concave further inward from the inner edge. The first fitting body 273 may be inserted into the first fitting portion 233 to be fitted.

The first fixer 230 may further have a groove into which at least a portion of the first upper elastic body 271 and the first side elastic body 272 is inserted.

The assembly position of the first buffer member 270 may be fixed by the fitting coupling of the first fitting portion 233 and the first fitting body 273 .

The first buffer member 270 may maintain a state coupled to the first fixer 230 by the fitting coupling of the first fitting part 233 and the first fitting body 273, and through this, for installation can improve morale.

The first upper elastic body 271 and the first side elastic body 272 are arranged to be crossed, and in this embodiment, the vertical cross-section of the first buffer body may be "a" shape.

The first buffer member 270 separates the inner surface and the upper surface of the solar panel 100 from the inner surface of the first fixer 230 .

Specifically, the first upper elastic body 271 separates the upper surface of the first pressing body 234 and the first solar panel 101 . The first side elastic body 272 separates the first fastening body 232 and the first side elastic body 272 from each other.

Since the upper surface and the side surface of the solar panel 100 are spaced apart, direct abrasion or damage to the outer surface of the solar panel 100 can be prevented even if the structure is vibrated by wind.

The second buffer member 280 is a second upper elastic body 281 in contact with the upper surface of the solar panel 100 to provide an elastic force, and the second upper elastic body 281 in contact with the side surface of the solar panel 100 to provide an elastic force. A second side elastic body 282 that provides It includes a second fitting body 283 that is.

In this embodiment, the second upper elastic body 281 and the second side elastic body 282 are integrally formed. Unlike this embodiment, the second upper elastic body 281 and the second side elastic body 282 may be separately manufactured. The second upper elastic body 281 and the second side elastic body 282 may be defined as a second buffer body.

The second fixer 240 is formed with a first fitting portion 243 concave further inward from the inner edge. The second fitting body 283 may be inserted into the second fitting portion 243 to be fitted.

The second fixer 240 may further have a groove into which at least a portion of the second upper elastic body 281 and the second side elastic body 282 is inserted.

The assembly position of the second buffer member 280 may be fixed by the fitting coupling of the second fitting part 243 and the second fitting body 283 . The second buffer member 280 may maintain a state coupled to the second fixer 240 by fitting the second fitting portion 243 and the second fitting body 283 .

The second upper elastic body 281 and the second side elastic body 282 are arranged to be crossed, and the vertical cross section of the second buffer body in this embodiment may be "a" shape.

The second buffer member 280 separates the inner surface and the upper surface of the solar panel 100 from the inner surface of the second fixer 240 .

As shown in FIG. 7 , the first solar panel 101 may be fixed to the first tilting frame 210 by the first fixer 230 , and the second solar panel 102 is It may be fixed to the second tilting frame 220 by the second fixer 240 .

The first fixer 230 and the first tilting frame 210 may be defined as a first tilting assembly, and the second fixer 240 and the second tilting frame 220 may be defined as a second tilting assembly.

The first tilting assembly may be rotated about the first tilting axis 211 , and the second tilting assembly may be rotated about the second tilting axis 221 .

The first tilting assembly and the second tilting assembly may be fixed in a state in which a predetermined tilting angle t is formed. The tilting angle t may vary depending on the curvature of the dome.

Since the tilting angle t is freely set according to the curvature of the dome structure, the cover structure 200 according to the present embodiment has the advantage that it can be installed in various types of dome structures.

In this embodiment, the first tilting assembly may be rotated about the first tilting shaft 211 and is not fixed. Similarly, the second tilting assembly may be rotated about the second tilting shaft 221 and is not fixed.

So, when bending occurs in the solar panels 100 due to wind, the first tilting assembly or the second tilting assembly is rotated about the first tilting shaft 211 or the second tilting shaft 221 while The bending deformation can be eliminated.

In addition, bending deformation may occur in the solar panels 100 as the first and second tilting assemblies contract or expand according to temperature changes, and even in this case, the first tilting assembly or the second tilting assembly is rotated about the first tilting shaft 211 or the second tilting shaft 221 , thereby eliminating bending deformation.

8 is a front view of a cover structure for a dome structure according to a second embodiment of the present invention, and FIG. 9 is a partially enlarged view of FIG. 8 .

The cover structure according to the present embodiment is characterized in that the base 300 of the main frame 250 can be rotated according to the angle of the outer surface of the dome structure.

The base 300 according to this embodiment is disposed below the support frame 252 , and a first base frame 310 rotatably disposed with the support frame 252 , and the support frame 252 . It is disposed on the lower side and includes a second base frame 320 rotatably disposed with the support frame 252 .

The first base frame 310 may be rotated about the first base rotation shaft 311 . The second base frame 320 may be rotated about the second base rotation shaft 321 .

The first base frame 310 may be fixed to the dome structure through a fastening member 263 . The second base frame 320 may be fixed to the dome structure through a fastening member 264 .

The first base rotation shaft 311 and the second base rotation shaft 321 may be symmetrically disposed with respect to the support frame 252 .

Hereinafter, since the rest of the configuration is similar to that of the first embodiment, a detailed description thereof will be omitted.

10 is a front view showing a cover structure for a dome structure according to a third embodiment of the present invention, and FIG. 11 is a cross-sectional view of the spacer shown in FIG. 10 .

Unlike the first embodiment, the cover structure according to the present embodiment is characterized in that a spacer 400 is further disposed between the first fixer 230 and the second fixer 240 .

The spacer 400 may press the first fixer 230 and the second fixer 240 to maintain the tilt angle t, and through this, the first solar panel 101 and the second solar panel There is an advantage that can maintain the installation angle of (102).

The outer end of the first tilting support unit 214 and the outer end of the first pressure body 234 form a gap S, and the outer end of the first pressure body 234 is the first tilting support unit 214 . Since it is disposed closer to the outer end of the first solar panel 101 than the outer end, when an external force or bending change is applied to the first fixer 230, the first fixer 230 is the first solar panel ( 101) and spaced apart from each other, there is a possibility that the first solar panel 101 is separated.

In particular, when a strong wind blows, the solar panel 101 may be bent in the vertical direction to cause bending deformation, which may cause separation from the first fixer 230 and the second fixer 240 .

The spacer 400 may push the first fixer 230 and the second fixer 240 into close contact with the solar panel 100 . The spacer 400 is fixed by being sandwiched between the first fixer 230 and the second fixer 240 .

The spacer 400 is in close contact with the first fixer 230 , a first spacer body 410 that presses the first fixer 230 , and the second fixer 240 are in close contact with the second fixer 240 , 2 A second spacer body 420 for pressing the fixer 240, and disposed on either one of the first spacer body 410 and the second spacer body 420, the first spacer body 410 and the second spacer body 410 2 The spacer rotation shaft 430 for relatively rotatably connecting the spacer body 420, and the first spacer body 410 or the second spacer body 420 are disposed on the other one, and the spacer rotation shaft 430 is A slot 440 that slides and a support disposed between the first spacer body 410 and the second spacer body 420 and supporting the first spacer body 410 and the second spacer body 420 . member 450 .

The first spacer body 410 and the second spacer body 420 have a structure in which relative movement and relative rotation are possible.

The spacer rotation shaft 430 may move along the slot 440 .

When the spacer rotation shaft 430 is disposed in the first spacer body 410 , a slot 440 is formed in the second spacer body 420 . The opposite is also free.

In this embodiment, the support member 450 is a coil spring is used. Unlike this embodiment, a leaf spring may be used. In addition, a material having an elastic force may be inserted and fixed to the first spacer body 410 and the second spacer body 420 .

A first installation boss 415 and a second installation boss 425 into which the coil spring is inserted are formed in the first spacer body 410 and the second spacer body 420 .

The first installation boss 415 and the second installation boss 425 are inserted into the support member 450 to prevent separation of the support member 450 .

The support member 450 presses the first spacer body 410 with the first fixer 230 through the elastic force of the material, and presses the second spacer body 420 with the second fixer 240 .

The spacer 400 may support the first fixer 230 and the second fixer 240 to maintain the tilt angle t, thereby preventing the solar panel from being separated from each fixer.

Hereinafter, since the rest of the configuration is similar to that of the first embodiment, a detailed description thereof will be omitted.

12 is a front view illustrating a cover structure in which a dome structure and a photovoltaic panel are bonded to each other to support photovoltaic power generation while maintaining a sealing function according to a fourth embodiment of the present invention.

Unlike the first embodiment, the dome structure 504 according to the present embodiment may have an arc shape when viewed from the front and a rectangular shape when viewed from a plan view.

In this case, as shown in FIG. 12 , the main frame 250 supporting the first solar panel 101 and the main frame 250 supporting the second solar panel 102 along the arc-shaped curved surface direction. ) can be installed sequentially.

In addition, although FIG. 12 illustrates a state in which the solar panel 100 is installed in a part of the dome structure 504 , it is obvious that the solar panel 100 may be installed in the entire dome structure 504 in the same manner. is interpreted as

13 is a view showing a detailed structure according to the first embodiment in the dome structure of the shape shown in FIG. 12 .

Referring to FIG. 13 , the dome structure 504 may be configured such that bar-shaped or rectangular-shaped panels RP are continuously arranged so that their long edges are in contact with each other in an arc-forming direction. That is, in the vertical direction of the arc formation direction, the short edges of the panels RP may be continuously arranged so as to be in contact with each other.

At this time, in the case of some of the panels RP among the panels RP, the transparent panel SL may be disposed between the panels RP to allow light to flow into the transparent panel SL. For example, the transparent panel SL may be made of polycarbonate.

Also, at least a portion of the dome structure 504 may be provided with an equipment inlet IO through which equipment can be carried in.

Meanwhile, in the dome structure 504 according to FIG. 13 , the solar panels may be sequentially disposed along the continuous arrangement direction of the two or more panels RP.

For example, the first solar panel 101 and the second solar panel 102 may be sequentially disposed along the arc-forming direction of the dome structure 504 .

At this time, in the case of the main frame 250 supporting the photovoltaic panel 100 , the main frame 250 supporting the other photovoltaic panel 100 may be installed such that the center is located on the edge in contact between the adjacent panels RP. The frame 250 is installed so that the center is located on the edge in contact between the panel RP and the transparent panel SL, so that the solar panel 100 is not located, some sunlight through the central point of the main frame 250 It can also be configured to flow into the interior.

14 is a view showing a detailed structure according to the second embodiment in the dome structure of the shape shown in FIG. 12 .

Referring to FIG. 14 , the dome structure 504 may be formed by continuously disposing rectangular or square-shaped panels adjacent to each other in an arc-forming direction and a vertical direction of the arc-forming direction.

At this time, the four panels may be configured to share one vertex, and the four panels are firmly fixed to share one vertex. .

For example, the internal frame structure constituting the dome structure 504 includes a long strut (STL) formed in a straight line along the vertical direction of the arc formation direction, an arch strut (STA) formed in an arc shape along the arc formation direction, and a long strut ( Gussets (GSL, GSV) for fixing the arch strut (STA) and the long strut (STL) to each other at the intersection of the STL) and the arch strut (STA) may be included.

Here, the gussets (GSL) include an upper gusset (GSV) fixed in the upper portion, and a lower gusset (GSL) fixed in the lower portion. In this case, the upper gusset (GSV) may be used for fixing the panel together from the outside of the panel if necessary.

15 is a plan view illustrating a cover structure in which a dome structure and a photovoltaic panel are bonded to each other according to a fifth embodiment of the present invention to support photovoltaic power generation while maintaining a sealing function.

The dome structure 505 according to this embodiment may be configured in an umbrella shape, and may include a circular frame formed in the center of the umbrella shape and a plurality of straight frames perpendicular to the outside of the circle around the circular frame. .

In this embodiment, each of the panels constituting the dome structure 505 has a trapezoidal shape in plan view, and the panels of the same size may be continuously arranged along a radius of the same size in the umbrella-shaped dome structure 505 . have.

At this time, the panels are formed to be larger in size as the radius from the center of the umbrella shape increases, and to be smaller in size as they are closer to the center of the umbrella shape.

Meanwhile, in the dome structure 505 of FIG. 15 , the solar panels 100 may be continuously disposed along a radius.

For example, the first solar panel 101 and the second solar panel 102 adjacent to each other may be arranged to cover adjacent panels positioned on the same radius, respectively.

At this time, the main frame 250 supporting the first solar panel 101 and the main frame 250 supporting the second solar panel 102 may be installed so as to be centered on adjacent straight frames, respectively. .

Here, the solar panel 100 is most preferably configured in a trapezoidal shape as shown in the drawing, like the panel, but may be configured in a rectangular shape in some cases.

As described above, the photovoltaic panel 100 according to the present invention continuously follows a curved surface or the same radius that forms an arc regardless of the shape of the dome structure 500 is an umbrella shape, a combination of triangular panels, a combination of rectangular panels, etc. Since it can be installed, it is possible to install in response to all of the dome structures 500 of various shapes.

Those of ordinary skill in the art to which the present invention pertains will understand that the present invention may be embodied in other specific forms without changing the technical spirit or essential features thereof. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the claims described below rather than the above detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts are included in the scope of the present invention. should be interpreted

101: first solar panel 102: second solar panel
210: first tilting frame 220: second tilting frame
230: first fixer 240: second fixer
250: main frame 261: first fastening member
262: second fastening member 270: first buffer member
280: second buffer member 300: base

Claims (5)

As a cover structure in which a dome structure and a photovoltaic panel are bonded to each other to support photovoltaic power generation while maintaining a sealing function,
dome structures;
a main frame 250 supported on the dome structure;
a first tilting frame 210 disposed at an upper end of the main frame 250 and rotatably assembled with respect to the main frame 250 and on which the first solar panel 101 is supported;
a second tilting frame 220 disposed on the other side of the upper end of the main frame 250 and rotatably assembled with respect to the main frame 250 and on which the second solar panel 102 is supported;
a first fixer 230 assembled to the first tilting frame 210 and pressing and fixing the first solar panel 101 to the first tilting frame 210; and
A second fixer 240 assembled to the second tilting frame 220 and pressing and fixing the second solar panel 102 to the second tilting frame 220; includes;
The main frame 250,
a base 300 supported by the dome structure;
a support frame 252 protruding upward from the base 300;
a support assembly unit 254 disposed on the upper side of the support frame 252 and assembled with the first tilting frame 210 and the second tilting frame 220;
The support assembly 254 and the first tilting frame 210 are disposed to pass through to couple the first tilting frame 210 to the support assembly 254 and rotation of the first tilting frame 210 . a first tilting axis 211 providing a center; and
The support assembly part 254 and the second tilting frame 220 are disposed to pass through, the second tilting frame 220 is coupled to the support assembly part 254, and the second tilting frame 220 is rotated. A second tilting axis 221 to provide a center; includes;
The first tilting frame 210 and the second tilting frame 220 are disposed on the main frame 250 symmetrically to each other, form a tilting angle t, and the first tilting frame 210 and As the second tilting frame 220 is spaced apart from each other, the first solar panel 101 and the second solar panel 102 are tilted while being spaced apart from each other,
When the first tilting frame 210 and the second tilting frame 220 contact each other, the first solar panel 101 and the second solar panel 102 are arranged in a line, the cover structure. delete delete The method according to claim 1,
The first fixer is disposed to surround the upper edge of the first solar panel,
The second fixer is disposed to surround the upper edge of the second solar panel, the cover structure. The method according to claim 1,
A first fastening member that penetrates through the first fixer 230 and is fastened to the first tilting frame 210 and presses the first solar panel 101 to the first tilting frame 210 through a fastening force. (261);
A second fastening member that penetrates through the second fixer 240 and is fastened to the second tilting frame 220 and presses the second solar panel 102 to the second tilting frame 220 through a fastening force. (262); further comprising;
The lower end of the first fixer 230 is spaced apart from the upper surface of the first tilting frame 210, and the lower end of the second fixer 240 is spaced apart from the upper surface of the second tilting frame 220, cover structure.

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