KR102534433B1 - Ceiling construction system utilizing sunlight panel - Google Patents

Abstract

A purpose of the present invention is to provide a roof installation system using solar panels. A configuration of the present invention comprises: a support structure unit (130) formed at a certain height from a roof (2); solar panel assemblies (120) supported by the support structure unit (130) and disposed on the roof (2); and a coupling object (140) that couples the solar panel assemblies (120) to each other.

Description

Roof installation system using solar panels {Ceiling construction system utilizing sunlight panel}

The present invention relates to a roof mounting system using a solar panel, and more particularly, a solar panel with a new configuration that can automatically adjust the angle of the solar panel according to sunlight and implements a stable solar panel installation support structure. It relates to a roof installation system using

In general, the upper part of a steel structure having a large area, such as a factory, an auditorium, a gymnasium, a rest area, or an airport, is often composed of a roof panel having an insulation function or a solar panel roof.

Prefabricated roof structures, such as roof panels and solar panels, are relatively easy to construct compared to roofs with other complex structures, but are vulnerable to natural disasters such as earthquakes due to the nature of prefabricated structures. The main members of prefabricated roof structures include beams, which are steel structures such as H-beams, purlins that cross vertically with beams, upper and lower panels and insulation layers provided on the upper side of purlins, and the corresponding members are connected by clips or bolts. are joined to each other by members.

However, in the past, there was a lack of means to automatically adjust the angle according to the sunlight, which reduced the efficiency of solar power generation, and a function that helps the support for installing the solar panel on the roof to withstand shock and vibration. When vibration is transmitted to the building due to an earthquake or strong wind due to insufficiency, each connecting member fixing the solar panel to the roof shakes and applies stress, and the connecting members that do not withstand this are damaged and separated from each other. In other words, since the existing roof structure does not have a separate device for dampening vibration in the event of an earthquake or the like, the transmitted vibration affects the roof structure as it is, and there is room for a serious collapse accident to occur.

Korean Registered Patent No. 10-2364837 (registered on February 15, 2022) Korean Registered Patent No. 10-2361351 (registered on February 7, 2022) Korean Registered Patent No. 10-2428020 (registered on July 28, 2022) Korean Patent Publication No. 10-2022-0058300 (published on May 09, 2022)

An object of the present invention is to provide a roof mounting system using a solar panel of a new configuration that can automatically adjust the angle of the solar panel according to sunlight and implements a stable solar panel installation support structure.

According to the present invention for solving the above problems, the support structure 130 formed at a certain height from the roof (2); a solar panel assembly 120 supported by the support structure 130 and disposed on the roof 2; There is provided a roof mounting system using a solar panel comprising a; coupling body 140 for coupling the solar panel assembly 120 to each other.

The support structure part 130 further includes a second support part 134, and the support part 132 includes a panel support frame 132BF supported and installed in a horizontal direction above the roof 2, the panel support frame (132BF) and includes an upright frame (132EF) disposed in the vertical direction, and the second support part (134) is a second panel support frame (134BF) supported and installed in the horizontal direction above the roof (2). , A second upright frame 134EF supported by the second panel support frame 134BF and disposed vertically, and the solar panel assembly 120 includes a solar panel 122SP attached to the panel frame 122PF. ) is coupled to the solar panel structure 122, and the second solar panel structure 124 in which the second solar panel 124SP is coupled to the second panel frame 124PF, the assembly 140 , the assembly 142 coupling the solar panel structure 122 to the upright frame 132EF of the support 132, the second solar panel structure 124 to the second support 134 It includes a second assembly 144 coupled to the second upright frame 134EF, and the height of the second upright frame 134EF is relatively higher than the height of the upright frame 132EF, so that the second solar panel It is characterized in that the installation height of the structure 124 is configured to be higher than the installation height of the solar panel structure 122.

The conjugate 142,

It consists of a channel shape in which an upper support channel piece and an upper support channel piece are provided at the upper and lower ends of the connection channel piece and extends along the horizontal and vertical directions of the panel support frame 132BF and is arranged in parallel with four couplings up, down, left, and right. A rail 122CR, a fixing bolt insertion hole 142B formed to pass through both sides of the panel frame 122PF constituting the solar panel structure 122, and a fixing bolt fastening hole formed in the four coupling rails 122CR. (142C), and the circumference of the solar panel structure 122 is inserted into the space between the upper support panel piece, the second upper support panel piece, and the connection channel piece of the four coupling rails 122CR, and is supported. In the state in which the fixing bolt 142D is inserted into the fixing bolt insertion hole 142B formed in the panel frame 122PF of the solar panel structure 122, and at the same time the fixing bolt fastening hole 142C of the coupling rail 122CR ) By being fastened to, it is configured to fix the solar panel structure 122 on the roof 2 by the four coupling rails 122CR, the fixing bolts 142D, and the panel support frame 132BF, and the second The combination body 144 is configured in a channel shape in which the second upper support channel piece and the second upper support channel piece are provided at the upper and lower ends of the second connection channel piece, and the second panel support frame 134BF is formed in the horizontal and vertical directions. Four second coupling rails 124CR extending along and disposed parallel to each other, and a second formed to pass through both sides of the second panel frame 124PF constituting the second solar panel structure 124. It includes fixing bolt insertion holes 144B and second fixing bolt fastening holes 144C formed in the four second coupling rails 124CR, and the second upper support panel piece of the four second coupling rails 124CR. And the circumference of the second solar panel structure 124 is inserted into the space between the second upper support panel piece and the second connection channel piece, and the first portion of the second solar panel structure 124 is supported. The second fixing bolt 144D is inserted into the second fixing bolt insertion hole 144B formed in the two-panel frame 124PF and simultaneously fastened to the second fixing bolt fastening hole 144C of the second coupling rail 124CR. , configured to fix the second solar panel structure 124 on the roof 2 by the four second coupling rails 124CR, the second fixing bolts 144D, and the second panel support frame 134BF. to be characterized

The roof installation system using the solar panel of the present invention implements a means for automatically adjusting the angle according to sunlight, thereby improving solar power generation efficiency, and structures such as supports for installing solar panels on the roof are impact-resistant and The anti-vibration function, which helps to withstand vibration, is satisfactorily implemented to prevent vibration from being transmitted to the building due to earthquakes or strong winds, thus preventing the risk of solar panels and supporting structures collapsing in advance. there is.

On the other hand, the present invention has various other effects in addition to the above effects, and the characteristics of the present invention are not limited only by the above effects.

1 is a perspective view showing the structure of a roof mounting system using a solar panel according to the present invention;
Figure 2 is a side view of Figure 1;
3 is a perspective view of a plurality of solar panel structures, which are main parts of the present invention;
4 is a side view showing a state prior to coupling a solar panel, which is a main part of the present invention, to a panel support frame;
5 is a side view showing a state in which the solar panel shown in FIG. 4 is coupled to a panel support frame;
6 is a perspective view showing a state in which the solar panel shown in FIG. 4 is coupled to a panel support frame;
7 is a perspective view showing a state prior to coupling of a panel support frame and a rotation bottom support frame, which are other main parts of the present invention;
Figure 8 is a perspective view showing an enlarged angle adjustment drive motor part, which is a main part for angle adjustment of the solar panel structure in the roof installation system using a solar panel according to the present invention;
Figure 9 is a side view of Figure 8;
10 is a side view schematically showing the structure of a rotation bottom support frame and a rotation driving motor to which the solar panel structure shown in FIG. 9 is rotatably coupled;
11 is a perspective view of a plurality of second solar panel structures, which are main parts of the present invention;
12 is a side view showing a state prior to coupling the second solar panel, which is the main part of the present invention, to the second panel support frame;
13 is a side view showing a state in which the second solar panel shown in FIG. 12 is coupled to a second panel support frame;
14 is a perspective view showing a state in which the second solar panel shown in FIG. 12 is coupled to a second panel support frame;
15 is a perspective view showing a state prior to coupling of a second panel support frame and a second rotation bottom support frame, which are other main parts of the present invention;
16 is a perspective view showing an enlarged second angle adjusting driving motor part, which is a main part for adjusting the angle of a second solar panel structure in a roof installation system using a solar panel according to the present invention;
Figure 17 is a side view of Figure 8;
18 is a side view schematically showing the structure of a second rotation bottom support frame and a second rotation driving motor to which the second solar panel structure shown in FIG. 11 is rotatably coupled;
19 is a side view showing the structure of a rotation support cylinder and a second rotation support cylinder, which are other main parts of a roof installation system using a solar panel according to the present invention;
20 and 21 are side views schematically showing the process of adjusting the angle of the solar panel structure, which is the main part of the present invention;
22 and 23 are side views schematically showing the process of adjusting the angle of the second solar panel structure, which is the main part of the present invention;
24 is an enlarged side view showing the structure of the vibration absorbing part, which is another main part of the roof mounting system using a solar panel according to the present invention;
25 is a side view showing an enlarged structure of a second vibration absorbing part, which is another main part of a roof installation system using a solar panel according to the present invention;
26 is a cross-sectional plan view schematically showing the structure of the vibration absorption unit shown in FIG. 24;
27 is a cross-sectional plan view schematically showing the structure of the second vibration absorption unit shown in FIG. 25;
28 is a diagram schematically showing a linkage driving structure of a user terminal, a solar panel structure, and a second solar panel structure, which are other main parts of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Objects, features and advantages of the present invention will be more easily understood by referring to the accompanying drawings and the following detailed description. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

Also, terms such as first, second, A, B, (a), and (b) may be used in describing the components of the present invention. These terms are only used to distinguish the component from other components, and the nature, order, or order of the corresponding component is not limited by the term. When an element is described as being “connected,” “coupled to,” or “connected” to another element, that element is directly connected or connectable to the other element, but there is another element between the elements. It will be understood that elements may be “connected”, “coupled” or “connected”.

1 is a perspective view showing the structure of a roof mounting system using a solar panel according to the present invention, FIG. 2 is a side view of FIG.

Referring to the drawings, the roof mounting system using the solar panel of the present invention is a support structure formed at a certain height from the roof (2) (130); a solar panel assembly 120 supported by the support structure 130 and disposed on the roof 2; A combination body 140 coupling the solar panel assemblies 120 to each other; includes.

The present invention includes an angle adjuster capable of automatically adjusting the angle according to sunlight, the coupling method of the assembly 140 is special, and the support structure 130 installed on the roof 2 is robust from shock and vibration. It includes a vibration absorbing unit that helps to withstand the heat, and is also characterized in that it further includes a configuration of a user terminal 216 capable of controlling the communication module 212 and the solar panel assembly 120.

In the present invention, the support structure part 130 further includes a second support part 134, and the support part 132 is a panel support frame 132BF supported and installed in a horizontal direction above the roof 2, the It includes an upright frame 132EF supported by the panel support frame 132BF and disposed vertically.

The panel supporting frame 132BF is configured in a rectangular frame shape elongated in the left-right direction or up-and-down direction of the roof 2 when viewing the roof 2 from above. The panel support frame 132BF is supported by fixing means such as bolts and brackets and is configured to be fixed on the roof 2 .

The upright frame 132EF is configured in a bar shape extending in a vertical direction. A plurality of solar panel structures 122 are erected and arranged along the vertical and horizontal directions of the panel support frame 132BF to support and support the solar panel structure 122 from below.

The second support part 134 includes a second panel support frame 134BF installed and supported in a horizontal direction above the roof 2, and a second panel support frame 134BF supported by the second panel support frame 134BF and disposed vertically. It includes an upright frame 134EF.

The solar panel assembly 120 includes a solar panel structure 122 in which a solar panel 122SP is coupled to a panel frame 122PF, and a second solar panel 124SP to a second panel frame 124PF. and a coupled second solar panel structure 124 .

The second panel support frame 134BF is configured in a rectangular frame shape elongated in the left-right direction or up-down direction of the roof 2 when viewing the roof 2 from above. The second panel support frame 134BF is supported by fixing means such as bolts and brackets and is configured to be fixed on the roof 2 .

The second upright frame 134EF has a bar shape extending in the vertical direction. A plurality of solar panel structures 124 are erected and disposed along the vertical and horizontal directions of the second panel support frame 134BF to support and support the second solar panel structure 124 from below.

The assembly 140 couples the solar panel structure 122 to the upright frame 132EF of the support 132 . The assembly 140 further includes a second assembly 144 coupling the second solar panel structure 124 to the second upright frame 134EF of the second support 134, and the second upright assembly 144 The height of the frame 134EF is relatively higher than that of the upright frame 132EF so that the installation height of the second solar panel structure 124 is higher than the installation height of the solar panel structure 122. do.

The panel frame 122PF is configured by coupling and fixing four coupling rails 122CR in vertical and horizontal directions. It is composed of a channel shape in which an upper support channel piece and a lower support channel piece are provided at the upper and lower ends of the connection channel piece, and four couplings of up, down, left, and right are arranged side by side extending along the horizontal and vertical directions of the panel support frame 132BF. The rails 122CR are coupled and fixed in the vertical and horizontal directions to form the panel frame 122PF.

The assembly 142 includes fixing bolt insertion holes 142B formed to pass through the four coupling rails 122CR of the panel frame 122PF constituting the solar panel structure 122, and the panel support frame 132BF. ), and includes a fixing bolt fastening hole 142C formed in the four coupling rails 122CR, and the solar panel structure 122 in the space between the upper support panel piece, the second upper support panel piece, and the connection channel piece. The fixing bolt 142D is inserted into the fixing bolt insertion hole 142B formed in the four coupling rails 122CR of the panel frame 122PF of the solar panel structure 122 in a state in which the circumference of the ) is inserted and supported. At the same time, the solar panel structure ( 122) is configured to be fixed on the roof (2). The assembly 142 also includes a fixing bolt 142D. The four coupling rails 122A are coupled and fixed in the vertical and horizontal directions to form the panel frame 122PF.

Therefore, the present invention can quickly and easily install the solar panel structure 122 on the roof 2 by the assembly 142, and when necessary, it is fixed on the roof 2 by loosening the fixing bolt 142D. It is possible to easily and quickly separate only the solar panel structure 122 from the panel support frame 132BF, which is advantageous in maintenance such as replacement installation of the solar panel structure 122 .

The second panel frame 124PF is formed by coupling and fixing four second coupling rails 124CR in vertical and horizontal directions. It is composed of a channel shape in which the second upper support channel piece and the second upper support channel piece are provided at the upper and lower ends of the second connection channel piece, and extend along the horizontal and vertical directions of the second panel support frame 134BF and are parallel to each other. The four second coupling rails 124CR arranged in a vertical and horizontal direction are coupled and fixed in the vertical and horizontal directions to form the second panel frame 124PF.

The second assembly 144 is a second fixing bolt insertion hole formed to pass through the four second coupling rails 124CR of the second panel frame 124PF constituting the second solar panel structure 124. 144B, and a second fixing bolt fastening hole 144C formed in the second panel support frame 134BF, and includes a second upper support panel piece and a second upper support of the four second coupling rails 124CR. The second panel frame 124PF of the second solar panel structure 124 in a state where the circumference of the second solar panel structure 124 is inserted and supported in the space between the panel piece and the second connection channel piece. The second fixing bolt 144D is inserted into the second fixing bolt insertion hole 144B formed in the four second coupling rails 124CR of the second fixing bolt fastening hole of the second panel support frame 134BF at the same time. By being fastened to (144C), the second solar panel structure 124 is installed on the roof (2) by the four second coupling rails 124CR, the second fixing bolts 144D, and the second panel support frame 134BF. ) characterized in that it is configured to be fixed on. The second assembly 144 also includes a second fixing bolt 144D.

Therefore, the present invention can quickly and easily install the solar panel structure 122 on the roof 2 by the second assembly 144, and if necessary, loosen the second fixing bolt 144D to the roof 2 ) It is possible to easily and quickly separate only the second solar panel structure 124 from the second panel support frame 134BF fixed thereon, and thereby, maintenance such as replacement installation of the second solar panel structure 124 has a beneficial effect.

At this time, the second panel support frame 134BF and the second upright frame 134EF are installed on the roof 2 so as to be disposed on the side of the base upright frame and the upright frame 132EF.

The height of the second upright frame 134EF is higher than the height of the upright frame 132EF compared to the height of the solar panel structure 122 supported on the upright frame 132EF. The height of the second solar panel structure 124 is higher.

Therefore, the height of the second solar panel structure 124 supported by the second upright frame 134EF is different from that of the solar panel structure 122, so that the solar panel structure 122 and the second solar panel structure 122 have a different height. Since the solar power generation amount of the light panel structure 124 can be differentiated, the solar power generation efficiency is further increased.

On the other hand, Figure 3 is a perspective view of a plurality of solar panel structures, which is the main part of the present invention, Figure 4 is a side view showing a state before coupling the solar panel, which is the main part of the present invention, to the panel support frame, Figure 5 is FIG. 6 is a perspective view showing a state in which the solar panel shown in FIG. 4 is coupled to the panel support frame, and FIG. 7 is another main aspect of the present invention. A perspective view showing a state before the coupling of the female panel support frame and the rotation bottom support frame, Figure 8 is an angle adjustment drive motor part, which is a main part for angle adjustment of the solar panel structure in the roof installation system using a solar panel according to the present invention A perspective view showing an enlarged view, FIG. 9 is a side view of FIG. 8, FIG. 10 is a side view schematically showing the structure of a rotational bottom support frame and a rotation drive motor in which the solar panel structure shown in FIG. 9 is rotatably coupled, 11 is a perspective view of a plurality of second solar panel structures, which are the main part of the present invention, and FIG. 12 is a side view showing a state before coupling the second solar panel, which is the main part of the present invention, to the second panel support frame. 13 is a side view showing a state in which the second solar panel shown in FIG. 12 is coupled to the second panel support frame, and FIG. 14 is a state in which the second solar panel shown in FIG. 12 is coupled to the second panel support frame. 15 is a perspective view showing a state prior to coupling of the second panel support frame and the second rotation bottom support frame, which are other main parts of the present invention, and FIG. 16 is a roof mounting system using a solar panel according to the present invention. A perspective view showing an enlarged second angle adjusting driving motor part, which is a main part for adjusting the angle of the second solar panel structure, FIG. 17 is a side view of FIG. 8, and FIG. 18 is a second solar panel structure shown in FIG. 11 One side view schematically showing the structure of the rotatably coupled second rotation bottom support frame and the second rotation driving motor, Figure 19 is a rotation support cylinder and the other main parts of the roof installation system using a solar panel according to the present invention 2 One side view showing the structure of the rotation support cylinder, Figures 20 and 21 are one side view schematically showing the process of adjusting the angle of the solar panel structure, which is the main part of the present invention, Figures 22 and 23 are the main part of the present invention One side view schematically showing the process of adjusting the angle of the second solar panel structure, FIG. 24 is one side view showing the structure of the vibration absorbing part, which is another main part of the roof installation system using a solar panel according to the present invention, in an enlarged manner, 25 is an enlarged side view showing the structure of the second vibration absorption unit, which is another main part of the roof installation system using a solar panel according to the present invention, and FIG. 26 is a plan view schematically showing the structure of the vibration absorption unit shown in FIG. 24, 27 is a cross-sectional plan view schematically showing the structure of the second vibration absorption unit shown in FIG. 25, and FIG. 28 is a schematic cross-sectional view of a linked drive structure of a user terminal, a solar panel structure, and a second solar panel structure, which are other main parts of the present invention. It is a drawing showing

In the present invention, an angle adjusting unit and a second angle adjusting unit for automatically adjusting the angle between the solar panel structure 122 and the second solar panel structure 124 according to sunlight are further included.

The angle adjuster is provided on the bottom surface of the panel support frame 132BF to which the bottom surface of the panel frame 122PF of the plurality of solar panel structures 122 is fixed, and at the same time, on the longitudinal center line of the panel support frame 132BF. A pair of arranged rotation support blocks; a pair of rotation support shafts 153 protruding from left and right side ends of the panel support frame 132BF, respectively, and disposed on a longitudinal center line of the panel support frame 132BF; a rotation bottom support frame 155 having a rotation axis bracket 154 to which the rotation support shaft 153 is rotatably coupled and coupled to an upper end of an upright frame 132EF installed on the roof 2; a rotation movable shaft 156 coupled to the rotation support block and rotatably coupled to the rotation bottom support frame 155; and an angle adjustment drive motor 157 fixed to the rotation bottom support frame 155 and having a motor shaft coupled to the rotation movable shaft 156.

The rotation bottom support frame 155 is configured in a rectangular frame shape, and two rotation axis brackets 154 are provided on the top surface of the rotation bottom support frame 155 to be side by side.

The rotation support block 152 is provided with a cutout penetrating the inner and outer circumferential surfaces, inserted into and coupled to the outer circumferential surface of the rotation movable shaft 156, tightened by bolts and nuts, and pressed against the outer circumferential surface of the rotation movable shaft 156, configured to be fixed.

The second angle adjuster is provided on the bottom surface of the second panel support frame 134BF to which the bottom surface of the second panel frame 124PF of the plurality of second solar panel structures 124 is fixed and supports the second panel at the same time. a pair of second rotation support blocks disposed on the longitudinal center line of the frame 134BF; a pair of second rotation support shafts 163 protruding from left and right side ends of the second panel support frame 134BF and disposed on a longitudinal center line of the second panel support frame 134BF; A second rotation bottom support frame having a second rotation axis bracket 164 to which the second rotation support shaft 163 is rotatably coupled and coupled to the upper end of the second upright frame 134EF installed on the roof 2 (165); a second rotation movable shaft 166 coupled to the second rotation support block and rotatably coupled to the second rotation bottom support frame 165; and a second angle adjusting drive motor 167 fixed to the second rotation bottom support frame 165 and having a motor shaft coupled to the second rotation movable shaft 166.

The second rotation bottom support frame 165 is configured in a rectangular frame shape, and two second rotation shaft brackets 164 are provided on the upper surface of the second rotation bottom support frame 165 to be side by side.

The second rotation support block 162 is provided with a cutout penetrating the inner and outer circumferential surfaces, is inserted into and coupled to the outer circumferential surface of the second rotation movable shaft 166, and is tightened by bolts and nuts to the second rotation movable shaft 166. ) Is configured to be pressed and fixed to the outer circumferential surface of the

The sun moves over time after sunrise, and in response to this, the rotation movable shaft 156 rotatably coupled to the rotation bottom support frame 155 is moved in one direction by driving the angle adjustment drive motor 157 When rotated (for example, clockwise), the plurality of solar panel structures 122, the rotation support block, and the panel support frame 132BF are rotated along with sunlight based on the rotation bottom support frame 155 Therefore, there is an effect of increasing the solar power generation efficiency by the solar panel 122SP of the solar panel structure 122 corresponding to the position where sunlight is radiated.

A rotation bottom support frame 155 in which a pair of left and right rotation support shafts 153 provided at the center of the left and right side ends of the panel support frame 132BF are coupled to the upper end of the upright frame 132EF installed on the roof 2 Since the rotation shaft bracket 154 is relatively rotated, the plurality of solar panel structures 122, the rotation support block, and the panel support frame 132BF can be rotated together based on the rotation bottom support frame 155 .

On the other hand, after the sunset of the sun, the rotation movable shaft 156 rotatably coupled to the rotation bottom support frame 155 is moved in the other direction (eg, counterclockwise) by the driving of the angle adjustment drive motor 157. ), the plurality of solar panel structures 122, the rotation support block 152, and the panel support frame 132BF return to their original positions based on the rotation bottom support frame 155 fixed on the roof 2 together After being rotated and restored, the solar panel structure 122 may switch to an angle adjustment standby state at sunrise on the next day in response to the radiation direction of sunlight.

The sun moves over time after sunrise, and in response to this, the second rotation movable shaft rotatably coupled to the second rotation bottom support frame 165 by driving the second angle adjustment drive motor 167 When 166 is rotated in one direction (for example, clockwise), the plurality of second solar panel structures 124, the second rotation support block, and the second panel support frame 134BF together form the second rotation bottom. Since it rotates along the sunlight based on the support frame 165, the solar power generation efficiency by the second solar panel 124SP of the second solar panel structure 124 is increased in response to the position where sunlight is radiated. There are possible effects.

A pair of left and right second rotation support shafts 163 provided at the center of the left and right side ends of the second panel support frame 134BF are coupled to the upper end of the second upright frame 134EF installed on the roof 2. Since the second rotation shaft bracket 164 of the two-rotation bottom support frame 165 is relatively rotated, the plurality of second solar panel structures 124, the second rotation support block, and the second panel support frame 134BF are together. It can rotate based on the second rotation bottom support frame 165 .

Meanwhile, after the sunset of the sun, the second rotation movable shaft 166 rotatably coupled to the second rotation bottom support frame 165 is moved in the other direction (e.g. For example, when rotated in a counterclockwise direction), the plurality of second solar panel structures 124, the second rotation support block 162, and the second panel support frame 134BF are fixed together on the roof 2. It is rotated and returned to its original position based on the rotation bottom support frame 165, so that the second solar panel structure 124 can switch to an angle adjustment standby state in response to the radiation direction of sunlight at sunrise on the next day. .

On the other hand, in the present invention, a plurality of rotation support cylinders having a cylinder rod connected to the lower surface of the panel support frame 132BF having the rotation support block via a hinge and a lower end connected to the upright frame 132EF via a hinge ( 172); A plurality of second rotation cylinder rods are connected to the lower surface of the second panel support frame (134BF) equipped with the second rotation support block through a hinge, and the lower end is connected to the second upright frame (134EF) through a hinge Characterized in that it further includes; support cylinder 182.

As time passes after the sun rises, the rotation support cylinder at one position while the plurality of solar panel structures 122 and the panel support frame 132BF rotate along the sunlight based on the rotation bottom support frame 155 The cylinder rod of (172) rises, and the cylinder rod of the rotation support cylinder 172 at the other position descends so that the solar panel structure 122 rotates smoothly along the sunlight, while supporting the rotation in two places Since the cylinder 172 supports the solar panel structure 122 from below, there is an effect of allowing the plurality of solar panel structures 122 to adjust their angles according to sunlight more stably and safely.

On the other hand, after the sunset of the sun, while the solar panel structure 122 is rotated in the opposite direction and returned to its original position, the cylinder rod of the rotation support cylinder 172 at one position descends, and the rotation at the other position Since the cylinder rod of the support cylinder 172 rises and the two rotation support cylinders 172 support the solar panel structure 122 from below, the plurality of solar panel structures 122 are more stable and safe than the original It can be supported to rotate into position.

In addition, as time passes after the sun rises, the plurality of second solar panel structures 124 and the second panel support frame 134BF rotate along the sunlight based on the second rotation bottom support frame 165 During this time, since the cylinder rod of the second rotation support cylinder 182 at one position rises and the cylinder rod of the second rotation support cylinder 182 at the other position descends, the second solar panel structure 124 ) is rotated smoothly along the sunlight, while the two second rotation support cylinders 182 support the second solar panel structure 124 from below, making it more stable and safe. A plurality of second solar panel structures (124) has the effect of allowing the angle to be adjusted according to sunlight.

On the other hand, while the solar panel structure 122 is rotated in the opposite direction after the sunset of the sun and returned to its original position, the cylinder rod of the second rotation support cylinder 182 at one position descends, and at the other position Since the cylinder rod of the second rotation support cylinder 182 is rising and the two rotation support cylinders 172 support the second solar panel structure 124 from below, more stably and safely. The panel structure 124 may be supported so as to rotate to its original position.

In addition, the present invention is installed on the roof (2) vibration absorbing portion for absorbing the vibration of the support portion 132 and the solar panel structure 122; A second vibration absorbing part installed on the roof 2 to absorb vibration of the second support part 134 and the second solar panel structure 124 is further included, and the vibration absorbing part comprises Installed on the roof 2 to support a plurality of upright frames 132EF provided on the panel support frame 132BF and protruding below the bottom surface of the panel support frame 132BF so as to be movable in the vertical and horizontal directions from the inside vibration absorption box 192; a vertical side vibration absorbing spring 194 interposed between a lower end of the upright frame 132EF and a bottom surface of the vibration absorbing box 192; It is composed of a horizontal vibration absorbing spring 196 interposed between the circumferential portion of the upright frame 132EF and the inner surface of the vibration absorbing box 192, and the second vibration absorbing portion is the second support portion 134 In order to support a plurality of second upright frames 134EF provided on the second panel support frame 134BF and protruding below the bottom surface of the second panel support frame 134BF to be movable in vertical and horizontal directions from the inside. a second vibration absorbing box 202 installed on the roof 2; a second vertical side vibration absorbing spring 204 interposed between the lower end of the second upright frame 134EF and the bottom surface of the second vibration absorbing box 202; It is composed of a second horizontal side vibration absorbing spring 206 interposed between the circumference of the second upright frame 134EF and the inner surface of the second vibration absorbing box 202 .

A supporting piece is provided inside the vibration absorbing box 192 so that the vertical vibration absorbing spring 194 and the horizontal vibration absorbing spring 196 are isolated from each other by the supporting piece, and the vertical vibration absorbing spring 194 is interposed between the lower end of the upright frame 132EF and the roof 2 to support the lower end of the upright frame 132EF.

In addition, a supporting piece is provided inside the second vibration absorbing box 202, and the second vertical vibration absorbing spring 204 and the 21st horizontal vibration absorbing spring are isolated from each other by the supporting piece, and the second vertical vibration absorbing spring 204 is isolated from each other. The side vibration absorbing spring 204 is interposed between the lower end of the second upright frame 134EF and the roof 2 to support the lower end of the second upright frame 134EF.

When an external vibration such as an earthquake occurs and the solar panel structure 122, the panel support frame 132BF, and the upright frame 132EF vibrate in the vertical direction on the roof 2, the vertical side vibration absorbing spring 194 It absorbs vibration in the vertical direction while being elastically stretched, and absorbs horizontal vibration when the solar panel structure 122, the panel support frame 132BF, and the upright frame 132EF vibrate in the horizontal direction on the roof 2. The spring 196 is also stretched and contracted to absorb vibration in the horizontal direction, thereby preventing the solar panel structure 122, the panel support frame 132BF, and the upright frame 132EF from being damaged by shaking caused by the vibration. there is

In addition, when an external vibration such as an earthquake occurs, the second solar panel structure 124, the second panel support frame 134BF, and the second upright frame 134EF vibrate in the vertical direction on the roof 2. 2 As the vertical side vibration absorbing spring 204 elastically expands and contracts, it absorbs vibration in the vertical direction, and the second solar panel structure 124, the second panel support frame 134BF, and the second upright frame 134EF When the roof 2 vibrates in the horizontal direction, the second horizontal side vibration absorbing spring 206 also expands and contracts to absorb the vibration in the horizontal direction, so that the second solar panel structure 124 and the second panel support frame ( 134BF) and the second upright frame 134EF are prevented from being damaged due to shaking due to vibration.

Therefore, the roof mounting system using the solar panel of the present invention implements a means for automatically adjusting the angle according to sunlight, thereby improving solar power generation efficiency, and a support structure for installing the solar panel on the roof (2). (130) has a satisfactory anti-vibration function that helps it withstand shocks and vibrations, so it prevents the risk of solar panels collapsing in advance by preventing vibrations from being transmitted to buildings due to earthquakes or strong winds. there is. In other words, in the present invention, since a device for buffering vibration in the event of an earthquake or the like is provided separately, the vibration transmitted by the earthquake or the like does not affect the roof (2) structure as it is, so there is no room for severe collapse accidents to occur. has a blocking effect.

On the other hand, the present invention is a communication module 212 installed on the roof (2); a control unit 214 electrically connected to the solar panel of the solar panel assembly 120; a user terminal 216 connected to the control unit 214 via a communication module 212; It further includes a user monitor 218 connected to the user terminal 216, and is characterized in that it is configured to control the angle of the solar panel through the control unit 214 in the user terminal 216.

In addition, the present invention includes an angle adjustment movable setting unit 223 provided in the control unit 214 so that the solar panel assembly 120 adjusts the angle according to the angle of sunlight; An angle adjustment time setting unit 225 provided in the control unit 214 to adjust the angle of the solar panel assembly 120 to be operated according to the sunrise and sunset times of the sun; characterized in that it further includes.

The communication module 212 is connected to the user terminal 216 via a wired or wireless communication network. The user terminal 216 may be configured as a user's computer. The angle adjustment operation setting unit 223 and the angle adjustment time setting unit 225 are configured to be connected to the control unit 214 via the communication module 212 and the user terminal 216.

Seasonal sunrise and sunset times are displayed between the screens of the user monitor 218 connected to the user terminal 216 by the angle adjustment time setting unit 225, and the user selects the sunrise and sunset times for each season on the screen of the user monitor 218. can be set

In addition, at sunrise, the motor shaft of the angle adjustment drive motor 157 and the motor shaft of the second angle adjustment drive motor 167 are rotated in one direction (for example, clockwise) by the angle adjustment set setting unit. By doing so, the angle adjustment is performed by one-way rotation of the solar panel structure 122 and the second solar panel structure 124, and at sunset, the motor shaft of the angle adjustment drive motor 157 and the second angle adjustment drive By controlling the motor shaft of the motor 167 to be rotated in the other direction (eg, counterclockwise), solar light generated by the rotation of the solar panel structure 122 and the second solar panel structure 124 in the other direction The panel structure 122 and the second solar panel structure 124 are returned to their original positions.

Therefore, the angle of the solar panel assembly 120 is adjusted according to the angle of sunlight emitted while the sun moves by selecting the sunrise and sunset times for each season displayed on the screen of the monitor connected to the user terminal 216 at the user side. Therefore, power (electricity) for adjusting the angle of the solar panel assembly 120 is stopped by stopping the angle adjustment operation of the solar panel assembly 120 before sunrise or after sunset while increasing the power generation efficiency of the solar panel. There is a possible effect of preventing the waste of

In the above, specific embodiments of the present invention have been described in detail. However, the spirit and scope of the present invention is not limited to these specific embodiments, and it is common knowledge in the technical field to which the present invention belongs that various modifications and variations are possible without changing the gist of the present invention. Anyone who has it will understand.

Therefore, since the embodiments described above are provided to completely inform those skilled in the art of the scope of the invention to which the present invention pertains, it should be understood that it is illustrative and not limiting in all respects, The invention is only defined by the scope of the claims.

2. Roof 120. Solar panel assembly
122. Solar panel structure 122SP. solar panels
122CR. Combined rail 122PF. panel frame
124. Second solar panel structure 124SP. 2nd solar panel
124CR. 2nd joining rail 124PF. 2nd panel frame
130. Support 132. Support
132BF. Panel support frame 132EF. upright frame
134. Second support 134BF. 2nd panel support frame
134EF. Second upright frame 140. Combination
142. Combination 142B. Fixing bolt insertion hole
142C. Fixing bolt fastening hole 142D. fixing bolt
144. Second assembly 144B. Second fixing bolt insertion hole
144 C. Second fixing bolt fastening hole 144D. 2nd fixing bolt
152. Rotation support block 153. Rotation support shaft
154. Rotation axis bracket 155. Rotation bottom support frame
156. Rotation movable shaft 157. Angle adjustment drive motor
162. Second rotation support block 163. Second rotation support shaft
164. Second rotation axis bracket 165. Second rotation bottom support frame
166. Second rotation movable shaft 167. Second angle adjustment drive motor
172. Rotation support cylinder 182. Second rotation support cylinder
192. Vibration absorbing box 194. Vertical side vibration absorbing spring
196. Horizontal side vibration absorbing spring 202. Second vibration absorbing box
204. Second vertical side vibration absorbing spring 206. Second horizontal side vibration absorbing spring
212. Communication module 214. Control unit
216. User terminal 218. User monitor
223. Angle adjustment operation setting unit 225. Angle adjustment time setting unit

Claims (3)

a support structure 130 formed at a certain height from the roof 2;
A plurality of solar panel assemblies 120 supported by the support structure 130, disposed on the roof 2, and coupled by a combination body 140;
The support structure 130,
It includes a support part 132 and a second support part 134,
The support part 132,
A panel support frame (132BF) supported and installed in the horizontal direction above the roof (2),
An upright frame 132EF supported by the panel support frame 132BF and arranged in a vertical direction,
The second support part 134,
A second panel support frame (134BF) supported and installed in the horizontal direction above the roof (2),
A second upright frame 134EF supported by the second panel support frame 134BF and arranged in a vertical direction,
The solar panel assembly 120,
A solar panel structure 122 in which a solar panel 122SP is coupled to a panel frame 122PF,
A second solar panel structure 124 in which the second solar panel 124SP is coupled to the second panel frame 124PF,
The conjugate 140,
An assembly 142 coupling the solar panel structure 122 to the panel support frame 132BF of the support part 132,
A second assembly 144 coupling the second solar panel structure 124 to the second panel support frame 134BF of the second support 134,
The height of the second upright frame 134EF is relatively higher than that of the upright frame 132EF, so that the installation height of the second solar panel structure 124 is greater than the installation height of the solar panel structure 122. configured to be higher
The conjugate 142,
It consists of a channel shape in which an upper support channel piece and an upper support channel piece are provided at the upper and lower ends of the connection channel piece and extends along the horizontal and vertical directions of the panel support frame 132BF and is arranged in parallel with four couplings up, down, left, and right. A rail 122CR, a fixing bolt insertion hole 142B formed to penetrate both sides of the panel frame 122PF constituting the solar panel structure 122, and a fixing bolt fastening hole formed in the four coupling rails 122CR (142C), and the circumference of the solar panel structure 122 is inserted into the space between the upper support panel piece, the second upper support panel piece, and the connection channel piece of the four coupling rails 122CR, and is supported. In the state in which the fixing bolt 142D is inserted into the fixing bolt insertion hole 142B formed in the panel frame 122PF of the solar panel structure 122, and at the same time the fixing bolt fastening hole 142C of the coupling rail 122CR ) is concluded,
It is composed of a channel shape in which an upper support channel piece and a lower support channel piece are provided at the upper and lower ends of the connection channel piece, and four couplings of up, down, left, and right are arranged side by side extending along the horizontal and vertical directions of the panel support frame 132BF. The rails 122CR are combined and fixed in the vertical and horizontal directions to form the panel frame 122PF,
The second assembly 144,
It is composed of a channel shape in which the second upper support channel piece and the second upper support channel piece are provided at the upper and lower ends of the second connection channel piece, and extend along the horizontal and vertical directions of the second panel support frame 134BF and are parallel to each other. The second fixing bolt insertion hole 144B formed to pass through both sides of the second panel frame 124PF constituting the second solar panel structure 124, and the four second coupling rails 124CR arranged vertically and horizontally. ), and second fixing bolt fastening holes 144C formed in the four second coupling rails 124CR, and the second upper support panel piece and the second upper support panel of the four second coupling rails 124CR. The second panel frame 124PF of the second solar panel structure 124 in a state where the circumference of the second solar panel structure 124 is inserted and supported in the space between the side and the second connection channel piece. The second fixing bolt 144D is inserted into the second fixing bolt insertion hole 144B formed in the second fixing bolt fastening hole 144C of the second coupling rail 124CR at the same time,
It is composed of a channel shape in which the second upper support channel piece and the second upper support channel piece are provided at the upper and lower ends of the second connection channel piece, and extend along the horizontal and vertical directions of the second panel support frame 134BF and are parallel to each other. Four second coupling rails 124CR arranged vertically and horizontally are coupled and fixed in the vertical and horizontal directions to form a second panel frame 124PF,
Further comprising an angle adjusting unit and a second angle adjusting unit for automatically adjusting an angle between the solar panel structure 122 and the second solar panel structure 124 according to sunlight,
The angle adjuster,
A pair of panels provided on the bottom surface of the panel support frame 132BF fixed to the bottom surface of the panel frame 122PF of the plurality of solar panel structures 122 and disposed on the center line in the longitudinal direction of the panel support frame 132BF. rotation support block;
a pair of rotation support shafts 153 protruding from left and right side ends of the panel support frame 132BF, respectively, and disposed on a longitudinal center line of the panel support frame 132BF;
a rotation bottom support frame 155 having a rotation axis bracket 154 to which the rotation support shaft 153 is rotatably coupled and coupled to an upper end of an upright frame 132EF installed on the roof 2;
a rotation movable shaft 156 coupled to the rotation support block and rotatably coupled to the rotation bottom support frame 155;
An angle adjustment drive motor 157 fixed to the rotation bottom support frame 155 and having a motor shaft coupled to the rotation movable shaft 156;
The second angle adjusting unit,
The lower surface of the second panel frame 124PF of the plurality of second solar panel structures 124 is provided on the lower surface of the fixed second panel support frame 134BF, and at the same time, the longitudinal direction of the second panel support frame 134BF a pair of second rotation support blocks disposed on the center line;
a pair of second rotation support shafts 163 protruding from left and right side ends of the second panel support frame 134BF and disposed on a longitudinal center line of the second panel support frame 134BF;
A second rotation bottom support frame having a second rotation axis bracket 164 to which the second rotation support shaft 163 is rotatably coupled and coupled to the upper end of the second upright frame 134EF installed on the roof 2 (165);
a second rotation movable shaft 166 coupled to the second rotation support block and rotatably coupled to the second rotation bottom support frame 165;
A second angle adjustment drive motor 167 fixed to the second rotation bottom support frame 165 and having a motor shaft coupled to the second rotation movable shaft 166;
A plurality of rotation support cylinders 172 having a cylinder rod connected to the lower surface of the panel support frame 132BF having a rotation support block through a hinge and having a lower end connected to the upright frame 132EF through a hinge; A plurality of second rotation cylinder rods are connected to the lower surface of the second panel support frame (134BF) equipped with the second rotation support block through a hinge, and the lower end is connected to the second upright frame (134EF) through a hinge Support cylinder 182; roof mounting system using a solar panel characterized in that it further comprises. delete delete

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