CN218335834U - Photoelectric wave board system - Google Patents

Abstract

A photoelectric wave plate system comprises a first wave plate, a second wave plate, a first solar panel and a second solar panel. The first corrugated plate is provided with a first bottom plate, a first bearing plate and a second bearing plate. The first bearing plate and the second bearing plate are positioned at two sides of the first bottom plate. The second corrugated plate is provided with a second bottom plate, a third bearing plate and a fourth bearing plate. The third bearing plate and the fourth bearing plate are positioned at two sides of the second bottom plate. The second bearing plate is partially overlapped with the third bearing plate to define a groove. The first solar panel is located on the first bearing plate and the second bearing plate. The second solar panel is located on the third bearing plate and the fourth bearing plate. The second bearing plate and the third bearing plate which are partially overlapped can strengthen the structural stability between the first wave plate and the second wave plate, and can prolong the service life of the photoelectric wave plate system.

Description

Photoelectric wave board system

Technical Field

The present disclosure relates to a photovoltaic wave panel system.

Background

In general, the installation work of the conventional solar energy system usually requires that a wave plate is laid on a building body (such as a roof). After the support is assembled on the wave plate, the solar panel is installed on the support, so that the installation cost of laying the wave plate and assembling the support is increased. For example, such an arrangement requires a lot of labor and time to drill holes on the panels and the brackets and use a lot of screws and blocks for spot-locking, thereby increasing the material cost for installing the solar system and increasing the load weight of the building body. In addition, after the solar panel is installed, because the solar panel and the support are only locked by the screws and the pressing blocks, when strong wind blows to the solar panel and the support, the negative wind pressure of the strong wind easily damages the structural stability between the solar panel and the support, and the solar system is damaged.

SUMMERY OF THE UTILITY MODEL

The present disclosure is directed to a photovoltaic wave plate system to solve at least one of the above problems.

According to an embodiment of the present disclosure, a photovoltaic panel system includes a first panel, a second panel, a first solar panel, and a second solar panel. The first corrugated plate is provided with a first bottom plate, a first bearing plate and a second bearing plate. The first bearing plate and the second bearing plate are positioned on two sides of the first bottom plate. The second corrugated plate is provided with a second bottom plate, a third bearing plate and a fourth bearing plate. The third bearing plate and the fourth bearing plate are positioned at two sides of the second bottom plate. The second bearing plate is partially overlapped with the third bearing plate to define a groove. The first solar panel is located on the first bearing plate and the second bearing plate. The second solar panel is located on the third bearing plate and the fourth bearing plate. At least one first space is arranged among the first solar panel, the first bottom plate, the first bearing plate and the second bearing plate. At least one second space is arranged among the second solar panel, the second bottom plate, the third bearing plate and the fourth bearing plate.

In an embodiment of the present disclosure, the groove is a V-shaped groove or a U-shaped groove.

In an embodiment of the present disclosure, the optoelectronic wave plate system further includes an adhesive material. The adhesive material is positioned in the groove.

In an embodiment of the present disclosure, the first bottom plate and the second bottom plate respectively have a first bearing portion and a second bearing portion. The first solar panel and the second solar panel are respectively positioned on the first bearing part and the second bearing part.

In an embodiment of the present disclosure, the optoelectronic wave plate system further includes a double-sided adhesive tape. The double-sided adhesive tape is positioned on the first bearing part, the second bearing part, the third bearing plate and the fourth bearing plate.

In an embodiment of the present disclosure, the optoelectronic wave plate system further includes an adhesive. The adhesive is located between the first solar panel and at least one of the first bearing plate and the second bearing plate, and between the second solar panel and at least one of the third bearing plate and the fourth bearing plate.

In an embodiment of the present disclosure, a distance between one of the first bottom plate and the second bottom plate and the solar panel is between 3cm and 20 cm.

In an embodiment of the present disclosure, the number of the first solar panels is two. The distance between the two first solar panels is between 1cm and 20 cm.

In an embodiment of the present disclosure, the ratio of the distance to the longitudinal length of one of the two first solar panels is between 1% and 20%.

In an embodiment of the present disclosure, the cables of the two first solar panels are connected in series.

In an embodiment of the present disclosure, the cables of the two first solar panels are concentrated to the cabling trough.

Another technical means of the present disclosure is a photovoltaic wave panel system.

According to an embodiment of the present disclosure, a photovoltaic panel system includes a first panel, a second panel, a first solar panel, a second solar panel, and two steel bodies. The first corrugated plate is provided with a first bottom plate, a first bearing plate and a second bearing plate. The first bearing plate and the second bearing plate are positioned at two sides of the first bottom plate. The second corrugated plate is provided with a second bottom plate, a third bearing plate and a fourth bearing plate. The third bearing plate and the fourth bearing plate are positioned at two sides of the second bottom plate. The second bearing plate is partially overlapped with the third bearing plate to define a groove. The first solar panel is located on the first bearing plate and the second bearing plate. The second solar panel is located on the third bearing plate and the fourth bearing plate. At least one first space is arranged among the first solar panel, the first bottom plate, the first bearing plate and the second bearing plate. At least one second space is arranged among the second solar panel, the second bottom plate, the third bearing plate and the fourth bearing plate. The two steel bodies are locked on the bottom surfaces of the first wave plate and the second wave plate. The steel structure distance between the two steel bodies is between 50cm and 200 cm.

In an embodiment of the present disclosure, a ratio of a longitudinal length of the solar panel to a steel structure pitch is between 50% and 200%.

In an embodiment of the present disclosure, a length direction of the first wave plate is perpendicular to a length direction of one of the two steel bodies.

In the above embodiments of the present disclosure, the optoelectronic wave plate system has a first wave plate and a second wave plate, and the second carrier plate of the first wave plate overlaps the third carrier plate of the second wave plate to define a groove. The second and third bearing plates which are partially overlapped can strengthen the structural stability between the first and second corrugated plates, so that when strong wind blows to the first and second corrugated plates, the first and second corrugated plates are not easy to be damaged, and the service life of the photoelectric corrugated plate system can be prolonged. In addition, the wave plates (such as the first wave plate and the second wave plate) of the photovoltaic wave plate system can be assembled in advance in a factory, and the first solar panel and the second solar panel are assembled on the first wave plate and the second wave plate in advance. The steel body can reduce the construction time for installing the photoelectric wave plate system on a building body, improve the overall operation efficiency and save labor and installation cost at the same time because most parts of the photoelectric wave plate system can be assembled in advance in a factory.

One technical aspect of the present disclosure is a photovoltaic wave panel system.

According to an embodiment of the present disclosure, a photovoltaic panel system includes a first panel, a second panel, a first solar panel, and a second solar panel. The first corrugated plate is provided with a first bottom plate, a first bearing plate and a second bearing plate. The first bearing plate and the second bearing plate are positioned on two sides of the first bottom plate. The second corrugated plate is provided with a second bottom plate, a third bearing plate and a fourth bearing plate. The third bearing plate and the fourth bearing plate are positioned at two sides of the second bottom plate. The second bearing plate of the first wave plate is connected with the third bearing plate of the second wave plate, and the second bearing plate is partially overlapped with the third bearing plate to define an inverted U-shaped groove. The first solar panel is located on the first bearing plate and the second bearing plate. The second solar panel is located on the third bearing plate and the fourth bearing plate.

In an embodiment of the present disclosure, one of the first bottom plate and the second bottom plate has a reinforcing rib. The top surface of the reinforcing rib is closer to one of the first solar panel and the second solar panel than the bottom surface of one of the first bottom plate and the second bottom plate.

In an embodiment of the present disclosure, one of the first bottom plate and the second bottom plate has a carrying portion. The bearing part is provided with two convex ribs which are opposite to each other.

In an embodiment of the present disclosure, the above-mentioned photovoltaic wave board system further includes a supporting member. The supporting piece is positioned between the two convex ribs of the bearing part.

In an embodiment of the present disclosure, the optoelectronic wave plate system further includes a double-sided adhesive tape. The double-sided adhesive tape is positioned on the bottom surface of one of the first solar panel and the second solar panel.

In an embodiment of the present disclosure, a distance between an edge of one of the first solar panel and the second solar panel and the double-sided structural tape is less than 7 millimeters (mm).

In an embodiment of the present disclosure, the optoelectronic wave plate system further includes an adhesive. The adhesive is located between the first bearing plate and the first solar panel and located between the fourth bearing plate and the second solar panel.

According to an embodiment of the present disclosure, a photovoltaic panel system includes a first panel, a second panel, two first solar panels, and two second solar panels. The first corrugated plate is provided with a first bottom plate, a first bearing plate and a second bearing plate. The first bearing plate and the second bearing plate are positioned at two sides of the first bottom plate. The second corrugated plate is provided with a second bottom plate, a third bearing plate and a fourth bearing plate. The third bearing plate and the fourth bearing plate are positioned at two sides of the second bottom plate. The second bearing plate of the first wave plate is connected with the third bearing plate of the second wave plate, and the second bearing plate is partially overlapped with the third bearing plate to define an inverted U-shaped groove. Two first solar panels are located on the first bearing plate and the second bearing plate. The distance between the two first solar panels is between 1 and 20 cm. The two second solar panels are located on the third bearing plate and the fourth bearing plate. The distance between the two second solar panels is between 1 and 20 cm.

In an embodiment of the present disclosure, a ratio of a distance between the two first solar panels to a longitudinal length of one of the two first solar panels is between 0.5% and 41%.

According to an embodiment of the present disclosure, a photovoltaic panel system includes a first panel, a second panel, two first solar panels, and two second solar panels. The first corrugated plate is provided with a first bottom plate, a first bearing plate and a second bearing plate. The first bearing plate and the second bearing plate are positioned at two sides of the first bottom plate. The second corrugated plate is provided with a second bottom plate, a third bearing plate and a fourth bearing plate. The third bearing plate and the fourth bearing plate are positioned at two sides of the second bottom plate. The second bearing plate of the first wave plate is connected with the third bearing plate of the second wave plate, and the second bearing plate is partially overlapped with the third bearing plate to define an inverted U-shaped groove. The first solar panel is located on the first bearing plate and the second bearing plate. The second solar panel is located on the third bearing plate and the fourth bearing plate. The two steel bodies are locked on the bottom surfaces of the first wave plate and the second wave plate. The steel structure spacing between the two steel bodies is between 50cm and 200 cm.

In an embodiment of the present disclosure, a ratio of a longitudinal length of one of the first solar panel and the second solar panel to a steel structure pitch is between 25% and 408%.

In the above embodiments of the present disclosure, the second loading plate of the first wave plate of the photovoltaic wave plate system is joined to and partially overlapped with the third loading plate of the second wave plate to define the inverted U-shaped groove. The second and third bearing plates which are partially overlapped can strengthen the structural stability between the first and second wave plates, so that when strong wind blows to the first and second wave plates, the structures of the first and second wave plates are not easy to be damaged, and the service life of the photoelectric wave plate system can be prolonged. In addition, the first wave plate and the second wave plate of the photovoltaic wave plate system can be assembled in a factory in advance, and the first solar panel and the second solar panel are respectively assembled on the first wave plate and the second wave plate in advance. Since most of the assembly of the photovoltaic panel system can be completed in advance in a factory, the construction time for installing the photovoltaic panel system on a building can be reduced, the overall operation efficiency can be improved, and the labor and the installation cost can be saved.

Drawings

An embodiment of the disclosure is best understood from the following detailed description when read in connection with the accompanying drawings. It is emphasized that, in accordance with the standard practice in the industry, various features are not drawn to scale and are used for illustrative purposes only. In fact, the dimensions of the various features may be arbitrarily increased or reduced for clarity of discussion.

Fig. 1 illustrates a perspective view of a photovoltaic wave panel system according to an embodiment of the present disclosure.

Fig. 2 shows a side view of the photovoltaic panel system of fig. 1.

Fig. 3 shows a partially enlarged view of the groove of fig. 2.

Fig. 4A shows a partial enlarged view of the third carrier plate of fig. 2.

Fig. 4B illustrates a partially enlarged view of the second bearing part of fig. 2.

Fig. 4C shows a partial enlarged view of the fourth loading plate of fig. 2.

Fig. 5 illustrates a top view of a photovoltaic wave panel system according to an embodiment of the present disclosure.

Fig. 6A shows a schematic diagram of a system for installing a photovoltaic panel according to an embodiment of the present disclosure.

Fig. 6B shows a partial enlarged view of the steel body of fig. 6A.

Figure 7A shows a schematic view of a cable of a solar panel according to an embodiment of the present disclosure.

Figure 7B shows a schematic view of the cables of a concentrating solar panel according to an embodiment of the present disclosure.

Fig. 8 illustrates a perspective view of a photovoltaic wave panel system according to an embodiment of the present disclosure.

Fig. 9 shows a close-up view of the inverted U-shaped groove of fig. 8, omitting the first and second solar panels of fig. 8.

Figure 10 illustrates a bottom view of the first solar panel of figure 8.

FIG. 11A shows a partial enlarged view of the first carrier plate of FIG. 8.

Fig. 11B shows a partial enlarged view of the fourth loading plate of fig. 8.

Fig. 12 illustrates a top view of a photovoltaic wave panel system according to an embodiment of the present disclosure.

Fig. 13 illustrates a perspective view of a system for installing a photovoltaic wave panel according to an embodiment of the present disclosure.

Fig. 14 shows a partially enlarged view of the support of fig. 13.

Fig. 15 shows a partially enlarged view of the auxiliary steel of fig. 13.

The reference numbers are as follows:

100 photoelectric wave board system

100a photoelectric wave plate system

100b photoelectric wave board system

100c photoelectric wave board system

110 the first corrugated board

111 bottom surface

112 first base plate

114 first carrier plate

116 second carrier plate

118 first bearing part

120 the second wave board

121 bottom surface

122 second base plate

124 the third bearing plate

126 fourth carrier plate

128 second bearing part

130a first solar panel

130b second solar panel

132 solar Module

134 cable

140 adhesive material

150 double-sided structure adhesive tape

160: adhesive

170 steel body

172 screw

174 auxiliary steel

200: wiring groove

800 photoelectric wave board system

800a photoelectric wave board system

800b photoelectric wave board system

810 first corrugated board

811 bottom surface

812 first base plate

813 reinforcing rib

814 first carrying plate

815, top surface

816 second bearing plate

818 bearing part

820 the second corrugated board

821 bottom surface

822 a second backplane

823 reinforcing rib

824, a third bearing plate

825 top surface

826 fourth carrying board

828 bearing part

830a first solar panel

830b second solar panel

832 bottom surface

834 a cable

836 edge

838 part of the margin

840a double-sided structure adhesive tape

840b adhesive

850: steel body

860 supporting element

870 auxiliary Steel

872 screw of

d1 is the distance

d2 distance

d3 longitudinal length

d4 is distance

d5 steel structure spacing

d6 is distance

d7 is distance

d8 longitudinal length

d9 distance

d10 steel structure spacing

C is a groove

D1: length direction

D2 longitudinal direction

E, convex ribs

G is an inverted U-shaped groove

Detailed Description

The following disclosure of embodiments provides many different embodiments, or examples, for implementing different features of the provided subject matter. Specific examples of components and arrangements are described below to simplify the present disclosure. Of course, the examples are merely examples and are not intended to be limiting. Further, the present disclosure may repeat reference numerals and/or letters in the various examples. This repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed.

Spatially relative terms such as "under 8230; \8230," "under 8230;, \8230," "under," "at 8230; \8230," "over," "over," and the like may be used herein for ease of description to describe one element or feature's relationship to another element or feature as illustrated in the figures. Spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. The device may be otherwise oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly as such.

Fig. 1 illustrates a perspective view of a photovoltaic wave board system 100 according to an embodiment of the present disclosure. Fig. 2 shows a side view of the photovoltaic panel system 100 of fig. 1. Referring to fig. 1 and fig. 2, the photovoltaic wave board system 100 includes a first wave board 110, a second wave board 120, a first solar panel 130a and a second solar panel 130b. The first corrugated board 110 has a first bottom plate 112, a first loading plate 114 and a second loading plate 116. The first bearing plate 114 and the second bearing plate 116 of the first wave plate 110 are located at two sides of the first bottom plate 112 of the first wave plate 110. In some embodiments, the first loading plate 114 of the first wave plate 110 is different from the second loading plate 116 of the first wave plate 110. For example, the second loading plate 116 of the first corrugated plate 110 has a V-shaped recess. The second wave plate 120 has a second bottom plate 122, a third loading plate 124 and a fourth loading plate 126. The third and fourth carrying plates 124 and 126 of the second wave plate 120 are located on two sides of the second bottom plate 122 of the second wave plate 120. For example, the first carrier plate 114 of the first wave plate 110 is similar in appearance to the third carrier plate 124 of the second wave plate 120, and the second carrier plate 116 of the first wave plate 110 is similar in appearance to the fourth carrier plate 126 of the second wave plate 120. It should be noted that the second loading plate 116 of the first wave plate 110 and the third loading plate 124 of the second wave plate 120 are partially overlapped to define a groove C. In detail, the third loading plate 124 of the second wave plate 120 is located on the second loading plate 116 of the first wave plate 110, and an edge of the third loading plate 124 of the second wave plate 120 is partially overlapped with the V-shaped recess of the second loading plate 116 of the first wave plate 110. The second and third carrier plates 116 and 124 partially overlapped can enhance the structural stability between the first and second corrugated panels 110 and 120.

In some embodiments, the first solar panel 130a is located on the first bearing plate 114 of the first wave plate 110 and the second bearing plate 116 of the first wave plate 110. The second solar panel 130b is located on the third carrier plate 124 of the second wave plate 120 and the fourth carrier plate 126 of the second wave plate 120. In addition, at least one first space S1 is formed between the first solar panel 130a, the first bottom plate 112 of the first wave plate 110, the first carrier plate 114 of the first wave plate 110, and the second carrier plate 116 of the first wave plate 110. At least one second space S2 is formed between the second solar panel 130b, the second bottom plate 122 of the second wave plate 120, the third carrier plate 124 of the second wave plate 120, and the fourth carrier plate 126 of the second wave plate 120. The first space S1 and the second space S2 can be regarded as heat dissipation spaces of the first solar panel 130a and the second solar panel 130b to take away heat generated by the first solar panel 130a and the second solar panel 130b during operation. Also, the cables 134 (to be described in detail in fig. 7A) of the first solar panel 130a may be integrated into the first space S1.

Specifically, the optoelectronic wave plate system 100 has a first wave plate 110 and a second wave plate 120, and the second carrier plate 116 of the first wave plate 110 and the third carrier plate 124 of the second wave plate 120 are partially overlapped to define a groove C. The second and third carrier plates 116 and 124, which are partially overlapped, can enhance the structural stability between the first and second wave plates 110 and 120, so that when strong wind blows on the first and second wave plates 110 and 120, the first and second wave plates 110 and 120 are not easily damaged, thereby improving the service life of the photovoltaic wave plate system 100.

In addition, the first wave board 110 and the second wave board 120 of the optoelectronic wave board system 100 can be assembled in advance in a factory, and the first solar panel 130a and the second solar panel 130b are assembled on the first wave board 110 and the second wave board 120 in advance. Since most of the assembly of the photovoltaic panel system 100 can be completed in advance in a factory, the time required for installing the photovoltaic panel system 100 on a building (e.g., a roof) can be reduced, the overall working efficiency can be improved, and the labor and installation costs can be saved. The optoelectronic wave board system 100 can be assembled in an array in a factory in advance. For example, the length of the 1kW type photovoltaic panel system 100 may be 8.2m. The length of the 1.125kW type photovoltaic panel system 100 may be 9.2m. The length of the 1.25kW type photovoltaic panel system 100 may be 10.2m. The length of the 1.375kW type photovoltaic panel system 100 may be 11.2m. The length of the 1.5kW type photovoltaic panel system 100 may be 12.2m.

In some embodiments, the first bottom plate 112 of the first wave plate 110 and the second bottom plate 122 of the second wave plate 120 have a first bearing portion 118 and a second bearing portion 128, respectively. The first solar panel 130a and the second solar panel 130b are respectively located on the first bearing portion 118 of the first wave plate 110 and the second bearing portion 128 of the second wave plate 120. In addition, the distance d1 between the first bottom plate 112 of the first wave plate 110 and the first solar panel 130a is between 3cm and 20 cm. The distance d2 between the second bottom panel 122 of the second corrugated panel 120 and the second solar panel 130b is between 3cm and 20 cm. The distances d1 and d2 between the first solar panel 130a and the second solar panel 130b and the first bottom plate 112 of the first corrugated plate 110 and the second bottom plate 122 of the second corrugated plate 120 can reduce the heat energy generated by the first solar panel 130a and the second solar panel 130b during operation to be transferred to the first bottom plate 112 and the second bottom plate 122, so as to improve the heat dissipation effect of the photovoltaic corrugated plate system 100.

Fig. 3 shows a partially enlarged view of the groove C of fig. 2. Referring to fig. 2 and 3, the groove C of the wave board system 100 may be a V-shaped groove or a U-shaped groove. In some embodiments, the photovoltaic panel system 100 further comprises an adhesive material 140. For example, the adhesive material 140 can be silicone, but not limited thereto. The adhesive material 140 can be located in the groove C to enhance the structural stability between the first wave plate 110 and the second wave plate 120. In addition, the adhesive material 140 is located in the groove C to prevent water leakage from the groove C, so as to improve the service life of the photovoltaic panel system 100.

Fig. 4A illustrates a partially enlarged view of the third loading plate 124 of fig. 2. Fig. 4B illustrates a partially enlarged view of the second bearing part 128 of fig. 2. Fig. 4C shows a partial enlarged view of the fourth loading plate 126 of fig. 2. Referring to fig. 2 to 4C, the photovoltaic panel system 100 further includes a double-sided structural adhesive tape 150. The double-sided tape 150 can be disposed on the third carrier plate 124, the fourth carrier plate 126 and the second carrier portion 128 of the second corrugated plate 120 to combine the second corrugated plate 120 and the second solar panel 130b. Similarly, the double-sided structural adhesive tape 150 can be disposed on the first carrying plate 114, the second carrying plate 116 and the first carrying portion 118 of the first corrugated plate 110 (see fig. 1) to combine the first corrugated plate 110 and the first solar panel 130a. In addition, the photovoltaic panel system 100 further includes an adhesive 160. The adhesive 160 of the photovoltaic panel system 100 can be located between the third carrier plate 124 of the second panel 120 and the second solar panel 130b, and between the fourth carrier plate 126 of the second panel 120 and the second solar panel 130b, so as to fix the second solar panel 130b. Similarly, the adhesive 160 can be located between the first carrying board 114 of the first wave board 110 and the first solar panel 130a (see fig. 2), and located between the second carrying board 116 of the first wave board 110 and the first solar panel 130a, so as to fix the first solar panel 130a. The adhesive 160 can seal the edges of the first solar panel 130a and the second solar panel 130b to provide protection.

It should be understood that the connection and function of the elements described above will not be repeated and will not be described in detail. In the following description, other forms of the photovoltaic panel system will be described.

Fig. 5 illustrates a top view of a photovoltaic wave board system 100a according to an embodiment of the present disclosure. The embodiment shown in fig. 5 is different from the embodiment shown in fig. 1 in that the number of the first solar panels 130a on the first wave plate 110 and the number of the second solar panels 130b on the second wave plate 120 of the photovoltaic wave plate system 100a are two. In some embodiments, the longitudinal length d3 of the first solar panel 130a and the second solar panel 130b may be between 95cm and 100cm, and the distance d4 between two first solar panels 130a (two second solar panels 130 b) may be between 1cm and 20 cm. In other words, the ratio of the distance d4 (e.g., 1cm to 20 cm) to the longitudinal length d3 (e.g., 95cm to 100 cm) may be between 1% and 20%. The distance d4 between the two first solar panels 130a (the two second solar panels 130 b) can provide enough heat dissipation space for the photovoltaic panel system 100a to carry away the heat generated by the first solar panels 130a and the second solar panels 130b during operation. In addition, the distance d4 between the two first solar panels 130a (the two second solar panels 130 b) can be used as a screw locking region to enhance the structural stability of the photovoltaic panel system 100 a.

Fig. 6A shows a schematic diagram of an installed photovoltaic panel system 100b according to an embodiment of the present disclosure. Fig. 6B shows a partial enlarged view of the steel body 170 of fig. 6A. Referring to fig. 6A and 6B together, the difference from the embodiment shown in fig. 5 is that the photovoltaic panel system 100B further includes a steel body 170. It is noted that the steel spacing d5 (pitch) between the two steel bodies 170 is between 50cm and 200 cm. In some embodiments, the ratio of the longitudinal length d3 (e.g., 95cm to 100 cm) of the first solar panel 130a and the second solar panel 130b to the steel spacing d5 (e.g., 50cm to 200 cm) may be between 50% and 200%. The steel body 170 can be locked on the bottom surface 111 of the first wave plate 110 and the bottom surface 121 of the second wave plate 120.

In some embodiments, steel body 170 may be locked using screws 172, and the securing effect of screws 172 may be strengthened using auxiliary steel 174. The length direction D1 of the steel body 170 is perpendicular to the length direction D2 of the first wave plate 110. In addition, if the first solar panel 130a and the second solar panel 130b are not disposed on the first wave plate 110 or the second wave plate 120, they can be used as a maintenance walkway. When the photoelectric wave plate system 100b has a fault and a worker needs to be dispatched to perform maintenance, the worker can perform maintenance on the maintenance walkway to improve the working efficiency.

In some embodiments, the steel body 170 may be used to install the photovoltaic panel system 100b on a building body (e.g., a roof) without using conventional brackets for installation, thereby reducing the load weight of the roof. In addition, most of the assembly of the photovoltaic panel system 100b can be completed in advance in a factory, so that the time required for installing the photovoltaic panel system 100b on a roof can be reduced, the overall operation efficiency can be improved, and the labor and installation costs can be saved.

Figure 7A shows a schematic view of the cables 134 of the first solar panel 130a according to an embodiment of the present disclosure. Fig. 7B shows a schematic view of the cable 134 of the first solar panel 130a of the concentrating photovoltaic panel system 100c according to an embodiment of the present disclosure. Referring to fig. 7A and 7B, the front side of the first solar panel 130a of the photovoltaic panel system 100c has a solar module 132, and the solar module 132 can absorb sunlight. The back side of the first solar panel 130a has cables 134. For example, the solar modules 132 of the first solar panel 130a can convert solar energy into electric energy after absorbing sunlight, and transmit the electric energy to the collector region through the cables 134 of the first solar panel 130a. In some embodiments, the cables 134 of the first solar panel 130a are connected in series and do not exceed the maximum system voltage of the photovoltaic panel system 100 c. In addition, the cables 134 of the first solar panel 130a of the photovoltaic wave plate system 100c are collected to the cabling channel 200, and the cabling channel 200 may be located on a ridge of a building to achieve a wire collecting effect.

In the following description, other forms of the photovoltaic panel system will be described.

Fig. 8 illustrates a perspective view of a photovoltaic wave board system 800 according to an embodiment of the present disclosure. Fig. 9 shows a partially enlarged view of the inverted U-shaped groove G of fig. 8, omitting the first solar panel 830a and the second solar panel 830b of fig. 8. Referring to fig. 8 and 9, the photovoltaic wave plate system 800 includes a first wave plate 810, a second wave plate 820, a first solar panel 830a, and a second solar panel 830b. The first wave plate 810 has a first bottom plate 812, a first loading plate 814 and a second loading plate 816. The first bearing plate 814 and the second bearing plate 816 of the first wave plate 810 are located at two sides of the first bottom plate 812 of the first wave plate 810.

The second wave plate 820 of the photovoltaic wave plate system 800 has a second bottom plate 822, a third loading plate 824 and a fourth loading plate 826. The third bearing plate 824 and the fourth bearing plate 826 of the second wave plate 820 are located at two sides of the second bottom plate 822. In some embodiments, the first loading plate 814 of the first wave plate 810 is similar in appearance to the third loading plate 824 of the second wave plate 820, the second loading plate 816 of the first wave plate 810 is similar in appearance to the fourth loading plate 826 of the second wave plate 820, and the second loading plate 816 of the first wave plate 810 is different in appearance from the third loading plate 824 of the second wave plate 820 (see fig. 9). It should be noted that the second loading plate 816 of the first wave plate 810 is connected to the third loading plate 824 of the second wave plate 820, and the second loading plate 816 and the third loading plate 824 partially overlap to define an inverted U-shaped groove G. In detail, the second carrier plate 816 of the first wave plate 810 is located on the third carrier plate 824 of the second wave plate 820, and the second carrier plate 816 and the third carrier plate 824, which are partially overlapped, can reinforce the structural stability between the first wave plate 810 and the second wave plate 820. In addition, glue can be applied to the inverted U-shaped groove G to strengthen the structure of the photovoltaic panel system 800, and the occurrence of water leakage can be reduced.

In some embodiments, the first solar panel 830a is located on the first and second carrying plates 814 and 816 of the first wave plate 810. The second solar panel 830b is located on the third carrier plate 824 and the fourth carrier plate 826 of the second wave plate 820. In some embodiments, the first bottom plate 812 of the first wave plate 810 and the second bottom plate 822 of the second wave plate 820 respectively have a bearing part 818 and a bearing part 828. The first solar panel 830a and the second solar panel 830b are respectively located on the carrying portion 818 of the first wave plate 810 and the carrying portion 828 of the second wave plate 820.

In addition, an accommodating space may be formed between the first solar panel 830a, the first bottom plate 812 of the first wave plate 810, the first bearing plate 814 of the first wave plate 810, and the second bearing plate 816 of the first wave plate 810. An accommodating space may be formed between the second solar panel 830b, the second bottom plate 822 of the second wave plate 820, the third bearing plate 824 of the second wave plate 820 and the fourth bearing plate 826 of the second wave plate 820. The accommodating space can be regarded as a heat dissipation space for the first solar panel 830a and the second solar panel 830b, and can take away heat generated by the first solar panel 830a and the second solar panel 830b during operation. Also, the cables 834 (described in detail in fig. 10) of the first solar panel 830a can be integrated into the accommodating space.

Specifically, the second carrier plate 816 of the first wave plate 810 of the photovoltaic wave plate system 800 is joined to and partially overlapped with the third carrier plate 824 of the second wave plate 820 to define an inverted U-shaped groove G. The second carrier plate 816 and the third carrier plate 824, which are partially overlapped, can enhance the structural stability between the first wave plate 810 and the second wave plate 820, so that when strong wind blows on the first wave plate 810 and the second wave plate 820, the structures of the first wave plate 810 and the second wave plate 820 are not easily damaged, and the service life of the photoelectric wave plate system 800 can be prolonged. In addition, the first wave plate 810 and the second wave plate 820 of the optoelectronic wave plate system 800 may be assembled in a factory in advance, and the first solar panel 830a and the second solar panel 830b may be assembled on the first wave plate 810 and the second wave plate 820 in advance, respectively. Since most of the assembly of the photovoltaic panel system 800 can be completed in a factory, the time required for installing the photovoltaic panel system 800 on a building (e.g., a roof) can be reduced, the overall working efficiency can be improved, and the labor cost can be saved.

Figure 10 illustrates a bottom view of the first solar panel 830a of figure 8. Referring to fig. 8 and 10, the photovoltaic panel system 800 further includes double-sided adhesive tapes 840a, and the number of the double-sided adhesive tapes 840a is not limited to the disclosure. Double-sided structural tape 840a may be positioned on bottom face 832 of first solar panel 830a. In addition, the first solar panel 830a may have a cable 834, and the cable 834 may be integrated in the accommodating space of the photovoltaic panel system 800. A distance d6 between the first edge 836 of the first solar panel 830a and the double-sided structural tape 840a is less than 7 millimeters (mm). The distance d7 between the second edge 838 of the first solar panel 830a and the other double-sided structural tape 840a is less than 7 mm. For example, the first edge 836 may be located at a long side of the first solar panel 830a, and the second edge 838 may be located at a short side of the first solar panel 830a. When the first solar panel 830a is assembled on the first corrugated board 810, the distance d6 and the distance d7 between the first edge 836 and the second edge 838 of the first solar panel 830a and the two double-sided tape 840a are regarded as glue filling areas, and glue 840b (to be described in detail in fig. 11A) may be filled in the glue filling areas, so as to further strengthen the structural stability between the first solar panel 830a and the first corrugated board 810. Similarly, the second solar panel 830b can be replaced with the first solar panel 830a, such that the second solar panel 830b has a double-sided tape 840a configuration thereon.

Fig. 11A illustrates a partially enlarged view of the first loading plate 814 of fig. 8. Fig. 11B illustrates a partial enlarged view of the fourth carrier plate 826 of fig. 8. Referring to fig. 11A and 11B, the optoelectronic wave plate system 800 further includes an adhesive 840B. The adhesive 840b may be located between the first carrying plate 814 and the first solar panel 830a to stabilize the first solar panel 830a. The adhesive 840b may be disposed between the fourth carrier plate 826 and the second solar panel 830b to stabilize the second solar panel 830b. In addition, the adhesive 840b can seal the edges of the first solar panel 830a and the second solar panel 830b to provide a protection effect.

Fig. 12 shows a top view of a photovoltaic wave board system 800a according to an embodiment of the present disclosure. The embodiment shown in fig. 12 is different from the embodiment shown in fig. 8 in that the number of the first solar panels 830a on the first wave plate 810 and the number of the second solar panels 830b on the second wave plate 820 of the photovoltaic wave plate system 800a are two. In some embodiments, the longitudinal length d8 of the first solar panel 830a and the second solar panel 830b may be between 49 centimeters and 199 centimeters, and the distance d9 between two first solar panels 830a (or two second solar panels 830 b) may be between 1 centimeter and 20 centimeters. In other words, the ratio of the distance d9 (e.g., 1cm to 20 cm) to the longitudinal length d8 (e.g., 49 cm to 199 cm) may be between 0.5% (e.g., the distance d9 is 1cm, the longitudinal length d8 is 199 cm) and 41% (e.g., the distance d9 is 20cm, the longitudinal length d8 is 49 cm), which may provide air circulation and heat dissipation effects, and the distance d9 may serve as a screw locking region to strengthen the overall structure of the photovoltaic panel system 800 a. The distance d9 between the two first solar panels 830a (or the two second solar panels 830 b) can provide enough heat dissipation space for the photovoltaic panel system 800a to carry away the heat generated by the operation of the first solar panels 830a and the second solar panels 830b. In addition, the distance d9 between the two first solar panels 830a (or the two second solar panels 830 b) can be used as a screw locking region to enhance the structural stability of the photovoltaic panel system 800 a.

Fig. 13 illustrates a perspective view of a system 800b for installing a photovoltaic panel according to an embodiment of the present disclosure. Fig. 14 shows a close-up view of the support 860 of fig. 13. Referring to fig. 13 and 14, the photovoltaic panel system 800b of fig. 13 is different from the embodiment shown in fig. 8 in that the photovoltaic panel system 800b further includes a steel body 850. The steel body 850 can be locked on the bottom surface 811 of the first wave plate 810 and the bottom surface 821 of the second wave plate 820. And, the steel structure spacing d10 (pitch) between the two steel bodies 850 is between 50cm and 200cm (e.g., 100 cm). The ratio of the steel spacing d10 (e.g., 50cm to 200 cm) to the longitudinal length d8 (e.g., 49 cm to 199 cm) of the first solar panel 830a and the second solar panel 830b may be between 25% (e.g., 50cm for steel spacing d10 and 199 cm for longitudinal length d 8) and 408% (e.g., 49 cm for steel spacing d10 and 200cm for longitudinal length d 8).

In some embodiments, the first bottom panel 812 of the first wave plate 810 has a first reinforcing rib 813. The top surface 815 of the first reinforcement rib 813 is closer to the first solar panel 830a than the bottom surface 811 of the first base plate 812. The second bottom plate 822 of the second wave plate 820 has a second reinforcing rib 823. The top surfaces 825 of the second reinforcing ribs 823 are closer to the second solar panel 830b than the bottom surfaces 821 of the second corrugated panel 820. The arrangement of the first reinforcement ribs 813 and the second reinforcement ribs 823 can increase the bearing capacity of the first wave plate 810 and the second wave plate 820. In addition, the first bottom plate 812 of the first wave plate 810 and the second bottom plate 822 of the second wave plate 820 respectively have a bearing part 818 and a bearing part 828. The bearing portion 818 of the first bottom plate 812 and the bearing portion 828 of the second bottom plate 822 both have two ribs E opposite to each other. The photovoltaic panel system 800b further comprises a support 860. Support 860 may be located between two ribs E of load-bearing portion 818 and between two ribs E of load-bearing portion 828. The configuration of the support 860 enhances the support of the carrier 818 to the first solar panel 830a and the support of the carrier 828 to the second solar panel 830b.

Fig. 15 shows a partially enlarged view of the auxiliary steel 870 of fig. 14. Referring to fig. 14 and 15, the auxiliary steel 870 may be locked to the steel body 850 by screws 872. The auxiliary steel 870 may enhance the fixing effect of the screw 872 to improve the structural stability of the photovoltaic wave plate system 800 b. For example, the photovoltaic panel system 800b can be installed on a building body (e.g., a roof) through the steel body 850 without using a conventional bracket, thereby reducing the load weight of the roof. In addition, most of the assembly of the photovoltaic panel system 800b can be completed in advance in a factory, so that the construction time of the photovoltaic panel system 800b on a roof can be reduced, the overall operation efficiency can be improved, and the labor and the installation cost can be saved.

The foregoing has outlined features of several embodiments so that those skilled in the art may better understand the manner of the present disclosure. Those skilled in the art should appreciate that they may readily use the present disclosure as a basis for designing or modifying other processes and structures for carrying out the same purposes and/or achieving the same advantages of the embodiments introduced herein. Those skilled in the art should also realize that such equivalent constructions do not depart from the spirit and scope of the present disclosure, and that they may make various changes, substitutions and alterations herein without departing from the spirit and scope of the present disclosure.

Claims (25)

1. A photovoltaic panel system, comprising:

the wave plate assembly comprises a first wave plate, a second wave plate and a plurality of first supporting plates, wherein the first wave plate is provided with a first bottom plate, the first supporting plates and the second supporting plates are positioned on two sides of the first bottom plate;

the second corrugated plate is provided with a second bottom plate, a third bearing plate and a fourth bearing plate, wherein the third bearing plate and the fourth bearing plate are positioned at two sides of the second bottom plate, and the second bearing plate and the third bearing plate are partially overlapped to define a groove; and

the solar panel comprises a first solar panel and a second solar panel, wherein the first solar panel is positioned on the first bearing plate and the second bearing plate, the second solar panel is positioned on the third bearing plate and the fourth bearing plate, at least one first space is arranged between the first solar panel and the first base plate and between the first bearing plate and the second bearing plate, and at least one second space is arranged between the second solar panel and the second base plate and between the third bearing plate and the fourth bearing plate.

2. The photovoltaic wave plate system of claim 1 wherein the groove is a V-shaped groove or a U-shaped groove.

3. The photovoltaic wave plate system of claim 1, further comprising:

and the adhesive material is positioned in the groove.

4. The optoelectronic wave plate system of claim 1, wherein the first bottom plate and the second bottom plate have a first carrying portion and a second carrying portion, respectively, and the first solar panel and the second solar panel are located on the first carrying portion and the second carrying portion, respectively.

5. The optoelectronic waveplate system of claim 4, further comprising:

and the double-sided adhesive tape is positioned on the first bearing part, the second bearing part, the third bearing plate and the fourth bearing plate.

6. The photovoltaic wave plate system of claim 1, further comprising:

and the adhesive is positioned between the first solar panel and at least one of the first bearing plate and the second bearing plate, and between the second solar panel and at least one of the third bearing plate and the fourth bearing plate.

7. The photovoltaic wave board system of claim 1, wherein a distance between the solar panel and one of the first and second bottom boards is between 3cm and 20 cm.

8. The photovoltaic wave plate system of claim 1 wherein the number of the first solar panels is two and a distance between the two first solar panels is between 1cm and 20 cm.

9. The photovoltaic wave board system of claim 8, wherein the ratio of the distance to the longitudinal length of one of the two first solar panels is between 1% and 20%.

10. The photovoltaic panel system of claim 8, wherein the cables of the two first solar panels are connected in series.

11. The photovoltaic panel system of claim 8, wherein the cables of the two first solar panels are concentrated to a raceway.

12. A photovoltaic wave plate system, comprising:

the wave plate assembly comprises a first wave plate, a second wave plate and a plurality of first supporting plates, wherein the first wave plate is provided with a first bottom plate, the first supporting plates and the second supporting plates are positioned on two sides of the first bottom plate;

the second corrugated plate is provided with a second bottom plate, a third bearing plate and a fourth bearing plate, wherein the third bearing plate and the fourth bearing plate are positioned at two sides of the second bottom plate, and the second bearing plate and the third bearing plate are partially overlapped to define a groove;

the solar panel assembly comprises a first solar panel and a second solar panel, wherein the first solar panel is positioned on the first bearing plate and the second bearing plate, the second solar panel is positioned on the third bearing plate and the fourth bearing plate, at least one first space is formed among the first solar panel, the first bottom plate, the first bearing plate and the second bearing plate, and at least one second space is formed among the second solar panel, the second bottom plate, the third bearing plate and the fourth bearing plate; and

two steel bodies locked to the bottom surfaces of the first and second wave plates, wherein a steel structure interval between the two steel bodies is between 50cm and 200 cm.

13. The photovoltaic panel system of claim 12, wherein the ratio of the longitudinal length of the solar panels to the steel structure spacing is between 50% and 200%.

14. The optoelectronic waveplate system of claim 12 wherein the length direction of the first waveplate is perpendicular to the length direction of one of the two steel bodies.

15. A photovoltaic wave plate system, comprising:

the wave plate assembly comprises a first wave plate, a second wave plate and a plurality of first supporting plates, wherein the first wave plate is provided with a first bottom plate, the first supporting plates and the second supporting plates are positioned on two sides of the first bottom plate;

a second corrugated board having a second bottom plate, a third loading plate and a fourth loading plate, wherein the third loading plate and the fourth loading plate are located at two sides of the second bottom plate, the second loading plate of the first corrugated board is joined with the third loading plate of the second corrugated board, and the second loading plate and the third loading plate are partially overlapped to define an inverted U-shaped groove; and

the solar panel assembly comprises a first solar panel and a second solar panel, wherein the first solar panel is positioned on the first bearing plate and the second bearing plate, and the second solar panel is positioned on the third bearing plate and the fourth bearing plate.

16. The photovoltaic wave plate system of claim 15, wherein one of the first base plate and the second base plate has a reinforcing rib, and a top surface of the reinforcing rib is closer to one of the first solar panel and the second solar panel than a bottom surface of the one of the first base plate and the second base plate.

17. The optoelectronic waveplate system of claim 15 wherein one of the first bottom plate and the second bottom plate has a load-bearing portion, and the load-bearing portion has two ribs opposite to each other.

18. The photovoltaic wave plate system of claim 17, further comprising:

and the supporting piece is positioned between the two convex ribs of the bearing part.

19. The optoelectronic waveplate system of claim 15, further comprising:

the double-sided structure adhesive tape is positioned on the bottom surface of one of the first solar panel and the second solar panel.

20. The photovoltaic wave board system of claim 19, wherein a distance between an edge of one of the first solar panel and the second solar panel and the double sided structural tape is less than 7 mm.

21. The photovoltaic wave plate system of claim 15, further comprising:

and the adhesive is positioned between the first bearing plate and the first solar panel and between the fourth bearing plate and the second solar panel.

22. A photovoltaic wave plate system, comprising:

the wave plate assembly comprises a first wave plate, a second wave plate and a plurality of first supporting plates, wherein the first wave plate is provided with a first bottom plate, the first supporting plates and the second supporting plates are positioned on two sides of the first bottom plate;

a second corrugated board having a second bottom plate, a third loading plate and a fourth loading plate, wherein the third loading plate and the fourth loading plate are located at two sides of the second bottom plate, the second loading plate of the first corrugated board is joined with the third loading plate of the second corrugated board, and the second loading plate and the third loading plate are partially overlapped to define an inverted U-shaped groove;

two first solar panels located on the first carrier plate and the second carrier plate, wherein a distance between the two first solar panels is between 1cm and 20 cm; and

and the two second solar panels are positioned on the third bearing plate and the fourth bearing plate, wherein a distance between the two second solar panels is 1-20 cm.

23. The photovoltaic wave board system of claim 22, wherein the ratio of the distance between the two first solar panels to the longitudinal length of one of the two first solar panels is between 0.5% and 41%.

24. A photovoltaic panel system, comprising:

the wave plate assembly comprises a first wave plate, a second wave plate and a plurality of first loading plates, wherein the first wave plate is provided with a first bottom plate, the first loading plates and the second loading plates are positioned on two sides of the first bottom plate;

a second wave plate having a second bottom plate, a third loading plate and a fourth loading plate, wherein the third loading plate and the fourth loading plate are located at two sides of the second bottom plate, the second loading plate of the first wave plate is joined with the third loading plate of the second wave plate, and the second loading plate and the third loading plate are partially overlapped to define an inverted U-shaped groove;

a first solar panel and a second solar panel, wherein the first solar panel is located on the first carrier plate and the second carrier plate, and the second solar panel is located on the third carrier plate and the fourth carrier plate; and

two steel bodies locked to the bottom surfaces of the first and second wave plates, wherein a steel structure distance between the two steel bodies is between 50cm and 200 cm.

25. The photovoltaic wave board system of claim 24, wherein a ratio of a longitudinal length of one of the first solar panel and the second solar panel to the steel structure spacing is between 25% and 408%.

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