BR202019016936U2 - SUPPORT MATRIX OF A FLOATING ENERGY GENERATION SYSTEM AND SAME GENERATION SYSTEM - Google Patents

Abstract

a floating power generation system and a support matrix for the floating power generation system are provided. the support matrix has a grid shape, including multiple first coupling bars spaced from each other and multiple second coupling bars spaced from each other. the first drawbar is connected to the second drawbar. the first drawbar includes multiple connected floating bodies, and the second drawbar includes multiple connected tubular bars. the tubular bars are mounted on the floating bodies. the support matrix of the floating power generation system described above has the advantages of both the pure floating body solution and the working structure solution in conventional technique, and the support matrix can overcome the defects of the two solutions. with the previous technical solution, high anti-surge capacity and compatibility can be ensured, so that the support matrix has strong applicability in different regions.

Description

SUPPORT MATRIX OF A FLOATING ENERGY GENERATION SYSTEM AND SAME GENERATION SYSTEM TECHNICAL FIELD

[001] The present disclosure refers to the technical field of photovoltaic energy generation, in particular, a floating energy generation system and a support matrix for the floating energy generation system.

FUNDAMENTALS

[002] The existing floating power generation system mainly has the following two structures. In a first structure, a pure floating body solution is adopted, the electrical, cable and photovoltaic modules in the power generation system are all arranged in the floating body, and the operation and maintenance channel is also formed by the floating body. The main drawback of this solution is that compatibility is poor, and the required floating body specifications also change when the PV module specifications and the PV module tilt angle change. In a second structure, a framework solution is adopted. Specifically, the various modules in the power generation system are supported by erecting an interlocking frame network on the floating body. This solution has better compatibility, but has a worse anti-surge capability than the pure floating body solution.

[003] Therefore, how to provide a solution to overcome the above defects is still a technical problem to be solved urgently by experts in the technique.

SUMMARY

[004] The purpose of this disclosure is to provide a floating power generation system and a support matrix for the floating power generation system. The support matrix has advantages of both the pure floating body solution and the working structure solution in conventional technique, and the support matrix can overcome the defects of the two solutions. According to the present disclosure, high anti-surge capacity and high compatibility can be ensured, so that the support matrix has strong applicability in different regions.

[005] In order to solve the above technical problem, a support matrix for a floating power generation system is provided in accordance with the present disclosure. The support matrix has a grid shape, and includes multiple first coupling bars spaced from each other and multiple second coupling bars spaced from each other. The first drawbar is connected to the second drawbar. The first drawbar includes multiple connected floating bodies, the second drawbar includes multiple connected tubular bars, and the tubular bars are mounted on the floating bodies.

[006] According to the support matrix of the floating power generation system provided by the present disclosure, a floating body connection solution is applied to the first coupling bar, thus providing a strong anti-surge capability for the entire floating matrix. . The second coupling bar connecting the first two adjacent coupling bars includes multiple tubular bars; and by adjusting a length of the tubular bar and a connection position, a spacing between the first two adjacent coupling bars can be conveniently adjusted to adapt to photovoltaic modules with different specifications, thereby greatly improving compatibility. In addition, the spacing between the first two adjacent coupling bars is related to the specification of the photovoltaic module. Generally, the spacing is small, that is, the second coupling bar has a small gap between the first two adjacent coupling bars, and the deformation of the second frame-type coupling bar can be effectively controlled.

[007] In other words, the support matrix of the floating power generation system provided by the present disclosure has the advantages of both the pure floating body solution and the working structure solution in conventional technique, and the support matrix can overcome the defects of the two solutions. With the technical solutions in accordance with the present disclosure, high anti-surge capacity and high compatibility can be ensured, so that the floating power generation system has strong applicability in different regions.

[008] Optionally, the first coupling bar extends in a longitudinal direction, an upper surface of the floating body is provided with a mounting groove extending in a lateral direction, and the tubular bar is mounted in the mounting groove.

[009] Optionally, the groove bottom of the mounting groove is provided with a reinforcement structure.

[0010] Optionally, the mounting positions are provided at both ends of the mounting groove. The floating power generation system includes a photovoltaic module and a combiner box. The mounting position is configured to mount a photovoltaic support of the photovoltaic module and a confluence support of the combiner box.

[0011] Optionally, the mounting position is a mounting plate provided with mounting holes, and at least two lateral ends of a lower surface of the floating body have chamfers that gradually tilt upwards from the inside out.

[0012] Optionally, both ends of the floating body are provided with terminals, and two adjacent floating bodies are connected through the terminals.

[0013] Optionally, at the terminals at both ends of the floating body, the terminal at one end protrudes longitudinally from the floating body to form an external terminal, and the terminal at the other end does not protrude longitudinally from the floating body to form an internal terminal. For two adjacent floating bodies, the internal terminal of one floating body is connected to the external terminal of the other floating body. After the two adjacent floating bodies are assembled together, adjacent end portions of the two adjacent floating bodies are abutted.

[0014] Optionally, the support matrix also includes an anchoring device. The anchoring device includes a longitudinal anchoring truss and a lateral anchoring truss. The longitudinal anchoring truss is mounted to the floating body terminals of the same first coupling bar, and the lateral anchoring truss is mounted to the floating body terminals of the first two longitudinally spaced coupling bars.

[0015] Optionally, two lateral ends of the floating body are provided, each, with a groove extending in an up-down direction.

[0016] Optionally, the second coupling bar also includes a cover plate, and two ends of the cover plate are respectively connected to two longitudinally adjacent tubular bars.

[0017] Optionally, a connecting member is disposed between two laterally adjacent tubular bars, and the tubular bars are articulated to the connecting member.

[0018] A floating power generation system including a support matrix is also provided in accordance with the present disclosure. The support matrix is the support matrix of the floating power generation system described above.

[0019] Optionally, the floating energy generation system also includes a photovoltaic module and a combiner box. The photovoltaic module and combiner box are both assembled with the first drawbar, and a cable laying channel is formed between the assembled combiner box and the corresponding first drawbar.

BRIEF DESCRIPTION OF THE FIGURES

[0020] Figure 1 is a schematic structural diagram of a floating power generation system in accordance with one embodiment of the present disclosure.

[0021] Figure 2 is a schematic structural diagram of a support matrix for the floating power generation system in Figure 1.

[0022] Figure 3 is a structural diagram for the connection of a floating body and a tubular bar.

[0023] Figure 4 is a top view of a floating body.

[0024] Figure 5 is a bottom view of a floating body.

[0025] Figure 6 is a structural diagram for the connection of a floating body and a photovoltaic support.

[0026] Figure 7 is a structural diagram for the connection of a floating body, a photovoltaic support and a photovoltaic module.

[0027] Figure 8 is a structural diagram for the connection of a floating body and a combiner box.

[0028] Figure 9 is a schematic structural diagram of two first adjacent coupling bars in a case where the first coupling bar functions as an operation and maintenance channel.

[0029] Figure 10 is a structural diagram of connection of first coupling bars and an anchoring device.

[0030] Figure 11 is a structural diagram for connecting tubular bars and a cover plate.

[0031] Figure 12 is a structural diagram of connection of two adjacent tubular bars and a connecting member.

• - 1 primeira barra de acoplamento, 11 corpo flutuante, 111 ranhura de montagem, 111a estrutura de reforço, 112 placa de montagem, 112a orifício de montagem, 113 chafro, 114 terminal, 114a terminal exterior, 114b terminal, 115 ranhura, 117 suporte de topo;
• - 2 segunda barra de acoplamento, 21 barra tubular, 22 placa de cobertura, 23 número de conexão, 231 haste de articulação;
• - 3 módulo fotovoltaico, 31 suporte fotovoltaico, 311 primeiro estabilizador, 312 segundo estabilizador;
• - 4 caixa combinadora, 41 suporte de confluência, 42 canal de colocação de cabo;
• - 5 treliça de ancoragem longitudinal, 51 treliça principal, 52 treliça auxiliar; e
• - 6 treliça de ancoragem lateral.

[0032] The reference numbers in Figures 1 to 12 are indicated as follows:

• - 1 first drawbar, 11 floating body, 111 mounting slot, 111a reinforcement frame, 112 mounting plate, 112a mounting hole, 113 chafing, 114 terminal, 114a outer terminal, 114b terminal, 115 slot, 117 support bracket top;
• - 2 second coupling bar, 21 tubular bar, 22 cover plate, 23 connection number, 231 articulation rod;
• - 3 photovoltaic module, 31 photovoltaic support, 311 first stabilizer, 312 second stabilizer;
• - 4 combiner box, 41 confluence support, 42 cable placement channel;
• - 5 longitudinal anchoring truss, 51 main truss, 52 auxiliary truss; and
• - 6 lateral anchoring truss.

DETAILED DESCRIPTION OF THE MODALITIES

[0033] In order to make those skilled in the art better understand the technical solutions of the present disclosure, the present disclosure is further illustrated in detail with reference to the attached drawings and specific modalities to follow.

[0034] "Multiple" as used herein refers to the number of objects is generally equal to or greater than two. In a case that "multiple" is used to indicate the number of components, it does not indicate the quantitative relationship of these components.

[0035] The words "first" and "second" are used here to describe two or more structures or components that are identical or similar in structure, and do not indicate a particular limitation in order.

[0036] Reference is made to Figures 1 to 12. Figure 1 is a schematic structural diagram of a floating power generation system provided in accordance with an embodiment of the present disclosure. Figure 2 is a schematic structural diagram of a support matrix for a floating power generation system in Figure 1. Figure 3 is a structural diagram for connecting a floating body and a tubular bar. Figure 4 is a top view of a floating body. Figure 5 is a bottom view of a floating body. Figure 6 is a structural diagram for the connection of a floating body and a photovoltaic support. Figure 7 is a structural diagram for the connection of a floating body, a photovoltaic support and a photovoltaic module. Figure 8 is a structural diagram of the connection of a floating body and a combiner box. Figure 9 is a schematic structural diagram of two adjacent first coupling bars, in a case where the first coupling bar functions as an operation and maintenance channel. Figure 10 is a structural diagram of the connection of the first coupling bars and an anchoring device. Figure 11 is a structural diagram for connecting tubular bars and a cover plate. Figure 12 is a structural connection diagram of two adjacent tubular bars and a connecting member.

[0037] As shown in Figure 1 and Figure 2, a support matrix for a floating power generation system is provided in accordance with the present disclosure. The support matrix has a grid shape, and includes multiple first coupling bars 1 spaced from each other and multiple second coupling bars 2 spaced from each other. The first drawbar 1 is connected to the second drawbar 2.

[0038] Unlike the conventional technique, in the present description, the first coupling bar 1 includes multiple connected floating bodies 11, the second coupling bar 2 includes multiple connected tubular bars 21, and the tubular bars 21 are mounted on the floating bodies 11. With this structure, a floating body connection solution 11 is applied to the first coupling bar 1, thus providing a strong anti-surge capability for the entire floating matrix. The second coupling bar 2 connecting the first two adjacent coupling bars 1 includes multiple tubular bars 21; and by adjusting the length of the tubular bar 21 and the connection position, the spacing between the first two adjacent coupling bars 1 can be conveniently adjusted to adapt to the PV module 3 with different specifications and different installation inclination angles, thus improving greatly compatibility. In addition, the spacing between two adjacent first coupling bars 1 is related to the specification of the PV module 3. Generally, the spacing is small, that is, the second coupling bar 2 has a small gap between the first two coupling bars adjacent 1, and the deformation of the second frame-type coupling bar 2 can be effectively controlled.

[0039] In other words, the support matrix of the floating power generation system provided by the present disclosure has the advantages of both the pure floating body solution and the working structure solution in conventional technique, and the support matrix can overcome the defects of the two solutions. With the technical solutions of the present disclosure, high anti-surge capacity and compatibility can be ensured, so that the floating energy generation system has strong applicability in different regions.

[0040] Furthermore, in comparison with the pure floating body solution and the frame solution in the conventional technique, the number of the floating bodies 11 and the number of the frames (referring mainly to the tubular bar 21 in the mode of the present disclosure ) in the support matrix provided by the present disclosure can be greatly reduced, so that the floating power generation system has a lower overall cost and is convenient for popularization. In addition, because the number of frames is small, the floating matrix itself has a relatively small charge, thus providing greater buoyancy. Especially in a case where the number of lines is increased, the supreme buoyancy provided by the floating matrix does not decrease, but in this way it better supports the photovoltaic module 3 and so on.

[0041] Here, an angle between the first coupling bar 1 and the second coupling bar 2 is not limited in the mode of the present disclosure. A person skilled in the art can adjust the angle according to the real needs of an implementation.

[0042] In one embodiment, the first coupling bar 1 can extend in the longitudinal direction, and the second coupling bar 2 can extend in the lateral direction, that is, the angle between the first and second coupling bars is 90 degrees . It should be understood that the 90 degree angle here refers to approximately 90 degrees, and a particular installation error is tolerated.

[0043] The first coupling bar 1 can include multiple floating bodies 11, that is, the first coupling bar 1 can be a floating body bar. As shown in Figure 3 and Figure 5, the upper surface of the floating body 11 can be provided with a mounting groove 111 extending laterally, and the tubular bar 21 can be mounted in the mounting groove 111. In detail, the tubular bar 21 can be inserted into the mounting groove 111, the groove bottom of the mounting groove 111 is also provided with connection holes, and a connecting member such as a screw, rivet or the like is bolted to the connection hole to secure the tubular bar 21. The connecting member here is preferably a plastic member to improve the flexible deformation capacity of a joint between the tubular bar 21 and the floating body 11; in addition, the corrosion resistance of the joint can be improved to ensure the reliability of the connection between the tubular bar 21 and the floating body 11 during long-term use. Practically, the connecting members can also be made of a metal such as stainless steel, which can also achieve the technical effects of connecting the tubular bar 21 and the floating body 11 and resisting corrosion.

[0044] It should be noted that the solution for providing the mounting groove 111 for positioning and mounting the tubular bar 21 is only a preferred solution of the modality of the present disclosure, and is not explained to limit the scope of implementation of the support matrix provided this disclosure. In case of satisfying the reliability condition, another connection solution between the tubular bar 21 and the floating body 11 can also be adopted. For example, the above mentioned mounting groove 111 may not be provided. In this case, the tubular bar 21 can be mounted directly on the upper surface of the floating body 11 through a connecting member, such as a screw, which can also achieve connection and fixation between the tubular bar 21 and the floating body 11.

[0045] The groove bottom of the mounting groove 111 can be provided with a reinforcement structure 111a. The reinforcement structure 111a can be of a groove type, which can improve the deformation resistance of the floating body 11 during processing, and can prevent the shrinkage of a groove bottom of the mounting groove 111, in large extent during the processing of the floating body 11, and the relative positional displacement of the connection hole caused by the shrinkage.

[0046] The two ends of the mounting slot 111 can be provided with mounting positions. The floating power generation system can also include a photovoltaic module 3 and a combiner box 4, and the photovoltaic module 3 and combiner box 4 can be installed in the mounting positions. That is, the floating body 11 can serve as a supporting floating body for both the photovoltaic module 3 and the combiner box 4, thus greatly reducing the types of the floating bodies 11, to simplify the processing and installation process, and being beneficial to improve further compatibility. For the specific structures of the photovoltaic module 3 and the combiner box 4, consult the conventional technique, and details are not described here.

[0047] In detail, as shown in Figure 6 and Figure 7, the photovoltaic module 3 can be mounted in the mounting position by the photovoltaic support 31. The photovoltaic support 31 can include a first stabilizer 311 and a second stabilizer 312. The heights of the two stabilizers can be different, so that the photovoltaic module 3 can be mounted on the first stabilizer 311 and the second stabilizer 312 at an adjustment angle. Here, the specific value of the adjustment angle is not limited in the mode of the present description, and the value is related to the installation latitude and the solar lighting angle of the floating power generation system. In an implementation, those skilled in the art can adjust the angle according to actual needs.

[0048] A pressing block can be provided above the first stabilizer 311 and the second stabilizer 312, and the pressing block can form a bayonet. The photovoltaic module 3 can be tightened on the bayonet of the pressing block to make a preliminary position on the photovoltaic module 3, and then the photovoltaic module 3 can be fixed by means of a connection number such as a screw, a rivet or the like. For the structure of the pressing block and the installation structure of the pressing block and photovoltaic module 3, consult the existing project, and details are not described here.

[0049] As shown in Figure 8, the combiner box 4 can be mounted in the mounting position by the confluence support 41, and an interval between the combiner box 4 and the floating body 11 forms a cable placement channel 42 for placing the cable. That is, the floating body 11 can also provide support for the cable, so that the floating cable support body in conventional technique can be omitted to further reduce the types of the floating bodies 11.

[0050] The photovoltaic support 31 and the confluence support 41 can be metal supports or plastic supports, which can be determined according to the actual installation requirement. In a case where the support is a metal support, the mounting position can be additionally provided with a flexible support plate. The flexible backing plate can be a flexible component, such as a plastic backing plate or a rubber backing plate, in order to reduce the wear of the floating body 11 mounting position caused by the metal support, and prolong the life floating body useful 11. In a case where the support is a plastic support, the reinforced polymer resin can be used to improve the flexural strength and corrosion resistance.

[0051] The mounting position can be a mounting plate 112. The mounting plate 112 can be provided with the mounting hole 112a through which the photovoltaic support 31 and the confluence support 41 can be fixed. Mounting plate 112 can be supplied separately, and then integrated with float 11 when float 11 is processed. Alternatively, the plate-like mounting plate 112 can be formed simultaneously when the floating body 11 is processed. To facilitate processing, at least the two lateral ends of the lower surface of the floating body 11 may have chamfers 113, which gradually tilt upwards from the inside to the outside, i.e. the lower surface of the floating body 11 can present a V-shape as a whole, to reduce the thickness of the two lateral ends of the floating body 11, thereby reducing a stretch ratio of the floating body 11 on the mounting plate 112, so that the floating body 11 can be processed more conveniently .

[0052] The floating body 11 can also be provided with a top support 117 connecting a top surface and a bottom surface, to improve the overall structural rigidity of the floating body 11, and also to prevent bulging caused by a temperature difference between the interior and exterior of the floating body 11, thus ensuring the stability of the structure of the floating body 11 during long-term use.

[0053] The two ends of the floating body 11 can be provided with terminals 114. The terminals 114 of the two adjacent floating bodies 11 can be anchored, and connecting members such as screws and nuts can be used to connect the two floating bodies 11 adjacent in the longitudinal direction. The connection member here is preferably a plastic member to improve the flexible deformation capacity of the joint of the adjacent floating bodies 11, and the corrosion resistance capacity of the joint can be improved to guarantee the reliability of the connection of the two adjacent floating bodies 11 during long-term use. Practically, the connecting member can also be made of a metallic material such as stainless steel, which can also achieve the technical effect of connecting the two adjacent floating bodies 11 and resisting corrosion.

[0054] Referring to Figure 4, at the terminals 114 at both ends of the floating body 11, the terminal 114 at one end can project from the floating body 11 in the longitudinal direction to form an external terminal 114a, and the terminal 114 at the other end it does not protrude from the floating body 11 in the longitudinal direction (i.e., there is no extension in the longitudinal direction) to form an internal terminal 114b. During assembly, for two adjacent floating bodies 11, the inner terminal 114b of one floating body is connected to the outer terminal 114a of the other floating body. After the two adjacent floating bodies are assembled together, the adjacent end portions of the two adjacent floating bodies 11 are abutted, thereby improving the stability of the connection between the two adjacent floating bodies 11.

[0055] It should be noted that the two adjacent floating bodies 11 can be abutted in various ways, and are not necessarily limited to the design of the outer terminal 114a and the inner terminal 114b. Other forms of design can also be used by those skilled in the art in an implementation. For example, the floating body 11 can be provided only with the internal terminal 114b; and by means of a plate-shaped connecting member, the two floating bodies 11 can be connected and the ends of the floating bodies can be abutted.

[0056] In the description above, the floating body 11 is mainly configured to support the photovoltaic module 3 and the combiner box 4. In addition, the floating body 11 can have other functions.

[0057] In one embodiment, as shown in Figure 9, the first coupling bar 1 composed of the floating body 11 can also function as an operation and maintenance channel. In this case, the upper surface of the floating body 11 can be provided with non-slip patterns (not shown in the Figure) to improve the roughness of the upper surface of the floating body 11, thereby preventing the worker from sliding when walking on the floating body 11 in large extent.

[0058] In another embodiment, as shown in Figure 10, the support matrix of the floating power generation system provided by the present disclosure can be additionally provided with an anchoring device. The anchoring device may include a longitudinal anchoring truss 5 and a lateral anchoring truss 6 to fix the mounting position of the support matrix on the water surface.

[0059] In installation, the longitudinal anchoring truss 5 can be mounted to the terminals 114 of the floating body 11 with the same first coupling bar 1. In detail, the longitudinal anchoring truss 5 can include a main truss 51 and a truss auxiliary 52. The main truss 51 can extend in the longitudinal direction, and the auxiliary truss 52 can extend in the lateral direction. The auxiliary truss 52 can be connected to the two terminals 114 at the same end of the floating body 11, and the main truss 51 can be connected to the two auxiliary trusses 52. Referring to Figure 10, the auxiliary trusses 52 at both ends of the truss longitudinal anchoring 5 can be mounted on the same floating body 11, or can be mounted on different floating bodies 11 of the same first coupling bar 1, which can be determined according to parameters such as the length of the main truss 51. The anchoring truss side 6 can be mounted on the terminals 114 of the floating body 11 of the first two longitudinally spaced coupling bars 1. Likewise, the two ends of the side anchoring truss 6 can be connected to the first two adjacent coupling bars 1 (the solution in Figure 10), or can be connected to the first two coupling bars 1 that are not adjacent. Alternatively, the side anchor truss 6 can be connected to three or more first coupling bars 1, which is determined according to parameters such as the side length of the side anchor truss 6.

[0060] The two lateral ends of the floating body 11 are each provided with a groove 115 extending in an up-down direction. On the one hand, the groove 115 can extend the lengths of the two sides of the floating body 11 in the long direction (i.e., the longitudinal direction), to increase the resistance of the long side of the floating body. On the other hand, the groove 115 can also function as a limiting structure for packaging to facilitate the packaging and transportation of the floating body 11. Here, the number of grooves 115 arranged on the lateral ends of the floating body 11 is not limited in the present embodiment. disclosure. In an implementation, experts in the art can define the number of the grooves according to the actual needs.

[0061] According to the description above, in the support matrix of the floating power generation system provided by the present description, the floating body 11 can simultaneously provide installation connection points for the photovoltaic module 3, the combiner box 4, the cable and the anchoring device, and can also function as an operation and maintenance channel. The floating body 11 achieves really multipurpose all-in-one, thus reducing the types of floating bodies 11 in the support matrix to the maximum extent, greatly facilitating the production, manufacture, transportation and management of the floating body products 11, reducing the difficulty of installation, generating a positive effect in improving installation efficiency, and thus greatly reducing the total cost.

[0062] As shown in Figure 11, the second coupling bar 2 can further include a cover plate 22. The two ends of the cover plate 22 can respectively be connected to two adjacent tubular bars 21 in the longitudinal direction. The cover plate 22 can cooperate with the two tubular bars 21 to form an operation and maintenance channel, for the personnel to maintain the photovoltaic module 3, the combiner box 4 and the cable and so on. Here, the cover plate 22 can be a plastic grid, a floating cover plate body, a metal wire mesh, and the cover plate 22 can be connected and fixed to the tubular bar 21 by a connecting member, such as a rivet, a rim or something like that.

[0063] In the lateral direction, a second coupling bar 2 includes multiple tubular bars 21. A connecting member 23 can be provided between the two adjacent tubular bars 21, and the tubular bar 21 can be articulated with the connecting members 23. In this way, the tubular bar 21 and the connecting members 23 can relatively rotate on a pivot rod 231, and the flexible deformation capacity of the joint between the tubular bar 21 and the connecting member 23 can be greatly improved, thereby improving the anti-surge capacity of the second coupling bar 2. Practically, in manufacture, the tubular bar 21 can be made of a material such as a resin reinforced with thermosetting polymer, so that the tubular bar 21 itself has a certain flexibility. As long as flexibility can meet usage requirements, the way of connecting two adjacent tubular bars 21 is unnecessary to be strictly limited.

[0064] A cross-sectional shape of the tubular bar 21 can be a shape of a "口" character, a shape of C or a shape of U, and can be adjusted according to actual needs.

[0065] A floating power generation system, including a support matrix is also provided in accordance with the present disclosure. The support matrix can be the support matrix described in the modalities above. The technical effect of the support matrix mentioned above can also be achieved by the floating power generation system according to the present description, and is not described here.

[0066] The floating power generation system mentioned above may also include a photovoltaic module 3 and a combiner box 4. The photovoltaic module 3 and combiner box 4 can be mounted on the first coupling bar 1. For the specific installation solution , see the content above, and the details are not described here.

[0067] The preferred modalities of the present disclosure are described above, and it should be noted that those skilled in the art can make multiple improvements and modifications without departing from the principles of the present disclosure. These improvements and modifications must be considered to fall within the scope of protection of this disclosure.

Claims (13)

Support matrix of a floating power generation system, in which the support matrix has a grid shape CHARACTERIZED by the fact that it comprises:
a plurality of first coupling bars (1) spaced from one another; and
a plurality of second coupling bars (2) spaced from each other,
wherein the first coupling bar (1) is connected to the second coupling bar (2); the first coupling bar (1) comprises a plurality of connected floating bodies (11), the second coupling bar (2) comprises a plurality of connected tubular bars (21); and the tubular bars (21) are mounted on the floating bodies (11). Support matrix according to claim 1, CHARACTERIZED by the fact that the first coupling bar (1) extends in a longitudinal direction, an upper surface of the floating body (11) is provided with a mounting groove (111) extending in a lateral direction, and the tubular bar (21) is mounted in the mounting groove (111). Supporting matrix according to claim 2, CHARACTERIZED by the fact that a groove bottom of the mounting groove (111) is provided with a reinforcement structure (111a). Matrix, according to claim 2, CHARACTERIZED by the fact that mounting positions are provided at both ends of the mounting groove (111); and
the floating power generation system comprises a photovoltaic module (3) and a combiner box (4), and the mounting position is configured to mount a photovoltaic support (31) of the photovoltaic module (3) and a confluence support (41 ) of the combiner box (4). Support matrix, according to claim 4, CHARACTERIZED by the fact that the mounting position is a mounting plate (112) provided with mounting holes (112a); and
at least two lateral ends of a lower surface of the floating body (11) have chamfers (113) that gradually tilt upward from the inside out. Array according to claim 2, CHARACTERIZED by the fact that both ends of the floating body (11) are provided with terminals (114), and two adjacent floating bodies (11) are connected through the terminals (114). Array of, according to claim 6, CHARACTERIZED by the fact that at the terminals (114) at both ends of the floating body (11), the terminal (114) at one end protrudes longitudinally from the floating body (11) to form an external terminal (114a), and the terminal (114) at the other end does not protrude longitudinally from the floating body (11) to form an internal terminal (114b); and
for two adjacent floating bodies (11), the inner terminal (114b) of one floating body is connected to the outer terminal (114a) of the other floating body, and adjacent end portions of the two adjacent floating bodies (11) are abutted after the two adjacent floating bodies are assembled together. Support matrix, according to claim 6, CHARACTERIZED by the fact that it also comprises: an anchoring device,
wherein the anchoring device comprises a longitudinal anchoring truss (5) and a lateral anchoring truss (6); and
the longitudinal anchoring truss (5) is mounted on the terminals (114) of the floating body (11) of the same first coupling bar (1), and the lateral anchoring truss (6) is mounted on the terminals (114) of the floating body (11) of the first two coupling bars (1) spaced longitudinally. Supporting matrix according to claim 2, CHARACTERIZED by the fact that two lateral ends of the floating body (11) are each provided with a groove (115) extending in an up-down direction. Support matrix according to any one of claims 2 to 9, CHARACTERIZED by the fact that the second coupling bar (2) further comprises a cover plate (22), and two ends of the cover plate are respectively connected to two tubular bars adjacent longitudinally (21). Supporting matrix according to claim 10, CHARACTERIZED by the fact that a connecting member (23) is arranged between two laterally adjacent tubular bars (21), and the tubular bars (21) are articulated to the connecting member (23 ). Floating power generation system, CHARACTERIZED by the fact that it comprises: a support matrix, wherein the support matrix is the support matrix of a floating power generation system according to any one of claims 1 to 11. Floating power generation system, according to claim 12, CHARACTERIZED by the fact that it also includes:
a photovoltaic module (3);
and a combiner box (4),
wherein the photovoltaic module (3) and the combiner box (4) are both mounted for the first coupling bar (1) and a cable laying channel (42) is formed between the mounted combiner box (4) and the first corresponding coupling bar (1).

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