CN216034988U - Support up-bridging type water surface photovoltaic supporting system - Google Patents

Abstract

The utility model discloses an upward-bridging-type water surface photovoltaic supporting system with a support, and relates to the technical field of photovoltaic power generation. The photovoltaic square matrix backbone net rack comprises grids and wave-proof rings; the grid comprises a transverse operation and maintenance channel and a longitudinal connecting channel; the wave-resisting ring comprises a transverse channel and a longitudinal channel; the photovoltaic module supporting system comprises a photovoltaic module supporting unit, and the photovoltaic module supporting unit is used for fixing the photovoltaic module in an inclined mode. The photovoltaic module supporting unit is embedded into the longitudinal connecting channel in an upward bridging manner from the bottom of the longitudinal connecting channel, and a supporting floating body of the photovoltaic module supporting unit is not used as a load for connecting the floating body; the supporting floating body is embedded into the connecting floating body in an upward bridging mode, deflection of the supporting floating body along the long edge direction can be resisted, and stability is enhanced.

Description

Support up-bridging type water surface photovoltaic supporting system

Technical Field

The utility model relates to the technical field of photovoltaic power generation, in particular to a support upward bridging type water surface photovoltaic support system.

Background

The floating type water surface photovoltaic power station utilizes the idle water surface to arrange the floating body, the floating body supports the photovoltaic module, and the function of photovoltaic power generation is realized on the water surface. Compared with a land photovoltaic power station, the floating type water surface photovoltaic power station component is placed above the floating type floating body, and the floating type water surface photovoltaic power station component has the characteristics of no land occupation and high generating capacity; the power generation gain is realized by reasonably utilizing idle water surface resources, and meanwhile, the increase of water body is reduced, so that the landscape benefit is brought.

The floating type water surface photovoltaic power station is in a humid environment, the supporting structure component is easy to corrode, and the supporting structure component is required to ensure the stability of the photovoltaic array in a wind and wave environment; under the wave of photovoltaic 'flat price surfing', how to reduce the manufacturing cost of the supporting structure part is the key problem required to be faced by the continuous development of the floating type water surface photovoltaic power station while ensuring the stable operation of the floating type water surface photovoltaic power station for 25 years.

Moreover, with the rapid development of the industries of polycrystalline silicon, silicon wafers, battery plates and photovoltaic modules, the capacity of a single photovoltaic module is continuously increased, the size specification of the single photovoltaic module is also continuously increased, and for the sake of safety, the installation distance between a plurality of photovoltaic modules is required to be larger than half of the length of the long edge of the single photovoltaic module; four mounting points of a single photovoltaic module in the full floating body type water surface photovoltaic power station need to be fixed on the same floating body, under the condition that the size of the photovoltaic module is increased, the size of the floating body is continuously increased, so that the wall thickness of the floating body is uneven, the production efficiency is low, the power consumption of equipment is high, the number of production machines is small, and the problem that the floating type water surface photovoltaic power station needs to solve is solved by solving the contradiction between the size of the floating body and the size of the floating body.

Therefore, it is necessary to develop a support-up cross-over type water surface photovoltaic support system with the characteristics of simple installation, strong expansibility, low water surface coverage rate, convenient operation and maintenance and the like.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the background technology and provide a support-upward bridging type water surface photovoltaic support system.

In order to achieve the purpose, the technical scheme of the utility model is as follows: support jumper connection formula surface of water photovoltaic braced system that makes progress, its characterized in that: the photovoltaic square matrix backbone net rack comprises grids and wave-resisting rings; the grid is of a net structure and comprises a plurality of rows of transverse operation and maintenance channels arranged in parallel at intervals and a plurality of rows of longitudinal connecting channels arranged in parallel at intervals, and the transverse operation and maintenance channels are perpendicular to the longitudinal connecting channels;

the wave-proof ring is positioned at the periphery of the grid and comprises transverse channels positioned at two ends of the longitudinal connecting channel and longitudinal channels positioned at two ends of the transverse operation and maintenance channel;

the photovoltaic module supporting system comprises a plurality of photovoltaic module supporting units, the photovoltaic module supporting units are embedded into the longitudinal connecting channels in an upward bridging mode from the bottoms of the longitudinal connecting channels, and the photovoltaic module supporting units are used for fixing the photovoltaic modules in an inclined mode.

In the technical scheme, each row of the transverse operation and maintenance channel is formed by interconnecting a plurality of walkway floating bodies, each row of the longitudinal connecting channel comprises a plurality of connecting floating bodies, and the connecting floating bodies are positioned between two walkway floating bodies in two adjacent rows;

the transverse channel is formed by interconnecting a plurality of walkway floating bodies, the longitudinal channel comprises a plurality of small walkway floating bodies and a plurality of equipment floating bodies, the equipment floating bodies are connected with the transverse operation and maintenance channel, and the equipment floating bodies are positioned between the two small walkway floating bodies;

the photovoltaic module supporting unit comprises a supporting floating body connected with the longitudinal connecting channel and a connecting piece which is positioned on the supporting floating body and used for fixing the photovoltaic module.

In the technical scheme, the walkway floating body is in a dumbbell-shaped structure, the middle part of the walkway floating body is a narrow area, two ends of the walkway floating body are wide areas, walkway floating body ear plates are arranged at four corners of the walkway floating body, side wall ear plates are arranged on two side walls of the narrow area, and a plurality of walkway floating bodies are connected through the walkway floating body ear plates;

the connecting floating body is of a rectangular structure, connecting floating body lug plates are arranged at four corners of the connecting floating body, two transversely-through grooves are formed in the lower surface of the connecting floating body, four supporting floating body mounting planes are arranged at two ends, corresponding to the grooves, of the upper surface of the connecting floating body, mounting round holes penetrating through the grooves are formed in the supporting floating body mounting planes, and the connecting floating body is connected with the side wall lug plates of the narrow area of the walkway floating body through the connecting floating body lug plates;

the supporting floating body comprises a high-position supporting floating body and a low-position supporting floating body, the bottoms of the high-position supporting floating body and the low-position supporting floating body are both cross rods, high-position supporting square columns are arranged at two ends of each cross rod of the high-position supporting floating body, low-position supporting square columns are arranged at two ends of each low-position supporting floating body, connecting cylinders matched with the mounting round holes are arranged on the cross rods, and the supporting floating bodies are upwards bridged at the bottoms of the connecting floating bodies through the connecting cylinders and the mounting round holes; the connecting piece is positioned on the top of the high-position supporting square column and the low-position supporting floating body.

In the technical scheme, the equipment floating body is of a rectangular structure, two through holes are formed in the middle of the equipment floating body, the lug plates of the equipment floating body are arranged at four corners of the equipment floating body, and equipment mounting holes for fixing electrical equipment are formed in the long edge of the equipment floating body;

the small walkway floating body is of a rectangular structure, connecting mechanisms are arranged at four corners of the small walkway floating body, and the small walkway floating body is connected with the equipment floating body lug plate of the equipment floating body and the walkway floating body lug plate of the walkway floating body through the connecting mechanisms.

In the technical scheme, mounting columns are arranged at the tops of the high-position supporting floating body and the low-position supporting floating body, and mounting column round holes are formed in the center of the mounting columns;

the connecting piece comprises a support mounting plane and an assembly mounting plane, the support mounting plane and the assembly mounting plane are both provided with connecting piece mounting round holes, included angles between the support mounting plane and the assembly mounting plane are equal to mounting inclination angles of the photovoltaic assembly, the connecting piece mounting round holes of the support mounting plane and mounting column round holes of mounting columns are fixed through bolts, and the connecting piece mounting round holes of the assembly mounting plane and mounting holes of the photovoltaic assembly are fixed through bolts.

In the above technical solution, the bottom surface of the supporting floating body and the bottom surface of the connecting floating body are located on the same plane.

In the above technical solution, the longitudinal channels have a plurality of rows.

In the technical scheme, one or more equipment floating bodies are arranged between the two small walkway floating bodies.

In the technical scheme, one or more connecting floating bodies are arranged between two adjacent rows of walkway floating bodies.

Compared with the prior art, the utility model has the following advantages:

1) the photovoltaic module supporting unit is embedded into the longitudinal connecting channel in an upward bridging manner from the bottom of the longitudinal connecting channel, and a supporting floating body of the photovoltaic module supporting unit is not used as a load for connecting the floating body; the supporting floating body is embedded into the connecting floating body in an upward bridging mode, deflection of the supporting floating body along the long edge direction can be resisted, and stability is enhanced.

2) Compared with a floating body with a large through hole and similar length and width, the connecting floating body has the advantages that the area of the inner side wall of the through hole is not increased, materials are saved under the condition of equivalent buoyancy, the processing difficulty of the connecting floating body and the production of waste edge waste are reduced, the cost is lower, and the economical efficiency of a water surface photovoltaic power station is improved.

3) The walkway floating body is of a dumbbell-shaped structure, the wide area can ensure that the transportation and maintenance personnel still can provide sufficient buoyancy when walking to the edge of the walkway floating body, and the narrow area is connected with the connecting floating body at two sides, so that the material consumption of the floating body can be reduced to the maximum extent, the cost of the floating body is reduced, and the economy of a water surface photovoltaic power station is improved under the condition that the buoyancy requirement is not influenced.

4) The photovoltaic module supporting system provided by the utility model adopts the connecting piece with a certain angle to replace an aluminum alloy pressing block and a base, so that the cost is low, and the construction is simple.

5) The extensible walkway has good expansibility, a single or a plurality of connecting floating bodies can be arranged in the longitudinal connecting channel between two walkway floating bodies in two adjacent rows according to requirements, one row of operation and maintenance channels of one row of photovoltaic modules can be expanded into one row of operation and maintenance channels of a plurality of rows of photovoltaic modules, and the construction is simple.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural diagram of a photovoltaic matrix backbone net rack and a photovoltaic module support system.

Fig. 3 is a schematic structural diagram of a photovoltaic matrix backbone grid.

Fig. 4 is a schematic structural diagram of an operation and maintenance channel of two rows of photovoltaic modules in embodiment 1.

Fig. 5 is a schematic structural view of the hidden photovoltaic module shown in fig. 4.

Fig. 6 is a schematic structural view 1 of the connecting float.

Fig. 7 is a schematic view of the structure of the connecting float 2.

Fig. 8 is a schematic structural view of the walkway float.

Fig. 9 is a schematic structural view of the support float.

Figure 10 is a schematic view of the structure with the support float straddling the connecting float.

Fig. 11 is a schematic structural view of the connector.

Fig. 12 is a schematic structural view of the device float.

Fig. 13 is a schematic structural view of the small-walkway floating body.

FIG. 14 is a schematic diagram of the structure of an apparatus column according to embodiment 1.

Fig. 15 is a schematic structural diagram of a small unit of the equipment column in embodiment 1.

Fig. 16 is a schematic structural diagram of an operation and maintenance channel of a row of photovoltaic modules in embodiment 2.

FIG. 17 is a schematic diagram of the structure of an apparatus column in example 2.

Fig. 18 is a schematic structural diagram of a small unit of the equipment column in embodiment 2.

Wherein, 1-photovoltaic matrix backbone net rack, 11-grid, 111-transverse operation and maintenance channel, 112-longitudinal connecting channel, 12-wave-proof ring, 121-transverse channel, 122-longitudinal channel, 2-photovoltaic component supporting system, 21-photovoltaic component supporting unit, 22-supporting floating body, 221-high supporting floating body, 222-low supporting floating body, 223-cross bar, 224-high supporting square column, 225-low supporting square column, 226-connecting cylinder, 227-mounting column, 228-mounting column round hole, 23-connecting piece, 231-bracket mounting plane, 232-component mounting plane, 233-connecting piece mounting round hole, 3-photovoltaic component, 41-walkway floating body, 411-narrow area, 412-wide area, 413-aisle floating body ear plates, 414-side wall ear plates, 42-connection floating bodies, 421-connection floating body ear plates, 422-grooves, 423-supporting floating body installation planes, 424-installation round holes, 43-small aisle floating bodies, 431-connection mechanisms, 44-device floating bodies, 441-through holes, 442-device floating body ear plates and 443-device installation holes.

Detailed Description

The embodiments of the present invention will be described in detail with reference to the accompanying drawings, which are not intended to limit the present invention, but are merely exemplary. While the advantages of the utility model will be clear and readily understood by the description.

With reference to the accompanying drawings: support jumper connection formula surface of water photovoltaic braced system that makes progress, its characterized in that: the photovoltaic square matrix backbone net rack comprises a photovoltaic square matrix backbone net rack 1 and a photovoltaic module supporting system 2, wherein the photovoltaic square matrix backbone net rack 1 comprises grids 11 and wave-resistant rings 12; the grid 11 is of a mesh structure, the grid 11 comprises a plurality of rows of transverse operation and maintenance channels 111 arranged in parallel at intervals and a plurality of columns of longitudinal connecting channels 112 arranged in parallel at intervals, and the transverse operation and maintenance channels 111 are perpendicular to the longitudinal connecting channels 112;

the wave guard ring 12 is positioned at the periphery of the grid 11, and the wave guard ring 12 comprises a transverse channel 121 positioned at two ends of a longitudinal connecting channel 112 and a longitudinal channel 122 positioned at two ends of a transverse operation and maintenance channel 111;

the photovoltaic module support system 2 comprises a plurality of photovoltaic module support units 21, the photovoltaic module support units 21 are embedded into the longitudinal connecting channels 112 in a bridging manner from the bottoms of the longitudinal connecting channels 112 to the upper part, and the photovoltaic module support units 21 are used for fixing the photovoltaic modules 3 in an inclined manner.

Each row of the transverse operation and maintenance channel 111 is formed by interconnecting a plurality of walkway floating bodies 41, each row of the longitudinal connecting channel 112 comprises a plurality of connecting floating bodies 42, and the connecting floating bodies 42 are positioned between two walkway floating bodies 41 in two adjacent rows;

the transverse channel 121 is formed by interconnecting a plurality of walkway floats 41, the longitudinal channel 122 comprises a plurality of small walkway floats 43 and a plurality of device floats 44, the device floats 44 are connected with the transverse maintenance channel 111, and the device floats 44 are positioned between the two small walkway floats 43;

the photovoltaic module support unit 21 includes a support floating body 22 connected with the longitudinal connecting channel 112 and a connecting member 23 located on the support floating body 22 and used for fixing the photovoltaic module 3.

As shown in fig. 8, the walkway floating body 41 is of a dumbbell-shaped structure, the middle part of the walkway floating body 41 is a narrow area 411, two ends of the walkway floating body 41 are wide areas 412, walkway floating body ear plates 413 are arranged at four corners of the walkway floating body 41, side wall ear plates 414 are arranged on two side walls of the narrow area 411, and a plurality of walkway floating bodies 41 are connected through the walkway floating body ear plates 413;

as shown in fig. 6 and 7, the connecting floating body 42 is a rectangular structure, connecting floating body ear plates 421 are arranged at four corners of the connecting floating body 42, two transversely through grooves 422 are formed in the lower surface of the connecting floating body 42, four supporting floating body mounting planes 423 are arranged at two ends of the upper surface of the connecting floating body 42 corresponding to the grooves 422, mounting round holes 424 penetrating through the grooves 422 are formed in the supporting floating body mounting planes 423, and the connecting floating body 42 is connected with the side wall ear plates 414 of the narrow area 411 of the walkway floating body 41 through the connecting floating body ear plates 421;

as shown in fig. 9 and 10, the support floating body 22 comprises a high-position support floating body 221 and a low-position support floating body 222, the bottoms of the high-position support floating body 221 and the low-position support floating body 222 are both cross bars 223, high-position support square columns 224 are arranged at two ends of the cross bars 223 of the high-position support floating body 221, low-position support square columns 225 are arranged at two ends of the low-position support floating body 222, connecting cylinders 226 matched with the mounting round holes 424 are arranged on the cross bars 223, and the support floating body 22 is bridged upwards at the bottoms of the connecting floating bodies 42 through the connecting cylinders 226 and the mounting round holes 424; the connectors 23 are located on top of the high support square column 224 and the low support float 222.

As shown in fig. 12, the device floating body 44 has a rectangular structure, two through holes 441 are formed in the middle of the device floating body 44, device floating body ear plates 442 are provided at four corners of the device floating body 44, and device mounting holes 443 for fixing electrical devices are formed in the long sides of the device floating body 44;

as shown in fig. 13, the small walkway floating body 43 has a rectangular structure, the small walkway floating body 43 is provided with connecting mechanisms 431 at four corners, and the small walkway floating body 43 is connected with the device floating body ear plates 442 of the device floating body 44 and the walkway floating body ear plates 413 of the walkway floating body 41 through the connecting mechanisms 431.

Mounting columns 227 are arranged at the tops of the high-position supporting floating body 221 and the low-position supporting floating body 222, and mounting column round holes 228 are formed in the center positions of the mounting columns 227;

as shown in fig. 11, the connecting member 23 includes a bracket mounting plane 231 and a module mounting plane 232, the bracket mounting plane 231 and the module mounting plane 232 are both provided with a connecting member mounting circular hole 233, an included angle between the bracket mounting plane 231 and the module mounting plane 232 is equal to a mounting inclination angle of the photovoltaic module 3, the connecting member mounting circular hole 233 of the bracket mounting plane 231 is fixed to the mounting column circular hole 228 of the mounting column 227 by a bolt, and the connecting member mounting circular hole 233 of the module mounting plane 232 is fixed to the mounting hole of the photovoltaic module 3 by a bolt.

The bottom surface of the support float 22 and the bottom surface of the connection float 42 are located on the same plane.

The longitudinal channels 122 have a plurality of rows.

Between the two small walkway floats 43 there are one or more equipment floats 44.

One or more connecting floating bodies 42 are arranged between two walkway floating bodies 41 in two adjacent rows.

Example 1

As shown in fig. 1, fig. 2, fig. 3, fig. 4, and fig. 5, in the support-upward-crossing-type water surface photovoltaic support system provided in this embodiment, two connecting floating bodies 42 are arranged between two adjacent rows of walkway floating bodies 41, and correspond to one row of operation and maintenance channels of two rows of photovoltaic modules 3.

As shown in fig. 14 and 15, the longitudinal channels 122 of the wave guard ring 12 are transversely expanded to form a plurality of columns of equipment for placing equipment such as a junction box and a cable, wherein the equipment column is formed by a plurality of equipment column small units s-1; the device train small unit S-1 of the present embodiment is constituted by a single small walkway floating body 43 and two device floating bodies 44.

Example 2

As shown in fig. 16, 17, and 18, the present embodiment is different from embodiment 1 in that embodiment 2 adopts a one-row photovoltaic operation and maintenance channel manner of a photovoltaic module, a single connecting floating body 42 is provided between two adjacent rows of walkway floating bodies 41, and the equipment column small unit S-2 is composed of a single small walkway floating body 43 and a single equipment floating body 44.

Other parts not described belong to the prior art.

Claims (9)

1. Support jumper connection formula surface of water photovoltaic braced system that makes progress, its characterized in that: the photovoltaic square matrix backbone net rack comprises a photovoltaic square matrix backbone net rack (1) and a photovoltaic module supporting system (2), wherein the photovoltaic square matrix backbone net rack (1) comprises grids (11) and wave-proof rings (12); the grid (11) is of a net structure, the grid (11) comprises a plurality of rows of transverse operation and maintenance channels (111) which are arranged in parallel at intervals and a plurality of columns of longitudinal connecting channels (112) which are arranged in parallel at intervals, and the transverse operation and maintenance channels (111) are perpendicular to the longitudinal connecting channels (112);

the wave-resistant ring (12) is positioned at the periphery of the grid (11), and the wave-resistant ring (12) comprises transverse channels (121) positioned at two ends of a longitudinal connecting channel (112) and longitudinal channels (122) positioned at two ends of a transverse operation and maintenance channel (111);

the photovoltaic module support system (2) comprises a plurality of photovoltaic module support units (21), the photovoltaic module support units (21) are embedded into the longitudinal connecting channels (112) in a mode of bridging upwards from the bottoms of the longitudinal connecting channels (112), and the photovoltaic module support units (21) are used for fixing the photovoltaic modules (3) in an inclined mode.

2. The rack-up straddle type water surface photovoltaic support system of claim 1, wherein: each row of the transverse operation and maintenance channel (111) is formed by interconnecting a plurality of walkway floating bodies (41), each row of the longitudinal connecting channel (112) comprises a plurality of connecting floating bodies (42), and the connecting floating bodies (42) are positioned between two walkway floating bodies (41) in two adjacent rows;

the transverse channel (121) is formed by interconnecting a plurality of walkway floating bodies (41), the longitudinal channel (122) comprises a plurality of small walkway floating bodies (43) and a plurality of equipment floating bodies (44), the equipment floating bodies (44) are connected with the transverse operation and maintenance channel (111), and the equipment floating bodies (44) are positioned between the two small walkway floating bodies (43);

the photovoltaic module supporting unit (21) comprises a supporting floating body (22) connected with the longitudinal connecting channel (112) and a connecting piece (23) which is positioned on the supporting floating body (22) and used for fixing the photovoltaic module (3).

3. The rack-up straddle type water surface photovoltaic support system of claim 2, wherein: the walkway floating bodies (41) are of a dumbbell-shaped structure, the middle parts of the walkway floating bodies (41) are narrow areas (411), the two ends of the walkway floating bodies (41) are wide areas (412), walkway floating body ear plates (413) are arranged at four corners of the walkway floating bodies (41), side wall ear plates (414) are arranged on two side walls of the narrow areas (411), and the walkway floating bodies (41) are connected through the walkway floating body ear plates (413);

the connecting floating body (42) is of a rectangular structure, connecting floating body ear plates (421) are arranged at four corners of the connecting floating body (42), two transversely-through grooves (422) are formed in the lower surface of the connecting floating body (42), four supporting floating body mounting planes (423) are arranged at two ends, corresponding to the grooves (422), of the upper surface of the connecting floating body (42), mounting round holes (424) penetrating through the grooves (422) are formed in the supporting floating body mounting planes (423), and the connecting floating body (42) is connected with side wall ear plates (414) of a narrow area (411) of the walkway floating body (41) through the connecting floating body ear plates (421);

the supporting floating body (22) comprises a high-position supporting floating body (221) and a low-position supporting floating body (222), the bottoms of the high-position supporting floating body (221) and the low-position supporting floating body (222) are both cross rods (223), high-position supporting square columns (224) are arranged at two ends of each cross rod (223) of the high-position supporting floating body (221), low-position supporting square columns (225) are arranged at two ends of the low-position supporting floating body (222), connecting cylinders (226) matched with the mounting round holes (424) are arranged on the cross rods (223), and the supporting floating body (22) is upwards bridged at the bottoms of the connecting floating bodies (42) through the connecting cylinders (226) and the mounting round holes (424); the connecting piece (23) is positioned at the top of the high-position supporting square column (224) and the low-position supporting floating body (222).

4. The rack-up straddle type water surface photovoltaic support system of claim 3, wherein: the device floating body (44) is of a rectangular structure, two through holes (441) are formed in the middle of the device floating body (44), device floating body ear plates (442) are arranged at four corners of the device floating body (44), and device mounting holes (443) for fixing electrical devices are formed in the long side of the device floating body (44);

the small walkway floating body (43) is of a rectangular structure, connecting mechanisms (431) are arranged at four corners of the small walkway floating body (43), and the small walkway floating body (43) is connected with a device floating body ear plate (442) of the device floating body (44) and a walkway floating body ear plate (413) of the walkway floating body (41) through the connecting mechanisms (431).

5. The rack-up straddle type water surface photovoltaic support system of claim 4, wherein: mounting columns (227) are arranged at the tops of the high-position supporting floating body (221) and the low-position supporting floating body (222), and mounting column round holes (228) are formed in the center positions of the mounting columns (227);

the connecting piece (23) comprises a support mounting plane (231) and an assembly mounting plane (232), the support mounting plane (231) and the assembly mounting plane (232) are provided with connecting piece mounting round holes (233), an included angle between the support mounting plane (231) and the assembly mounting plane (232) is equal to an installation inclination angle of the photovoltaic assembly (3), the connecting piece mounting round holes (233) of the support mounting plane (231) and the mounting column round holes (228) of the mounting columns (227) are fixed through bolts, and the connecting piece mounting round holes (233) of the assembly mounting plane (232) and the mounting holes of the photovoltaic assembly (3) are fixed through bolts.

6. The rack-up straddle type water surface photovoltaic support system of claim 5, wherein: the bottom surface of the supporting floating body (22) and the bottom surface of the connecting floating body (42) are positioned on the same plane.

7. The rack-up straddle type water surface photovoltaic support system of claim 6, wherein: the longitudinal channels (122) have a plurality of rows.

8. The rack-up straddle type water surface photovoltaic support system of claim 6, wherein: one or more equipment floating bodies (44) are arranged between the two small walkway floating bodies (43).

9. The rack-up straddle type water surface photovoltaic support system of claim 8, wherein: one or more connecting floating bodies (42) are arranged between two adjacent rows of walkway floating bodies (41).

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