CN119766102B

CN119766102B - Solar photovoltaic module and base pouring construction method thereof

Info

Publication number: CN119766102B
Application number: CN202510049496.XA
Authority: CN
Inventors: 孙永树; 马旭; 乔章华; 高胜; 赵辉; 安立军; 吕超; 姚金满; 代兵; 郭海军
Original assignee: Fushun Mining Group Co ltd Power Supply Department; Liaoning Risheng Solar Power Generation Co ltd
Current assignee: Fushun Mining Group Co ltd Power Supply Department; Liaoning Risheng Solar Power Generation Co ltd
Priority date: 2025-01-13
Filing date: 2025-01-13
Publication date: 2025-08-01
Anticipated expiration: 2045-01-13
Also published as: CN119766102A

Abstract

The invention relates to the technical field of solar photovoltaic module construction, in particular to a solar photovoltaic module and a base pouring construction method thereof, which solve the problems that the construction mode of a support of a photovoltaic module is complicated and the time consumption is long when the solar photovoltaic module is constructed, so that the construction efficiency of the photovoltaic module is reduced. The utility model provides a solar photovoltaic module and base station pouring construction method thereof, includes photovoltaic board subassembly, controller, dc-to-ac converter and battery, and photovoltaic board subassembly and controller, dc-to-ac converter and battery are connected through the wire each other, photovoltaic board subassembly includes photovoltaic board protection metal frame. According to the invention, the rubber sleeve is inflated by pouring concrete into the rubber sleeve, and the inflated rubber sleeve extrudes the sliding block through the moving block and the guide push rod, so that the sliding block pushes the reinforced oblique inserting rod to extend out of the guide oblique hole and be obliquely inserted into the soil layer, the stability and the connection strength between the bracket base and the soil layer are improved, and the stability of the solar photovoltaic module base station is ensured.

Description

Solar photovoltaic module and base pouring construction method thereof

Technical Field

The invention relates to the technical field of solar photovoltaic module construction, in particular to a solar photovoltaic module and a base station pouring construction method thereof.

Background

The solar photovoltaic system is a facility for converting solar energy into direct current electric energy by utilizing the photovoltaic effect of a photovoltaic semiconductor material, wherein the semiconductor material used for generating electricity mainly comprises monocrystalline silicon, polycrystalline silicon, amorphous silicon, cadmium telluride and the like, and the main components of the ‌ solar photovoltaic system comprise a solar cell module, a controller, an inverter and a storage battery;

the solar cell module is a core part of the system and is responsible for converting solar energy into electric energy, the controller is used for managing the charging and discharging processes of the storage battery to ensure the stable operation of the system, the inverter is used for converting direct current into alternating current so as to meet the requirements of various loads, and the storage battery is used for storing the electric energy to ensure that the system can still work normally ‌ when no sunlight exists.

However, when the solar photovoltaic module is constructed, the construction mode of the support of the photovoltaic module is complicated and takes long time, so that the construction efficiency of the photovoltaic module is reduced, the existing requirements are not met, and the solar photovoltaic module and the base pouring construction method thereof are provided.

Disclosure of Invention

The invention aims to provide a solar photovoltaic module and a base pouring construction method thereof, which are used for solving the problems that the construction mode of a support of a photovoltaic module is complicated and the time consumption is long when the solar photovoltaic module is constructed in the background technology, so that the construction efficiency of the photovoltaic module is reduced.

In order to achieve the aim, the invention provides the technical scheme that the solar photovoltaic module comprises a photovoltaic panel assembly, a controller, an inverter and a storage battery, wherein the photovoltaic panel assembly is connected with the controller, the inverter and the storage battery through wires, the photovoltaic panel assembly comprises a photovoltaic panel protection metal frame, a solar conversion plate is inlaid at the inner side of the photovoltaic panel protection metal frame, a sunlight receiving plate is fixed on the upper surface of the solar conversion plate, and a layer of transparent protection film is covered on the upper surface of the sunlight receiving plate;

The photovoltaic board protection metal frame comprises a photovoltaic board protection metal frame, and is characterized in that photovoltaic board support frames are all detachably installed at four end angle bottoms of the photovoltaic board protection metal frame, a support base is detachably installed at the bottom end of the photovoltaic board support frames, the photovoltaic board support frames comprise support rods, assembly screw holes are formed in four side faces of the bottom end of each support rod, an adjustable connecting rod is slidably inserted into the top ends of the support rods, limit screws are installed on the front surfaces of the top ends of the support rods through threads, threaded ends of the limit screws penetrate through the support rods and are in contact with the adjustable connecting rods, connecting rods are fixedly connected with rods, the top ends of the connecting rods are spherical, an adjustable locking plate is rotatably installed on the outer sides of the top ends of the connecting rods, through holes are formed in the four end angle positions of each adjustable locking plate, and the adjustable locking plate and the photovoltaic board protection metal frame are connected through screws.

Preferably, the outer surface of bracing piece is fixed with and accomodates the splice plate, splice through accomodating the splice plate between photovoltaic board support frame and the photovoltaic board support frame and accomodate.

Preferably, the storage splice plate comprises a fixed plate, one side of the fixed plate is fixed with the outer side of the supporting rod, a butt joint strip is fixed on the other side of the fixed plate, a T-shaped clamping groove is formed in one side surface of the butt joint strip, and a T-shaped clamping plate is fixed on one side of the side, connected with the butt joint strip, of the fixed plate.

Preferably, the support base comprises a base, a ring plate is fixed on the outer side of the base, a positioning sleeve rod is fixed on the top end of the base, a square groove is formed in the top end of the positioning sleeve rod, and the bottom end of the support rod is inserted into the inner side of the square groove.

Preferably, the outer surface of the top end of the positioning sleeve rod is provided with four positioning holes, fastening screws are inserted into the positioning holes, and the threaded ends of the fastening screws are screwed into the inner sides of the assembly screw holes through threads.

Preferably, the bottom surface of location loop bar is equipped with the pouring hole that runs through, the inside of base is equipped with the rubber sleeve, the inside cavity of rubber sleeve and top are equipped with the round hole, the outside of round hole is fixed with the butt joint sleeve, the butt joint sleeve is pegged graft in the bottom of location loop bar, and the outside of butt joint sleeve is equipped with the hole that runs through, hole and pouring hole position align and the axis coincide each other.

Preferably, the surface of the annular plate is provided with a plurality of groups of guide inclined holes distributed around the circular array of the circle center, each group of guide inclined holes are vertically symmetrical in position, a plurality of sliding blocks are slidably mounted in the annular plate and distributed around the axis of the base in a circular array, the inner side of each guide inclined hole is slidably mounted with a reinforcing inclined inserting rod, and one end of each reinforcing inclined inserting rod is in contact with each sliding block.

Preferably, the outside of rubber sleeve is equipped with a plurality of movable blocks, and the movable block is circular array distribution around the axis of rubber sleeve, and is adjacent two be fixed with the elastic connection strip between the movable block, the surface mounting of movable block has the direction push rod, the direction push rod runs through the base and slides and peg graft inside the annular plate.

Preferably, the reinforcing oblique inserted bar comprises two splicing bars which are symmetrically distributed, one end of each splicing bar is fixedly provided with a contact ball end, the contact ball end is hemispherical and is in contact with the sliding block, the inner side of the other end of each splicing bar is provided with a guide inclined plane, and the guide inclined planes of the end parts form a V-shaped notch when the two symmetrical splicing bars are attached.

A pouring construction method of a base station of a solar photovoltaic module comprises the following steps:

s1, firstly, four symmetrical holes with uniform depth are dug at the installation site of the photovoltaic panel assembly, and the diameters of the holes are consistent with the diameters of the annular plates;

S2, placing the support base into the excavated pit, and butting a pipeline filled with concrete with a pouring hole at the bottom end of the positioning sleeve rod;

S3, pouring concrete into the butt joint sleeve and the rubber sleeve through pouring holes, and expanding the rubber sleeve after the concrete is poured;

s4, the expanded rubber sleeve pushes the moving block and the guide push rod to move, the guide push rod enters the inside of the annular plate and pushes the sliding block to slide, and the sliding block pushes the reinforced oblique inserted rod out of the guide oblique hole and is obliquely inserted into soil;

S5, backfilling the pits by using excavated soil after filling the concrete in the rubber sleeve;

S6, after backfilling the pit, butting the bottom end of the supporting rod with a positioning sleeve rod, and fixing the positioning sleeve rod with the supporting rod by using a fastening screw;

s7, adjusting the height positions of the four adjustable locking plates and the inclination angles of the adjustable locking plates according to the installation angles of the photovoltaic plate assemblies;

s8, after the height and the inclination angle of the adjustable locking plate are adjusted, locking the adjustable connecting rod by using a limit screw;

and S9, finally, installing and fixing the photovoltaic panel assembly and the four adjustable locking plates with the angles adjusted.

Compared with the prior art, the invention has the beneficial effects that:

1. According to the invention, the rubber sleeve is inflated by pouring concrete into the rubber sleeve, and the inflated rubber sleeve extrudes the sliding block through the moving block and the guide push rod, so that the sliding block pushes the reinforced oblique insert rod to extend out of the guide oblique hole and be inserted into the soil layer in an oblique manner, the stability and the connection strength between the bracket base and the soil layer are improved, and the stability of the solar photovoltaic module base station after construction is ensured.

2. According to the invention, the guide inclined planes are formed on the inner sides of the end parts of the two symmetrical splicing rods, and the two guide inclined planes form the V-shaped notch, so that the two splicing rods incline and are away from each other after entering the soil, the reinforced oblique inserting rods are bifurcated in the soil and are unfolded in a V shape, the connection strength between the annular plate and the soil layer is better increased, and the stability of the solar photovoltaic module base station after construction is further ensured.

3. According to the invention, the T-shaped clamping plates at the outer side of one supporting rod are slidably inserted into the T-shaped clamping grooves at the side surface of the butt joint strip at the outer side of the other supporting rod, so that the mutual splicing and assembly of the four photovoltaic panel supporting frames can be realized quickly, the photovoltaic panel supporting frames are not required to be bound by other tools, the photovoltaic panel supporting frames are convenient to store and carry, the four photovoltaic panel supporting frames are spliced into a group, and the photovoltaic panel supporting frame spliced bodies with the corresponding group number are selected according to the number of the photovoltaic panel components during construction, the number of the photovoltaic panel supporting frames is not required to be confirmed independently, and the construction is convenient.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the structure of the photovoltaic panel assembly of the present invention;

FIG. 3 is a schematic view of the structure of the photovoltaic panel support frame of the present invention;

FIG. 4 is a schematic view of the assembly of the adjustable locking plate and connecting club of the present invention;

FIG. 5 is a schematic view of the connection of a storage splice plate to a storage splice plate according to the present invention;

FIG. 6 is an enlarged view of the structure at A in FIG. 3;

FIG. 7 is a schematic view of the structure of the bracket base of the present invention;

FIG. 8 is a schematic view of the internal structure of the base of the present invention;

FIG. 9 is a cross-sectional view of the rubber boot of the present invention;

fig. 10 is a schematic structural view of the reinforcing diagonal member according to the present invention.

In the figure, a photovoltaic panel assembly, a photovoltaic panel protection metal frame, 102, a transparent protection film, 103, a sunlight receiving plate, 104, a solar energy conversion plate, 2, a photovoltaic panel support frame, 201, a support rod, 202, an adjustable connecting rod, 203, a limit screw, 204, an adjustable locking plate, 205, a connecting rod, 206, an assembling screw hole, 3, a support base, 301, a base, 302, a loop plate, 303, a guide inclined hole, 304, a positioning sleeve rod, 305, a positioning hole, 306, a fastening screw, 307, a pouring hole, 308, a reinforcing inclined rod, 3081, a splicing rod, 3082, a guide inclined surface, 3083, a contact ball end, 309, a butting sleeve, 310, a rubber sleeve, 311, a moving block, 312, an elastic connecting strip, 313, a guide push rod, 314, a sliding block, 4, a splicing plate, a fixing plate, 402, a T-shaped clamping plate, 403, a butting strip, 404 and a T-shaped clamping groove are shown.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

As shown in fig. 1 and 2, a solar photovoltaic module comprises a photovoltaic panel assembly 1, a controller, an inverter and a storage battery, wherein the photovoltaic panel assembly 1 is connected with the controller, the inverter and the storage battery through wires, the photovoltaic panel assembly 1 comprises a photovoltaic panel protection metal frame 101, a solar conversion plate 104 is inlaid on the inner side of the photovoltaic panel protection metal frame 101, a sunlight receiving plate 103 is fixed on the upper surface of the solar conversion plate 104, and a layer of transparent protection film 102 is covered on the upper surface of the sunlight receiving plate 103.

As shown in fig. 1, fig. 3 and fig. 4, the photovoltaic panel support frame 2 is detachably installed at the bottoms of four end corners of the photovoltaic panel protection metal frame 101, the bracket base 3 is detachably installed at the bottom end of the photovoltaic panel support frame 2, the photovoltaic panel support frame 2 comprises a support rod 201, the four side faces of the bottom end of the support rod 201 are all provided with assembly screw holes 206, the top end of the support rod 201 is slidably inserted with an adjustable connecting rod 202, the front surface of the top end of the support rod 201 is provided with a limit screw 203 through threads, the threaded end of the limit screw 203 penetrates through the support rod 201 and is in contact with the adjustable connecting rod 202, the top end of the adjustable connecting rod 202 is fixedly provided with a connecting club 205, the top end of the connecting club 205 is a sphere, the outer side of the top end of the connecting club 205 is rotatably provided with an adjustable locking plate 204, the adjustable locking plate 204 is connected with the photovoltaic panel protection metal frame 101 through screws, the height of the adjustable locking plate 204 is pulled according to the installation angle of the photovoltaic panel assembly 1, and the photovoltaic panel assembly 1 can be well converted into solar energy.

As shown in fig. 7 to 10, the bracket base 3 includes a base 301, a ring plate 302 is fixed on the outer side of the base 301, a positioning sleeve rod 304 is fixed on the top end of the base 301, a square groove is formed in the top end of the positioning sleeve rod 304, the bottom end of the supporting rod 201 is inserted into the inner side of the square groove, four positioning holes 305 are formed in the outer surface of the top end of the positioning sleeve rod 304, fastening screws 306 are inserted into the positioning holes 305, the threaded ends of the fastening screws 306 are screwed into the inner sides of the assembly screw holes 206 through threads, the supporting rod 201 and the positioning sleeve rod 304 are connected and fixed through the fastening screws 306, and structural stability of the supporting rod 201 is guaranteed and the photovoltaic panel assembly 1 is supported.

The bottom surface of location loop bar 304 is equipped with the pouring hole 307 that runs through, the inside of base 301 is equipped with rubber sleeve 310, the inside cavity of rubber sleeve 310 and top are equipped with the round hole, the outside of round hole is fixed with butt joint sleeve 309, butt joint sleeve 309 peg graft in the bottom of location loop bar 304, and the outside of butt joint sleeve 309 is equipped with the hole that runs through, the hole aligns and the mutual coincidence of axis with pouring hole 307, utilize pouring hole 307 and hole to pour into rubber sleeve 310 with the concrete for rubber sleeve 310 inflation and to the inside packing of base 301, increase the weight of base 301, guarantee the resistance ability to external wind-force after photovoltaic board assembly 1 installs.

The outer surface of the annular plate 302 is provided with a plurality of groups of guide inclined holes 303 distributed around the circular array of the circle center of the annular plate, each group of guide inclined holes 303 are vertically symmetrical in position, a plurality of sliding blocks 314 are slidably arranged in the annular plate 302, the sliding blocks 314 are circularly distributed around the axis of the base 301, the reinforcing inclined inserting rods 308 are slidably arranged in the inner sides of the guide inclined holes 303, one ends of the reinforcing inclined inserting rods 308 are in contact with the sliding blocks 314, a plurality of moving blocks 311 are arranged on the outer sides of the rubber sleeve 310, the moving blocks 311 are circularly distributed around the axis of the rubber sleeve 310, elastic connecting strips 312 are fixed between two adjacent moving blocks 311, guide push rods 313 are fixedly arranged on the outer surfaces of the moving blocks 311, the guide push rods 313 penetrate through the base 301 and are slidably inserted into the annular plate 302, after the rubber sleeve 310 is filled with concrete and expanded, the moving blocks 311 are pushed by the expanded rubber sleeve 310, at the moment, the moving blocks 311 push the guide push rods 313 into the annular plate 302, the sliding blocks 314 are pushed by the reinforcing inclined inserting rods 308 to be extruded, the reinforcing inclined inserting rods 308 are enabled to be inserted into soil in the inclined inserting rods, the soil is enabled to be inserted into the annular plate 302, the integral and the strength of the integral soil is guaranteed, and the whole soil is firmly filled with the soil layer is guaranteed, and the whole soil is firmly fixed.

The reinforced oblique inserting rod 308 comprises two symmetrically distributed splicing rods 3081, one end of each splicing rod 3081 is fixedly provided with a contact ball end 3083, the contact ball end 3083 is hemispherical and is in contact with a sliding block 314, the inner side of the other end of each splicing rod 3081 is provided with a guide inclined surface 3082, the guide inclined surfaces 3082 of the end parts form V-shaped notches when the two symmetrical splicing rods 3081 are attached, the end parts of the two splicing rods 3081 are V-shaped notches formed by the guide inclined surfaces 3082, when the two splicing rods 3081 extend out of the guide oblique holes 303 and are in contact with soil, the end parts of the two splicing rods 3081 are mutually separated due to the contact of the guide inclined surfaces 3082 and the soil, so that the reinforced oblique inserting rod 308 is in V-shaped and unfolded in the soil, and the structural stability of the base 301 and the annular plate 302 after construction is further increased.

As shown in fig. 5 and 6, the outer surface of the supporting rod 201 is fixed with a storage splice plate 4, the photovoltaic panel supporting frames 2 and the photovoltaic panel supporting frames 2 are spliced and stored through the storage splice plate 4, the storage splice plate 4 comprises a fixed plate 401, one side of the fixed plate 401 is fixed with the outer side of the supporting rod 201, a butt joint strip 403 is fixed on the other side of the fixed plate 401, a T-shaped clamping groove 404 is formed in one side surface of the butt joint strip 403, the T-shaped clamping plate 402 on the outer side of the supporting rod 201 is slidingly spliced in the T-shaped clamping groove 404 on the side surface of the butt joint strip 403 on the outer side of the other supporting rod 201, the four photovoltaic panel supporting frames 2 can be quickly spliced and assembled, other tools are not required to be used for binding the photovoltaic panel supporting frames 2, the photovoltaic panel supporting frames 2 are conveniently stored and carried, the four photovoltaic panel supporting frames 2 are spliced into a group of spliced bodies through the storage splice plate 4, the photovoltaic panel supporting frames 2 spliced bodies are only required to be selected according to the number of the photovoltaic panel components 1 during construction, the number of the photovoltaic panel supporting frames 2 spliced bodies are not required to be independently confirmed, and construction is convenient.

Firstly, four symmetrical holes with uniform depth and diameter are dug at the installation position of the photovoltaic panel assembly 1, a base 301 and a ring plate 302 are placed in the holes, the upper surface of the base 301 is flush with the ground, the outer surface of the ring plate 302 is in contact with the inner wall of the holes, at this time, a concrete pouring pipeline is in butt joint with a pouring hole 307, and concrete is poured into the pouring hole 307 through the concrete pouring pipeline after the butt joint;

When concrete is poured, the concrete enters the inside of the butt joint sleeve 309 through a hole at the outer side of the butt joint sleeve 309 and enters the inside of the rubber sleeve 310 through a round hole at the top end of the rubber sleeve 310, the rubber sleeve 310 gradually expands along with the pouring of the concrete in the inside, the expanded rubber sleeve 310 extrudes the moving block 311 towards the inside of the base 301, meanwhile, the elastic connecting strip 312 is elastically stretched, meanwhile, the moving block 311 pushes the guide push rod 313 into the inside of the annular plate 302, the end part of the guide push rod 313 entering the inside of the annular plate 302 extrudes the sliding block 314, at the moment, the sliding block 314 is pushed by the guide push rod 313 and slides in the inside of the annular plate 302, the sliding block 314 in the sliding pushes the reinforcing inclined insert rod 308, and the reinforcing inclined insert rod 308 extends out of the guide inclined hole 303;

The reinforcing oblique inserted rod 308 contacts with the inner wall of the pit and is inserted into the soil layer of the pit after extending out of the guide oblique hole 303, when the reinforcing oblique inserted rod 308 is inserted into the soil layer, soil can enter a V-shaped notch formed by the guide oblique faces 3082 on the inner sides of the end parts of the two mutually-attached splicing rods 3081, and as the soil continuously enters, the gap between the end parts of the two splicing rods 3081 can gradually increase, so that the two splicing rods 3081 move obliquely sideways, and after the reinforcing oblique inserted rod 308 extends out of the guide oblique hole 303 and enters the soil layer, the reinforcing oblique inserted rod 308 is forked into the soil layer to be unfolded in a V shape, and the connecting strength between the ring plate 302 and the inner wall of the pit is increased by utilizing the forked reinforcing oblique inserted rod 308 which is inserted into the soil layer;

After the concrete in the rubber sleeve 310 is poured, the bottom end of the supporting rod 201 is in butt joint with the positioning sleeve rod 304 and is fixedly connected through the fastening screw 306, at this time, the heights and the inclination angles of the four adjustable locking plates 204 are adjusted according to the installation angle of the photovoltaic panel assembly 1, only the adjustable connecting rod 202 is pulled to slide out of the top of the supporting rod 201 or to recover and push the adjustable locking plates 204 to rotate at the outer side of the connecting rod 205 during adjustment, the adjustable connecting rod 202 is extruded and locked through the limit screw 203 after the height adjustment of the adjustable locking plates 204 is finished, the fact that the adjustable connecting rod 202 cannot slide along the axial direction is ensured, and finally the photovoltaic panel assembly 1 is locked with the adjustable locking plates 204 through the screw, so that the construction mode of the solar photovoltaic module is simplified, the construction implementation is shortened, and the construction efficiency of the solar photovoltaic module is effectively improved.

s1, firstly, four symmetrical holes with uniform depth are dug at the installation site of the photovoltaic panel assembly 1, and the diameters of the holes are consistent with the diameters of the annular plates 302;

S2, placing the support base 3 into the excavated pit, and butting a pipeline filled with concrete with a pouring hole 307 at the bottom end of the positioning sleeve rod 304;

S3, pouring concrete into the butt joint sleeve 309 and the rubber sleeve 310 through the pouring holes 307, and expanding the rubber sleeve 310 after the concrete is poured;

S4, the expanded rubber sleeve 310 pushes the moving block 311 and the guide push rod 313 to move, the guide push rod 313 enters the inside of the annular plate 302 and pushes the sliding block 314 to slide, and the sliding block 314 pushes the reinforcing inclined inserting rod 308 out of the guide inclined hole 303 and is obliquely inserted into soil;

S5, backfilling the pits by using excavated soil after filling the concrete in the rubber sleeve 310;

s6, after backfilling the pit, butting the bottom end of the supporting rod 201 with a positioning sleeve rod 304, and fixing the positioning sleeve rod 304 with the supporting rod 201 by using a fastening screw 306;

s7, adjusting the height positions and the inclination angles of the four adjustable locking plates 204 according to the installation angle of the photovoltaic panel assembly 1;

S8, after the height and the inclination angle of the adjustable locking plate 204 are adjusted, locking the adjustable connecting rod 202 by using the limit screw 203;

and S9, finally, the photovoltaic panel assembly 1 and the four adjustable locking plates 204 with the angles adjusted are installed and fixed.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. A solar photovoltaic module, comprising a photovoltaic panel assembly (1), a controller, an inverter and a battery, wherein the photovoltaic panel assembly (1) is connected to the controller, the inverter and the battery via wires, and is characterized in that: the photovoltaic panel assembly (1) comprises a photovoltaic panel protection metal frame (101), a solar energy conversion panel (104) is embedded on the inner side of the photovoltaic panel protection metal frame (101), a sunlight receiving panel (103) is fixed on the upper surface of the solar energy conversion panel (104), and the upper surface of the sunlight receiving panel (103) is covered with a layer of transparent protective film (102);

The photovoltaic panel protection metal frame (101) is detachably mounted with a photovoltaic panel support frame (2) at the bottom of the four end corners, and a bracket base (3) is detachably mounted at the bottom end of the photovoltaic panel support frame (2). The photovoltaic panel support frame (2) includes a support rod (201), and the four side surfaces of the bottom end of the support rod (201) are provided with assembly screw holes (206). The top end of the support rod (201) is slidably plugged with an adjustable connecting rod (202). The front surface of the top end of the support rod (201) is threadedly mounted with a limit screw (206). 03), the threaded end of the limit screw (203) passes through the support rod (201) and contacts the adjustable connecting rod (202), the top of the adjustable connecting rod (202) is fixed with a connecting ball rod (205), the top of the connecting ball rod (205) is a sphere, and an adjustable locking plate (204) is rotatably installed on the outer side of the top of the connecting ball rod (205), the four end corners of the adjustable locking plate (204) are provided with through holes, and the adjustable locking plate (204) is connected to the photovoltaic panel protection metal frame (101) by screws;

The bracket base (3) comprises a base (301), a ring plate (302) is fixed on the outer side of the base (301), a positioning sleeve rod (304) is fixed on the top of the base (301), a square groove is provided on the top of the positioning sleeve rod (304), and the bottom end of the support rod (201) is inserted into the inner side of the square groove;

The outer surface of the bottom end of the positioning sleeve (304) is provided with a through casting hole (307), the interior of the base (301) is provided with a rubber sleeve (310), the interior of the rubber sleeve (310) is hollow and the top end is provided with a circular hole, the outside of the circular hole is fixed with a docking sleeve (309), the docking sleeve (309) is plugged into the bottom end of the positioning sleeve (304), and the outside of the docking sleeve (309) is provided with a through hole, the hole and the casting hole (307) are aligned and the axes coincide with each other;

The outer surface of the ring plate (302) is provided with a plurality of groups of guide oblique holes (303) distributed in a circular array around the center of the ring plate (302), each group of guide oblique holes (303) has two guide oblique holes (303) and the positions are symmetrical up and down, a plurality of sliding blocks (314) are slidably installed inside the ring plate (302), and the sliding blocks (314) are distributed in a circular array around the axis of the base (301), and a reinforcing oblique insertion rod (308) is slidably installed inside the guide oblique hole (303), and one end of the reinforcing oblique insertion rod (308) is in contact with the sliding block (314);

A plurality of moving blocks (311) are provided on the outside of the rubber sleeve (310), and the moving blocks (311) are distributed in a circular array around the axis of the rubber sleeve (310). An elastic connecting strip (312) is fixed between two adjacent moving blocks (311). A guide push rod (313) is fixed on the outer surface of the moving block (311), and the guide push rod (313) passes through the base (301) and is slidably inserted into the inside of the ring plate (302);

The reinforced oblique insertion rod (308) comprises two symmetrically distributed splicing rods (3081), one end of the splicing rod (3081) is fixed with a contact ball end (3083), the contact ball end (3083) is hemispherical and contacts the sliding block (314), and the other end of the splicing rod (3081) is provided with a guide inclined surface (3082) on the inner side. When the two symmetrical splicing rods (3081) are fitted together, the guide inclined surfaces (3082) at the ends form a V-shaped notch.

2. A solar photovoltaic module according to claim 1, characterized in that: a receiving splicing plate (4) is fixed to the outer surface of the support rod (201), and the photovoltaic panel support frames (2) are spliced and received by the receiving splicing plate (4).

3. A solar photovoltaic module according to claim 2, characterized in that: the storage splicing plate (4) includes a fixing plate (401), one side of the fixing plate (401) is fixed to the outside of the support rod (201), and the other side of the fixing plate (401) is fixed with a docking strip (403), one side surface of the docking strip (403) is provided with a T-shaped card groove (404), and the side of the fixing plate (401) connected to the docking strip (403) is fixed with a T-shaped card plate (402).

4. A solar photovoltaic module according to claim 3, characterized in that: the outer surface of the top end of the positioning sleeve (304) is provided with four positioning holes (305), and fastening screws (306) are inserted into the positioning holes (305), and the threaded ends of the fastening screws (306) are screwed into the inner side of the assembly screw hole (206) through threads.

5. A base casting construction method for a solar photovoltaic module according to claim 4, characterized in that the base casting construction method comprises the following steps:

S1: First, four symmetrically positioned and uniformly deep pits are dug at the photovoltaic panel assembly (1) installation site, wherein the diameter of the pits is consistent with the diameter of the ring plate (302);

S2: Place the support base (3) into the excavated pit, and connect the concrete pouring pipe to the pouring hole (307) at the bottom end of the positioning sleeve (304);

S3: pouring concrete into the docking sleeve (309) and the rubber sleeve (310) through the pouring hole (307), and the rubber sleeve (310) expands after the concrete is poured;

S4: The expanded rubber sleeve (310) pushes the moving block (311) and the guide push rod (313) to move, the guide push rod (313) enters the interior of the ring plate (302) and pushes the sliding block (314) to slide, and the sliding block (314) pushes the reinforcement oblique insertion rod (308) out of the guide oblique hole (303) and inserts it obliquely into the soil;

S5: After the concrete filling inside the rubber sleeve (310) is completed, the hole is backfilled with the excavated soil;

S6: After the pit is backfilled, the bottom end of the support rod (201) is docked with the positioning sleeve rod (304), and the positioning sleeve rod (304) and the support rod (201) are fixed using a fastening screw (306);

S7: adjusting the height positions of the four adjustable locking plates (204) and the tilt angles of the adjustable locking plates (204) according to the installation angle of the photovoltaic panel assembly (1);

S8: After the height and tilt angle of the adjustable locking plate (204) are adjusted, the adjustable connecting rod (202) is locked using the limit screw (203);

S9: Finally, the photovoltaic panel assembly (1) and the adjustable locking plate (204) with the four angles adjusted are installed and fixed.