A generator set for solar power equipment

By introducing pile foundations, floating components, and drive components into the floating photovoltaic panel system, the automatic adjustment of the photovoltaic panel's tilt angle and stable installation are achieved, solving the problems of poor lighting effect and easy overturning of floating photovoltaic panels, and improving power generation efficiency and safety.

CN121367441BActive Publication Date: 2026-06-30ZHEJIANG UNIVPOWER MACHINERY

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
ZHEJIANG UNIVPOWER MACHINERY
Filing Date
2025-12-03
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Unlike terrestrial solar panels, floating solar panels cannot be installed at large tilt angles and cannot automatically adjust to changes in the direction of sunlight, resulting in poor lighting performance and a high risk of tipping over in strong winds.

Method used

A generator set for solar energy equipment, comprising a pile foundation, a floating section, a drive assembly, and photovoltaic modules, was designed. The floating plate is driven to rotate by blades, and combined with a transmission ring and an adjustment frame, the photovoltaic panels can be stably installed on water and automatically adjust their tilt angle to adapt to changes in sunlight and wind conditions.

Benefits of technology

It improves the light-gathering efficiency and stability of photovoltaic panels, protects them in strong winds, and ensures power generation efficiency and safety.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN121367441B_ABST
    Figure CN121367441B_ABST
Patent Text Reader

Abstract

This invention relates to the field of solar power generation technology, specifically to a generator set for a solar energy device. The generator set includes a pile foundation, with a pipe rotatably connected to the outer side of the top of the pile foundation. A floating part is fixedly connected to the outer side of a transmission ring. The floating part includes two mutually fixed float plates, a first float plate and a second float plate. Multiple drive components are fixed at equal angles on the bottom surface of the second float plate, each drive component including a housing with blades rotatably connected to it. A photovoltaic module is mounted on the top of the second float plate, comprising multiple photovoltaic panels and an adjustment frame. In this invention, by having multiple photovoltaic panels supported on the second float plate at a large tilt angle to receive sunlight, and by having multiple blades at the bottom of the second float plate rotate to drive the float plate carrying the multiple photovoltaic panels around the pile foundation, the photovoltaic panels can automatically adjust their direction of sunlight reception according to changes in the direction of sunlight, thus improving the efficiency of photovoltaic power generation.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This invention relates to the field of solar power generation technology, specifically a generator set for solar energy equipment. Background Technology

[0002] Solar-powered generator sets use solar panels (also called photovoltaic panels) to absorb sunlight and then convert solar radiation into electrical energy through the photoelectric effect. The electrical energy is then transmitted to the power conversion controller, which in turn transmits the electrical energy to energy storage battery packs such as batteries and lithium batteries. Finally, the electrical equipment can be connected to the energy storage battery packs through an inverter to use the power. Depending on the installation location of the photovoltaic panels, solar-powered generator sets can be divided into floating solar-powered generator sets and land-based solar-powered generator sets.

[0003] Floating solar power generators mainly use floating platforms to install photovoltaic panels on the water surface to generate electricity. Currently, the photovoltaic panels on the floating platforms are generally installed at a fixed tilt angle of no more than 20 degrees. This is because strong winds blowing over photovoltaic panels installed at large tilt angles can cause them to tilt, creating upward or downward lift and potentially causing them to overturn. Therefore, most photovoltaic panels cannot be set at a large tilt angle of 30°-45° like ground-based photovoltaic panels to improve the light-gathering effect. Furthermore, most photovoltaic panels in water-based generator sets cannot automatically adjust the direction of sunlight reception to further improve the light-gathering effect as the direction of sunlight changes. Summary of the Invention

[0004] The purpose of this invention is to provide a generator set for solar energy equipment to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, the present invention provides the following technical solution:

[0006] A generator set for solar power equipment includes:

[0007] A pile foundation is fixed to the riverbed, and a pipe is rotatably connected to the pile foundation. A circular plate and a transmission ring are slidably and rotatably connected to the outside of the pipe.

[0008] The floating part is fixedly connected to the transmission ring, and the floating part includes a float plate one and a float plate two that are fixed to each other;

[0009] Multiple drive components are evenly installed on the bottom surface of the second floating plate. Each drive component includes a chassis, and blades are rotatably connected to the chassis.

[0010] A photovoltaic module, comprising multiple photovoltaic panels and an adjustment frame, wherein one end of each photovoltaic panel is rotatably connected to a floating plate, and the adjustment frame comprises two movable beams, each slidably connected to the floating plate, and multiple shafts for adjusting the tilt angle of the photovoltaic panels are rotatably connected between the two movable beams.

[0011] The fixing assembly includes a fixing ring that is movably sleeved on the pipe fitting, and a plurality of cylinders that can fix the floating plate to the pile foundation are fixed on the fixing ring.

[0012] Furthermore, the top surface of the first float plate is provided with a circular cavity capable of accommodating the circular plate, and the second float plate is fixedly connected to the transmission ring.

[0013] Furthermore, the chassis contains a motor that drives the blades to rotate, and the chassis has a protective cover on its outer side.

[0014] Furthermore, the circular plate has multiple locking blocks fixed in the middle, and the inner side of the transmission ring is uniformly connected to multiple transmission blocks, with both the locking blocks and the transmission blocks slidingly engaging with the pipe fitting.

[0015] Furthermore, the inner side of the transmission ring is evenly provided with multiple receiving grooves, and the transmission block is rotatably connected to one end of the receiving groove.

[0016] Furthermore, a circular seat is fixed to the top surface of the pile foundation, and multiple connecting columns, all of which are slidably connected to the circular seat, are fixed on the fixing ring.

[0017] Furthermore, the top surface of the second float plate is evenly provided with multiple positioning holes for the insertion of the fixed post of the air supply cylinder output end, and the bottom surface of the circular seat is fixed with an electromagnet that can attract and fix the pipe fitting.

[0018] Furthermore, a connecting ring that is slidably connected to the connecting column is fixed to the outer side of the circular seat, and an anemometer is fixed to the top of the circular seat.

[0019] Furthermore, one end of the photovoltaic panel is rotatably connected to an adjusting rod that is rotatably connected to a corresponding shaft, and the outer side of one of the shafts is rotatably connected to a driving rod that is connected to the circular plate.

[0020] Furthermore, the circular plate has an eccentrically formed annular groove on its top surface, and one end of the drive rod is rotatably connected to a roller that slides and engages with the annular groove.

[0021] Compared with the prior art, the beneficial effects of the present invention are:

[0022] 1. By rotating float plate one and float plate two around the outside of the pile foundation with the help of a transmission ring, the pile foundation is fixed to the riverbed. Multiple photovoltaic panels are rotatably connected to the top of float plate two, so that multiple photovoltaic panels float and are fixed to the periphery of the pile foundation with the help of float plate one and float plate two. This helps to improve the stability of multiple photovoltaic panels installed on float plate one. An adjusting rod is rotatably connected to one end of the photovoltaic panel, and two moving beams are slidably connected to the top of float plate one. Multiple shafts are rotatably connected to the moving beams, and the shafts are rotatably connected to the adjusting beams. One of the shafts is rotatably connected to a drive rod that is connected to the circular plate. In the initial state, multiple photovoltaic panels are supported on float plate one at a large tilt angle of 30°-45°, which can improve the lighting effect like photovoltaic panels on land.

[0023] When the anemometer detects strong winds, multiple blades arranged on the bottom surface of the second floating plate rotate, driving the second floating plate, the first floating plate, and the photovoltaic modules to rotate counterclockwise around the pipe on the water surface. At this time, the pipe and the circular plate do not rotate. The drive rod, driven by the eccentrically arranged annular groove, pushes the shaft towards the photovoltaic panel. Under the linkage of the drive beam, multiple shafts simultaneously push the adjusting rod towards the photovoltaic panel, thereby reducing the tilt angle of multiple photovoltaic panels at the same time. This effectively prevents the photovoltaic panels from overturning due to strong winds, thus enabling the photovoltaic panels to receive sunlight and generate electricity efficiently at a large tilt angle during normal use, improving power generation efficiency. In strong winds, the tilt angle can be automatically reduced to protect the photovoltaic panels, improving the safety of photovoltaic panel use.

[0024] 2. A transmission ring is installed between the float plate and the pipe fitting. Multiple transmission blocks are rotatably connected to the inner side of the transmission ring and can engage with the sliding groove on the pipe fitting. When the float plate rotates clockwise around the pipe fitting with the transmission ring, the transmission blocks engage with the sliding groove inside the pipe fitting, causing the pipe fitting, the circular plate, the float plate, and the float plate to rotate together. At this time, the annular groove on the circular plate will not drive the adjustment frame on the photovoltaic module to adjust the tilt angle of the photovoltaic panel. When the float plate rotates counterclockwise around the pipe fitting, the transmission blocks rotate and are accommodated in the receiving groove of the transmission ring, no longer rotating synchronously with the float plate with the circular plate and the pipe fitting. At this time, as the float plate rotates counterclockwise with the entire photovoltaic module, the annular groove on the circular plate will drive the adjustment frame to reduce the tilt angle of the photovoltaic panel.

[0025] During normal use of photovoltaic modules, the blades at the bottom of float plate two can rotate to drive float plate one and float plate two, along with the photovoltaic module as a whole, to rotate clockwise. This allows the photovoltaic panel to maintain a large tilt angle and automatically adjust the direction of sunlight reception as the sun's position changes at different times, thereby further improving the light-gathering effect and power generation efficiency. In windy weather, the blades at the bottom of float plate two can first rotate to drive float plate one and float plate two, along with the photovoltaic module as a whole, to rotate counterclockwise to lower the tilt angle. Then, float plate one and float plate two can rotate clockwise to align with the direction of sunlight. This allows the photovoltaic panel with a smaller tilt angle to continue to automatically adjust the direction of sunlight reception as the sun's position changes at different times, thus enabling the photovoltaic panel to automatically adjust the direction of sunlight reception according to changes in the sun's position at both large and small tilt angles. Attached Figure Description

[0026] Figure 1 This is a schematic diagram of the overall structure of the invention. Figure 1 ;

[0027] Figure 2 This is a schematic diagram of the overall structure of the invention. Figure 2 ;

[0028] Figure 3 This is a schematic diagram of the photovoltaic panel tilt angle reduction structure in this invention;

[0029] Figure 4 This is a schematic diagram of the internal structure of float plate one and float plate two in this invention;

[0030] Figure 5 This is a schematic diagram of the overall external structure of the pile foundation in this invention;

[0031] Figure 6 This is a schematic diagram of the three-dimensional structure of the pipe fitting, circular plate, and transmission ring in this invention.

[0032] Figure 7 This is a schematic diagram of the floating part and driving component structure in this invention;

[0033] Figure 8 This is a schematic diagram of the photovoltaic module structure in this invention;

[0034] Figure 9 This is a schematic diagram of the fixed component structure in this invention.

[0035] In the diagram: 100, pile foundation; 110, pipe fitting; 120, circular seat; 121, connecting ring; 122, anemometer; 130, circular plate; 131, annular groove; 140, transmission ring; 141, transmission block; 142, receiving groove; 200, floating part; 210, float plate one; 211, circular cavity; 220, float plate two; 221, positioning hole; 300, drive assembly; 310, chassis; 311, protective cover; 320, blade; 400, photovoltaic module; 410, photovoltaic panel; 411, adjusting rod; 412, fixed seat; 413, rotating seat one; 420, moving beam; 430, shaft; 440, drive rod; 441, roller; 500, fixed assembly; 510, fixed ring; 520, cylinder; 530, connecting column. Detailed Implementation

[0036] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0037] Example 1, please refer to Figure 1 - Figure 9 In this embodiment of the invention, a generator set for a solar energy device includes a pile foundation 100 fixed to the riverbed. A pipe fitting 110 is rotatably connected to the outer side of the top of the pile foundation 100. A circular plate 130 and a transmission ring 140 are slidably and rotatably connected to the outer side of the pipe fitting 110. A floating part 200 is fixedly connected to the outer side of the transmission ring 140. The floating part 200 includes a first float plate 210 and a second float plate 220 fixed to each other. Multiple drive components 300 are fixed at equal angles on the bottom surface of the second float plate 220. Each drive component 300 includes a housing 310. A blade 320 is rotatably connected to the housing 310. The top of the second float plate 220 is provided with... There is a photovoltaic module 400, which includes multiple photovoltaic panels 410 and an adjustment frame. One end of the photovoltaic panel 410 is rotatably connected to the floating plate 210. The adjustment frame includes two movable beams 420 that are slidably connected to the floating plate 210. Multiple shafts 430 that can adjust the tilt angle of multiple photovoltaic panels 410 at corresponding positions are rotatably connected between the two movable beams 420. A fixing component 500 is sleeved on the outside of the pipe fitting 110. The fixing component 500 includes a fixing ring 510 that is movably sleeved with the pipe fitting 110. Multiple cylinders 520 that can fix the floating plate 210 to the pile foundation 100 are evenly fixed on the fixing ring 510.

[0038] Specifically, by fixing a pile foundation 100 in the water, a pipe fitting 110 is rotatably connected to the outside of the pile foundation 100. A first float 210 and a second float 220 are rotatably connected to the outside of the pipe fitting 110 via a transmission ring 140. Multiple photovoltaic panels 410 are installed on the second float 220. Thus, the pile foundation 100 securely installs multiple photovoltaic panels 410 on the water surface by positioning and fixing the floats (including the first float 210 and the second float 220). Initially, the multiple photovoltaic panels 410 can be supported on the second float 220 at a large angle to receive sunlight. When the sun's position changes, the bottom of the second float 220 can... Multiple blades 320 rotate to drive the floating plate, carrying multiple photovoltaic panels 410, to rotate around the pile foundation 100. This allows the photovoltaic panels 410 to automatically adjust the direction of receiving sunlight according to changes in the direction of sunlight, which helps to improve the power generation efficiency of the photovoltaic panels 410. When encountering strong winds, the blades 320 rotate in the opposite direction to drive the floating plate, carrying the photovoltaic panels 410, to rotate in the opposite direction around the pile foundation 100. During the reverse rotation, the adjustment frame on the photovoltaic module 400 lowers the tilt angle of the photovoltaic panels 410, which can effectively prevent the photovoltaic panels 410 from being blown over by the wind and improve the safety of the photovoltaic panels 410 when used on the water.

[0039] like Figure 1 , Figure 3 and Figure 7 As shown, in this embodiment, a motor capable of driving the blades 320 to rotate is fixed inside the housing 310, a protective cover 311 is fixed on the outside of the housing 310, a longitudinal beam is fixedly connected between the housing 310 and the float plate 210, and multiple blades 320 are arranged in a ring at equal angles.

[0040] In this embodiment, when the motor inside the housing 310 drives the blades 320 to rotate, the rotation of multiple blades 320 drains water, enabling float plate 1 210 and float plate 220 to carry the entire photovoltaic module 400 to float on the water surface and rotate clockwise around the pile foundation 100. This allows the photovoltaic panel 410 to automatically adjust its position to receive sunlight after the sun's position changes at different times. When the motor output drives the blades 320 to rotate in the opposite direction, float plate 1 210 and float plate 220 can carry the entire photovoltaic module 400 to float on the water surface and rotate counterclockwise around the pile foundation 100. The motor is a waterproof motor of the prior art. In addition, the mesh protective cover 311 can be fitted over the outside of the blades 320 to prevent debris from hitting and damaging the blades 320.

[0041] like Figure 5 and Figure 6As shown, in this embodiment, the outer side of the pipe fitting 110 is provided with multiple grooves distributed along the axial direction of the pipe fitting 110 at equal angles in an annular shape. The middle part of the circular plate 130 is fixed with multiple locking blocks at equal angles in an annular shape. The inner side of the transmission ring 140 is rotatably connected with multiple transmission blocks 141 at equal angles in an annular shape. Both the locking blocks and the transmission blocks 141 are slidably engaged with the grooves, and both the locking blocks and the transmission blocks 141 can also be engaged with the grooves in a transmission manner. The engagement of the locking blocks with the grooves in a transmission manner facilitates the synchronous rotation of the pipe fitting 110 with the circular plate 130. The engagement of the transmission blocks 141 with the grooves in a transmission manner facilitates the floating plate 220 driving the pipe fitting 110 to rotate through the transmission ring 140.

[0042] In this embodiment, the inner side of the transmission ring 140 is provided with a plurality of receiving grooves 142 at equal angles. One end of the receiving groove 142 is fixed with a connecting shaft. The transmission block 141 is rotatably inserted into the connecting shaft. A torsion spring is sleeved between the connecting shaft and the transmission block 141. In the initial state, the transmission block 141 can rotate out of the receiving groove 142 under the elastic force of the torsion spring. The receiving groove 142 can accommodate the transmission block 141.

[0043] In this embodiment, when the float 220 rotates clockwise with the transmission ring 140, the transmission block 141 on the transmission ring 140 cannot be retracted into the receiving groove 142 and will rotate clockwise with the pipe 110 outside the pile foundation 100. The pipe 110 then rotates clockwise with the circular plate 130, thereby causing the floating part 200, photovoltaic module 400, and circular plate 130 to rotate clockwise around the pile foundation 100 along with the pipe 110. When the float 220 rotates counterclockwise with the transmission ring 140... When the needle rotates, the transmission block 141 on the transmission ring 140 rotates and is stored in the receiving groove 142. At this time, the transmission ring 140 does not drive the pipe 110 to rotate. The pipe 110 is fixed to the outside of the pile foundation 100 by means of the circular seat 120 and the circular plate 130. At this time, the floating part 200 and the photovoltaic module 400 rotate counterclockwise around the pile foundation 100. The stationary circular plate 130 facilitates the adjustment frame on the photovoltaic module 400 to drive the photovoltaic panel 410 to adjust the tilt angle.

[0044] In this embodiment, when the water level rises, float plate 210 and float plate 220 move the photovoltaic module 400 upward as a whole. At this time, the transmission block 141 on the transmission ring 140 and the locking block in the middle of the circular plate 130 can simultaneously move the float plate upward along the sliding groove outside the pipe 110 to the height of the upward movement. Conversely, when the water level falls, float plate 210 and float plate 220 move the photovoltaic module 400 downward as a whole. At this time, the transmission block 141 on the transmission ring 140 and the locking block in the middle of the circular plate 130 can simultaneously move the float plate downward along the sliding groove outside the pipe 110 to the height of the downward movement. This allows the entire floating part 200 to still support the photovoltaic module 400 when the water level changes, and to drive the photovoltaic module 400 to adjust its tilt angle.

[0045] like Figure 4 and Figure 7 As shown, in this embodiment, the top surface of float plate 210 is provided with a circular cavity 211 that can accommodate the circular plate 130. Float plate 220 and transmission ring 140 are embedded and fixed, so that float plate 210 and float plate 220 as a whole can move up and down with transmission ring 140 and circular plate 130. When the circular plate 130 does not rotate synchronously with float plate 210 and float plate 220, the circular plate 130 rotates inside the circular cavity 211 as float plate 210 rotates.

[0046] like Figure 1 and Figure 5 As shown, in this embodiment, a circular seat 120 is fixed on the top surface of the pile foundation 100, and an existing component ring electromagnet is embedded and fixed on the bottom surface of the circular seat 120. When the floating part 200 drives the photovoltaic module 400 to rotate counterclockwise, the electromagnet is energized to attract and fix the top surface of the pipe 110, so that the pipe 110 can be stably fixed on the outside of the pile foundation 100 with the circular plate 130 without rotating.

[0047] like Figure 4 , Figure 5 Figure 8 As shown, in this embodiment, a rotating seat 413 is fixedly connected to one end of the photovoltaic panel 410. An adjusting rod 411, which is rotatably connected to the corresponding shaft 430, is rotatably connected to the rotating seat 413. Two rotating seats 2 are fixed to the other end of the photovoltaic panel 410. A fixed seat 412 is rotatably connected to the rotating seat 2. The fixed seat 412 is fixedly connected to the floating plate 220. A driving rod 440 is rotatably connected to the outer side of one shaft 430. A roller 441 is rotatably connected to one end of the driving rod 440. An annular groove 131 is eccentrically opened on the top surface of the circular plate 130. The roller 441 is in rolling connection with the annular groove 131.

[0048] In this embodiment, the initial state is referenced Figure 2 At this time, multiple photovoltaic panels 410 are arranged on the surface of the floating plate 220 at a large tilt angle. When it is necessary to lower the tilt angle of the photovoltaic panel 410, the driving component 300 drives the floating part 200 to rotate counterclockwise. The floating part 200 carries the entire photovoltaic component 400 to rotate counterclockwise on the circular plate 130. As the roller 441 on the driving rod 440 rotates 180 degrees, that is, after rotating to a position on the annular groove 131 away from the pile foundation 100, the eccentrically arranged annular groove 131 drives the driving rod 440 to move outward, thereby causing the driving rod 440 to move the shaft 430 towards the photovoltaic panel 410. Under the linkage of the two moving beams 420, multiple shafts 430 move towards the photovoltaic panel 410 at the same time, thereby causing the adjusting rod 411 to be tilted, thereby reducing the tilt angle of the photovoltaic panel 410.

[0049] When the effect of a light breeze on the tilt angle of the photovoltaic panel 410 is negligible, the floating part 200 can continue to rotate counterclockwise with the photovoltaic module 400. At this time, the roller 441 of the drive rod 440 on the adjusting frame moves to the position on the initial annular groove 131 close to the pile foundation 100, so that the drive rod 440 moves with multiple shafts 430 in the direction away from the photovoltaic panel 410, thereby increasing the tilt angle of the photovoltaic panel 410.

[0050] like Figure 4 , Figure 5 Figure 9 As shown, in this embodiment, a plurality of connecting posts 530 are fixed on the fixing ring 510, and a connecting ring 121 that is slidably connected to the connecting posts 530 is fixed on the outer side of the circular seat 120. The top surface of the float plate 220 is provided with a plurality of positioning holes 221 for the fixing posts of the air supply cylinder 520 to be inserted into at equal angles.

[0051] In this embodiment, when the entire floating part 200 is rotated and adjusted to a certain position and stops, the output end of the cylinder 520 can be extended to allow the positioning pin to be inserted between the fixing ring 510 and the positioning hole 221, thereby positioning and fixing the float plate 220 on the circular seat 120, and then positioning and fixing the float plate 220 on the pile foundation 100, thus fixing the entire floating part 200 in the water. When the water level changes, the fixing ring 510 moves up and down with the float plate 220, causing the connecting pin 530 to slide up and down on the connecting ring 121, so that the function of the entire fixing assembly 500 in fixing the float plate 220 is not affected by the rise and fall of the water level.

[0052] In this embodiment, an anemometer 122 is fixed on the top of the circular base 120. The anemometer 122 is a prior art component that can detect wind speed and direction. An existing controller can be externally installed on this application. The controller is connected to the anemometer 122 and can also receive weather information from weather forecasts. When the controller detects strong winds, it can drive the drive component 300 to work and complete the tilt angle adjustment of the photovoltaic panel 410.

[0053] In this invention, the photovoltaic panel 410 is connected to the power conversion controller via wires. The conversion controller then transmits the power to the energy storage battery pack, such as the storage battery or lithium battery, via wires. Finally, the electrical equipment can be connected to the energy storage battery pack via an inverter to use the power. This part is related to the existing technology of power storage and use, and the specific working principle will not be described in detail.

[0054] It will be apparent to those skilled in the art that the present invention is not limited to the details of the exemplary embodiments described above, and that the invention can be implemented in other specific forms without departing from its spirit or essential characteristics. Therefore, the embodiments should be considered in all respects as exemplary and non-limiting, and the scope of the invention is defined by the appended claims rather than the foregoing description. Thus, all variations falling within the meaning and scope of equivalents of the claims are intended to be included within the present invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

[0055] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.

Claims

1. A generator set for solar energy equipment, characterized in that, include: A pile foundation (100) is fixed to the riverbed. A pipe fitting (110) is rotatably connected to the pile foundation (100). A circular plate (130) and a transmission ring (140) are slidably and rotatably connected to the outside of the pipe fitting (110). The floating part (200) is fixedly connected to the transmission ring (140). The floating part (200) includes a float plate one (210) and a float plate two (220) fixed to each other. The top surface of the float plate one (210) is provided with a circular cavity (211) that can accommodate a circular plate (130). The float plate two (220) is fixedly connected to the transmission ring (140). Multiple drive components (300) are evenly installed on the bottom surface of the second floating plate (220). Each drive component (300) includes a chassis (310) and a propeller (320) is rotatably connected to the chassis (310). The photovoltaic module (400) includes multiple photovoltaic panels (410) and an adjustment frame. One end of the photovoltaic panel (410) is rotatably connected to a floating plate (210). The adjustment frame includes two movable beams (420) that are slidably connected to the floating plate (210). Multiple shafts (430) for adjusting the tilt angle of the photovoltaic panel (410) are rotatably connected between the two movable beams (420). The fixing assembly (500) includes a fixing ring (510) movably sleeved on the pipe fitting (110), and a plurality of cylinders (520) fixed on the fixing ring (510) for fixing the float (210) to the pile foundation (100). Multiple locking blocks are fixed in the middle of the circular plate (130), and multiple transmission blocks (141) are uniformly connected to the inner side of the transmission ring (140). Both the locking blocks and the transmission blocks (141) are slidably engaged with the pipe fitting (110). Multiple receiving grooves (142) are evenly provided on the inner side of the transmission ring (140), and the transmission block (141) is rotatably connected to one end of the receiving groove (142); One end of the photovoltaic panel (410) is rotatably connected to an adjusting rod (411) that is rotatably connected to a corresponding shaft (430), and the outside of one shaft (430) is rotatably connected to a drive rod (440) that is connected to the circular plate (130). The top surface of the circular plate (130) is eccentrically provided with an annular groove (131), and one end of the drive rod (440) is rotatably connected to a roller (441) that slides and engages with the annular groove (131).

2. The generator set for solar energy equipment according to claim 1, characterized in that, The chassis (310) is equipped with a motor that drives the blades (320) to rotate, and a protective cover (311) is fixed on the outside of the chassis (310).

3. The generator set for solar energy equipment according to claim 1, characterized in that, A circular seat (120) is fixed on the top surface of the pile foundation (100), and a number of connecting columns (530) that are slidably connected to the circular seat (120) are fixed on the fixing ring (510).

4. The generator set for solar energy equipment according to claim 3, characterized in that, The top surface of the float plate (220) is evenly provided with multiple positioning holes (221) for the fixed post of the output end of the air supply cylinder (520) to be inserted, and the bottom surface of the circular seat (120) is fixed with an electromagnet that can attract and fix the pipe fitting (110).

5. The generator set for solar energy equipment according to claim 4, characterized in that, A connecting ring (121) that is slidably connected to the connecting column (530) is fixed on the outside of the circular seat (120), and an anemometer (122) is fixed on the top of the circular seat (120).