CN113066898A

CN113066898A - Photovoltaic module capable of improving lamination efficiency

Info

Publication number: CN113066898A
Application number: CN202110302420.5A
Authority: CN
Inventors: 郑利敏
Original assignee: Hangzhou Polytechnic
Current assignee: Hangzhou Qinglanggan Management Consulting Co.,Ltd.
Priority date: 2021-03-22
Filing date: 2021-03-22
Publication date: 2021-07-02
Anticipated expiration: 2041-03-22
Also published as: CN113066898B

Abstract

The invention relates to the technical field of photovoltaic modules, in particular to a photovoltaic module for improving lamination efficiency, which comprises a base, a sliding module, a lifting module, a mounting plate and a photovoltaic plate, wherein the photovoltaic plate of the photovoltaic module can be adjusted in angle, so that the photovoltaic module can adjust the photovoltaic plate according to the solar energy recommended mounting angle of the world weather service bureau, the flexibility of the photovoltaic module in use is improved, the generated energy of the photovoltaic module is as large as possible by adjusting the angle of the photovoltaic plate, the generated energy of the photovoltaic module is improved, the economic benefit of the photovoltaic module in use is further improved, the photovoltaic plate of the photovoltaic module is more stably adjusted and fixed by fixing the photovoltaic plate through bolts, and the reliability of the photovoltaic module in use is further improved.

Description

Photovoltaic module capable of improving lamination efficiency

Technical Field

The invention relates to the technical field of photovoltaic modules, in particular to a photovoltaic module capable of improving lamination efficiency.

Background

Along with the deep popularization and use of clean energy in various fields of social economy, solar energy which utilizes solar radiation to generate energy is increasingly used, the utilization of the solar energy needs to use a photovoltaic module which is based on battery integration, has encapsulation and internal connection, can independently provide direct current output and is the smallest indivisible photovoltaic battery combination device, the photovoltaic module is a core part in a solar power generation system and is also the most important part in the solar power generation system, and the photovoltaic module consists of a high-efficiency crystalline silicon solar cell piece, ultra-white cloth grain toughened glass, EVA (ethylene vinyl acetate), a transparent TPT (thermoplastic vulcanizate) back plate and an aluminum alloy frame, and has the characteristics of long service life, strong mechanical pressure resistance and external force and the like.

However, the existing photovoltaic module has a great problem in the using process, the existing photovoltaic module is in the lamination processing process, because the photovoltaic module cannot move, the precision of lamination processing is not high, and further the lamination efficiency of the photovoltaic module is reduced, the existing photovoltaic module cannot flexibly adjust a photovoltaic panel, the flexibility of use is reduced, meanwhile, the adjustment of the photovoltaic module on the direct sunlight angle is not facilitated, the generated energy is reduced, the size of the working area of the photovoltaic panel cannot be freely adjusted by the existing photovoltaic module, and further the generated energy cannot be flexibly adjusted, meanwhile, the installation and the use of the photovoltaic module in different occasions are also not facilitated, and the use range of the photovoltaic module is reduced.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a photovoltaic module for improving the lamination efficiency.

The technical scheme adopted by the invention for solving the technical problems is as follows: a photovoltaic assembly for improving lamination efficiency comprises a base, a sliding assembly, a lifting assembly, a mounting plate and a photovoltaic plate, wherein the sliding assembly is matched on the base in a sliding mode, the lifting assembly is welded at the top of the sliding assembly, the mounting plate is welded at one side of the top of the lifting assembly, a main photovoltaic frame and an auxiliary photovoltaic frame are mounted at one side, away from the lifting assembly, of the mounting plate, the photovoltaic plate is arranged in each of the main photovoltaic frame and the auxiliary photovoltaic frame, and the photovoltaic plate is mounted in each of the auxiliary photovoltaic frames through the arrangement of the auxiliary photovoltaic frames, so that the area of the photovoltaic plate of the photovoltaic assembly is larger;

the base comprises a bottom frame, a first lead screw and a first motor, the first lead screw is rotatably matched in the bottom frame, the first motor is installed at one end of the bottom frame and connected with the first lead screw through a rotating shaft, slide rails are welded on two sides of the bottom frame, and the cross sections of the two slide rails are in an I-shaped structure;

the sliding assembly comprises a connecting plate, sliding plates and sliding blocks, the connecting plate is horizontally arranged, a nut is welded at the center of the top of the connecting plate, a first lead screw is in threaded fit with the nut, the sliding plates are vertically welded at two ends of the top of the connecting plate, the connecting plate and the two sliding plates are integrally of a U-shaped structure, the sliding blocks are welded at one sides of the two sliding plates close to the nut, first sliding grooves are formed in one sides of the two sliding blocks close to the nut, the cross sections of the first sliding grooves are matched with the cross sections of the sliding rails in size, the sliding blocks are in sliding fit on the sliding rails through the first sliding grooves, the sliding rails are arranged, the sliding blocks are in sliding fit on the sliding rails, the connecting plate is more stable in movement, the first lead screw is driven to rotate by a first motor, the first lead screw rotates to drive the nut to move on, the connecting plate can move back and forth, so that the photovoltaic plate of the photovoltaic module can move back and forth, and the position of the photovoltaic plate is adjusted by moving the photovoltaic plate back and forth, so that the photovoltaic module can automatically correct the position in the lamination processing process;

the lifting assembly comprises supporting plates, a first fixing plate and a third fixing plate, the two supporting plates are vertically welded at the top of a connecting plate, the first fixing plate is sleeved on the two supporting plates, the first fixing plate is welded and fixed with the two supporting plates, a second fixing plate is welded at the top of the two supporting plates, first sliding rods penetrate through two ends of the top of the second fixing plate, the two first sliding rods are in sliding fit with the second fixing plate, the third fixing plate is more stable in movement by arranging the first sliding rods and enabling the first sliding rods to be in sliding fit with the second fixing plate, a third fixing plate is welded at the top of the two first sliding rods, a second motor is mounted at the top of the third fixing plate, a second lead screw is in rotating fit with the third fixing plate, the top of the second lead screw is connected with the second motor through a rotating shaft, and the second lead screw penetrates through the second fixing plate, the second screw rod is in threaded fit connection with the second fixing plate, the second screw rod is driven by a second motor to rotate, the third fixing plate is enabled to move up and down through the first sliding rod by rotating the second screw rod, the photovoltaic plate of the photovoltaic assembly can further move up and down, and the height of the movable photovoltaic plate is adjusted by moving up and down, so that the photovoltaic plate of the photovoltaic assembly can better support each lamination;

the mounting plate is vertically arranged, the mounting plate is welded at one side of the third fixing plate, a knob is rotatably matched at one side of the mounting plate close to the third fixing plate, one end of the knob penetrates through the mounting plate, one end of the knob penetrating through the mounting plate is welded with one end of the main photovoltaic frame, the knob drives the main photovoltaic frame to rotate by rotating the knob, the angle of the photovoltaic panel is adjusted, a slideway is arranged on the mounting plate and is arranged in an arc shape, a bolt is matched and arranged in the slideway in a sliding way, the bolt is connected with the main photovoltaic frame in a threaded matching way, the bolt is screwed on the main photovoltaic frame and the mounting plate by rotating the bolt, fixing the photovoltaic plate, wherein two pushing assemblies are welded at the bottom end of the main photovoltaic frame, an auxiliary photovoltaic frame is welded at one side of the two pushing assemblies, and the auxiliary photovoltaic frame is movably matched below the main photovoltaic frame through the pushing assemblies;

the photovoltaic panel comprises a bottom plate, a battery piece and a glass piece, wherein the bottom plate is welded at the bottom end of a main photovoltaic frame and an auxiliary photovoltaic frame respectively, a back plate is fixed on the bottom plate, a plurality of glue dots are arranged between the bottom plate and the back plate, the bottom plate and the back plate are bonded through the glue dots, a first packaging glue film is arranged at the top of the back plate, the battery piece is arranged at the top of the first packaging glue film, a second packaging glue film is arranged at the top of the battery piece, the glass piece is arranged at the top of the second packaging glue film, the bottom plate is welded at the bottom of the main photovoltaic frame and the auxiliary photovoltaic frame, the back plate is fixed through the bottom plate, and therefore the photovoltaic panel of the photovoltaic module can be assembled more conveniently.

Preferably, the cross section of the bottom frame is of a square structure, and four corners of the top of the bottom frame are provided with screw holes.

Preferably, first motor, first lead screw and slide rail all are the level setting, and just first lead screw is located the centre of two slide rails.

Preferably, two slides are located the both sides of underframe respectively, and the slide passes through slider sliding fit on the slide rail, and the connecting plate passes through two slide sliding fit in the below of underframe.

Preferably, first fixed plate, second fixed plate and third fixed plate all are the level setting, and first fixed plate, second fixed plate and third fixed plate are parallel to each other between two liang.

Preferably, a second sliding groove is formed in one side of the supporting plate, the section of the second sliding groove is of a semicircular structure, and the lower half part of the first sliding rod is in sliding fit in the second sliding groove.

Preferably, the top of the first fixing plate is provided with a through hole, and the diameter of the cross section of the through hole is larger than that of the cross section of the second screw rod.

Preferably, the pushing assembly comprises a fixing frame, a push plate and a third lead screw, the fixing frame is welded at the bottom end of the main photovoltaic frame, the cross section of the fixing frame is of an L-shaped structure, the third lead screw penetrates through the fixing frame, the thread of the third lead screw is in matched connection with the thread of the fixing frame, a rotating handle is fixedly welded at one end of the third lead screw, second slide bars penetrate through two ends of the fixing frame, the push plate is fixedly welded at one ends of the two second slide bars, one side of the push plate, far away from the second slide bars, is welded with one side of the auxiliary photovoltaic frame, one end of the third lead screw, far away from the rotating handle, is in rotating fit with the push plate, the third lead screw is rotated by rotating the rotating handle, the third lead screw moves forwards by rotating on the fixing frame, the push plate is moved forwards by the third lead screw, the auxiliary photovoltaic frame is pushed by the push plate, the auxiliary photovoltaic, the working area of the photovoltaic plate of the photovoltaic module can be freely adjusted, and therefore the generated energy of the photovoltaic module can be accurately controlled.

Preferably, change the handle by changeing the piece and the rotary drum is constituteed, change the piece welding in the one end of third lead screw, rotary drum normal running fit is in the one side of changeing the piece, and the rotary drum is "L" type structure with changeing the piece wholly, and through setting up the rotary drum, it is more convenient to make the rotation of changeing the handle.

Preferably, the method for using the photovoltaic module for improving the lamination efficiency specifically comprises the following steps:

the method comprises the following steps: the first screw rod is driven by the first motor to rotate, the first screw rod drives the nut to move on the first screw rod, the nut drives the connecting plate to move the connecting plate back and forth, so that the photovoltaic panel of the photovoltaic assembly can move back and forth, the second screw rod is driven by the second motor to rotate, and the third fixing plate moves up and down through the first sliding rod by rotating the second screw rod, so that the photovoltaic panel of the photovoltaic assembly can move up and down;

step two: the knob drives the main photovoltaic frame to rotate by rotating the knob, the angle of the photovoltaic panel is adjusted, and the bolt is screwed on the main photovoltaic frame and the mounting plate by rotating the bolt to fix the photovoltaic panel;

step three: the third screw rod is rotated by rotating the rotating handle, moves forwards by rotating the third screw rod on the fixing frame, and moves forwards to push the push plate, so that the push plate pushes the auxiliary photovoltaic frame and pushes the auxiliary photovoltaic frame out, and the photovoltaic panel on the auxiliary photovoltaic frame is displayed.

The invention has the beneficial effects that:

(1) the photovoltaic module for improving the lamination efficiency can automatically correct the position of the photovoltaic module in the lamination processing process by moving the photovoltaic panel back and forth and adjusting the position of the photovoltaic panel, so that the lamination processing accuracy of the photovoltaic module is higher, the lamination efficiency of the photovoltaic module is improved, the photovoltaic panel of the photovoltaic module can better support each lamination by adjusting the height of the movable photovoltaic panel up and down, the lamination efficiency of the photovoltaic module is further improved, the photovoltaic panel can better follow a mechanical arm for lamination processing by moving the photovoltaic panel back and forth and matching with the movable photovoltaic panel up and down, the reciprocating material taking process of the mechanical arm is reduced, the lamination efficiency of the photovoltaic module is improved, the sliding rail is arranged, the sliding block is matched on the sliding rail in a sliding manner, so that the connecting plate can move more stably, and then make the photovoltaic board back-and-forth movement more stable to further improve the accurate nature of this photovoltaic module stromatolite processing, further improve the efficiency of this photovoltaic module stromatolite, through setting up first slide bar, and with first slide bar sliding fit on the second fixed plate, make the third fixed plate remove more steady, and then make this photovoltaic board adjust more steady smooth from top to bottom, further improve the efficiency of this photovoltaic module stromatolite.

(2) According to the photovoltaic module for improving the lamination efficiency, the angle of the photovoltaic panel of the photovoltaic module can be adjusted, so that the photovoltaic module can adjust the photovoltaic panel according to the solar energy recommended installation angle of the world weather bureau, the flexibility of the photovoltaic module in use is improved, the generated energy of the photovoltaic module is as large as possible by adjusting the angle of the photovoltaic panel, the generated energy of the photovoltaic module is improved, the economic benefit of the photovoltaic module in use is further improved, the photovoltaic panel is fixed by using the bolts, the photovoltaic panel of the photovoltaic module is adjusted and fixed more stably, and the reliability of the photovoltaic module in use is further improved.

(3) The photovoltaic module for improving the lamination efficiency has the advantages that the area of the photovoltaic panel of the photovoltaic module is larger by arranging the auxiliary photovoltaic frame and installing the photovoltaic panel in the auxiliary photovoltaic frame, so that the generating capacity of the photovoltaic module is improved, the working area of the photovoltaic panel of the photovoltaic module can be freely adjusted by adjusting the auxiliary photovoltaic frame, so that the generating capacity of the photovoltaic module can be accurately controlled, the photovoltaic module can generate electricity according to the actual electricity demand, meanwhile, the photovoltaic module can be installed and used in more different occasions by flexibly adjusting the area of the photovoltaic panel, the using range of the photovoltaic module is improved, the base plates are welded at the bottoms of the main photovoltaic frame and the auxiliary photovoltaic frame, and the back plates are fixed through the base plates, so that the photovoltaic panel of the photovoltaic module can be more conveniently assembled, further improving the lamination efficiency of the photovoltaic component.

Drawings

The invention is further illustrated with reference to the following figures and examples.

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

FIG. 2 is a schematic view of a base structure according to the present invention.

FIG. 3 is a schematic view of the sliding assembly of the present invention.

Fig. 4 is a schematic structural view of the lifting assembly of the present invention.

Fig. 5 is a cross-sectional view of the support plate of the present invention.

Fig. 6 is a schematic view of the assembly structure of the sliding assembly and the lifting assembly of the present invention.

FIG. 7 is a schematic view of the structure of the mounting plate of the present invention.

Fig. 8 is a schematic structural diagram of a pushing assembly according to the present invention.

Fig. 9 is a schematic view of the structure of the rotating handle of the present invention.

Fig. 10 is a schematic structural view of a main photovoltaic frame according to the present invention.

Fig. 11 is a schematic structural view of a sub-photovoltaic frame according to the present invention.

Fig. 12 is a cross-sectional view of a photovoltaic panel of the present invention.

In the figure: 1. a base; 101. a bottom frame; 102. a slide rail; 103. a first lead screw; 104. a first motor; 105. a screw hole; 2. a sliding assembly; 201. a connecting plate; 202. a nut; 203. a slide plate; 204. a slider; 205. a first chute; 3. a lifting assembly; 301. a support plate; 302. a second chute; 303. a first fixing plate; 304. a second fixing plate; 305. a first slide bar; 306. a third fixing plate; 307. a second lead screw; 308. a second motor; 4. mounting a plate; 401. a slideway; 5. a knob; 6. a bolt; 7. a push assembly; 701. a fixed mount; 702. pushing the plate; 703. a third screw rod; 704. a second slide bar; 705. turning a handle; 706. rotating the block; 707. a rotating drum; 8. a main photovoltaic frame; 9. a sub-photovoltaic frame; 10. a photovoltaic panel; 11. a base plate; 12. a back plate; 13. a first packaging adhesive film; 14. a battery piece; 15. a second packaging adhesive film; 16. a glass sheet.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

As shown in fig. 1-12, the photovoltaic module for improving lamination efficiency of the invention comprises a base 1, a sliding module 2, a lifting module 3, a mounting plate 4 and a photovoltaic panel 10, wherein the sliding module 2 is in sliding fit on the base 1, the lifting module 3 is welded on the top of the sliding module 2, the mounting plate 4 is welded on one side of the top of the lifting module 3, a main photovoltaic frame 8 and an auxiliary photovoltaic frame 9 are installed on one side of the mounting plate 4 far away from the lifting module 3, the photovoltaic panel 10 is arranged in both the main photovoltaic frame 8 and the auxiliary photovoltaic frame 9, and the photovoltaic panel 10 is installed in the auxiliary photovoltaic frame 9 by arranging the auxiliary photovoltaic frame 9, so that the area of the photovoltaic panel 10 of the photovoltaic module is larger, and the power generation capacity of the photovoltaic module is further improved;

the base 1 comprises a bottom frame 101, a first screw rod 103 and a first motor 104, wherein the first screw rod 103 is rotatably matched in the bottom frame 101, the first motor 104 is installed at one end of the bottom frame 101, the first motor 104 is connected with the first screw rod 103 through a rotating shaft, slide rails 102 are welded on two sides of the bottom frame 101, and the sections of the two slide rails 102 are in an I-shaped structure;

the sliding assembly 2 comprises a connecting plate 201, sliding plates 203 and sliding blocks 204, the connecting plate 201 is horizontally arranged, a nut 202 is welded at the center of the top of the connecting plate 201, a first screw rod 103 is in threaded fit with the nut 202, the sliding plates 203 are vertically welded at two ends of the top of the connecting plate 201, the connecting plate 201 and the two sliding plates 203 are integrally in a U-shaped structure, the sliding blocks 204 are welded at one sides of the two sliding plates 203, which are close to the nut 202, respectively, a first sliding groove 205 is formed in one sides of the two sliding plates 204, which are close to the nut 202, respectively, the cross section of the first sliding groove 205 is matched with the cross section of the sliding rail 102 in size, the sliding blocks 204 are in sliding fit on the sliding rail 102 through the first sliding grooves 205, the sliding rail 102 is arranged, the connecting plate 201 moves more stably, the photovoltaic panel 10 moves more stably, and the photovoltaic panel, the efficiency of the lamination of the photovoltaic module is further improved, the first lead screw 103 is driven to rotate by the first motor 104, the first lead screw 103 drives the nut 102 to rotate, the nut 102 moves on the first lead screw 103, the nut 102 drives the connecting plate 201, the connecting plate 201 can move back and forth, the photovoltaic plate 10 of the photovoltaic module can move back and forth, the position of the photovoltaic plate 10 is adjusted by moving the photovoltaic plate 10 back and forth, the photovoltaic module can automatically correct the position in the lamination processing process, the precision of the lamination processing of the photovoltaic module is higher, and the lamination efficiency of the photovoltaic module is improved;

the lifting component 3 comprises supporting plates 301, a first fixing plate 303 and a third fixing plate 306, the two supporting plates 301 are vertically welded on the top of the connecting plate 201, the first fixing plate 303 is sleeved on the two supporting plates 301, the first fixing plate 303 is welded and fixed with the two supporting plates 301, the top of the two supporting plates 301 is welded with the second fixing plate 304, two ends of the top of the second fixing plate 304 are respectively penetrated with a first sliding rod 305, the two first sliding rods 305 are in sliding fit with the second fixing plate 304, the first sliding rods 305 are arranged and are in sliding fit with the second fixing plate 304, so that the third fixing plate 306 moves more stably, the photovoltaic panel 10 is adjusted up and down more stably and smoothly, the laminating efficiency of the photovoltaic component is further improved, the third fixing plate 306 is welded on the top of the two first sliding rods 305, and a second motor 308 is installed on the top of the third fixing plate 306, a second screw rod 307 is rotatably matched with the third fixing plate 306, the top of the second screw rod 307 is connected with a second motor 308 through a rotating shaft, the second screw rod 307 penetrates through the second fixing plate 304, the second screw rod 307 is in threaded fit with the second fixing plate 304, the second screw rod 307 is driven by the second motor 308 to rotate, the third fixing plate 306 is moved up and down through a first slide bar 305 by rotating the second screw rod 307, the photovoltaic panel 10 of the photovoltaic module can move up and down, the height of the movable photovoltaic panel 10 is adjusted by moving up and down, the photovoltaic panel 10 of the photovoltaic module can better receive each lamination, and therefore the lamination efficiency of the photovoltaic module is further improved;

the mounting plate 4 is vertically arranged, the mounting plate 4 is welded on one side of the third fixing plate 306, one side of the mounting plate 4 close to the third fixing plate 306 is rotatably matched with a knob 5, one end of the knob 5 penetrates through the mounting plate 4, one end of the knob 5 penetrating through the mounting plate 4 is welded with one end of the main photovoltaic frame 8, the knob 5 drives the main photovoltaic frame 8 to rotate by rotating the knob 5, the angle of the photovoltaic panel 10 is adjusted, a slide way 401 is arranged on the mounting plate 4, the slide way 401 is arranged in an arc shape, a bolt 6 is arranged in the slide way 401 in a sliding fit manner, the bolt 6 is connected with the main photovoltaic frame 8 in a threaded fit manner, the bolt 6 is screwed on the main photovoltaic frame 8 and the mounting plate 4 by rotating the bolt 6, fixing a photovoltaic plate 10, welding two pushing assemblies 7 at the bottom end of a main photovoltaic frame 8, welding an auxiliary photovoltaic frame 9 at one side of the two pushing assemblies 7, and movably matching the auxiliary photovoltaic frame 9 below the main photovoltaic frame 8 through the pushing assemblies 7;

photovoltaic board 10 includes bottom plate 11, battery piece 14 and glass piece 16, two bottom plates 11 weld respectively in the bottom of main photovoltaic frame 8 and vice photovoltaic frame 9, be fixed with backplate 12 on the bottom plate 11, be equipped with a plurality of glue point between bottom plate 11 and the backplate 12, bottom plate 11 and backplate 12 bond through the glue point, the top of backplate 12 is equipped with first encapsulation glued membrane 13, the top of first encapsulation glued membrane 13 is equipped with battery piece 14, the top of battery piece 14 is equipped with second encapsulation glued membrane 15, the top of second encapsulation glued membrane 15 is equipped with glass piece 16, through welding bottom plate 11 at the bottom of main photovoltaic frame 8 and vice photovoltaic frame 9, and fix backplate 12 through bottom plate 11, make this photovoltaic module's photovoltaic board 10 can be more convenient assemble, and then further improve the stromatolite efficiency of this photovoltaic group price.

The cross section of the bottom frame 101 is in a structure like a Chinese character kou, and four corners of the top of the bottom frame 101 are provided with screw holes 105.

The first motor 104, the first screw 103 and the slide rail 102 are all horizontally arranged, and the first screw 103 is located between the two slide rails 102.

The two sliding plates 203 are respectively positioned at two sides of the bottom frame 101, the sliding plates 203 are slidably fitted on the sliding rails 102 through the sliding blocks 204, and the connecting plate 201 is slidably fitted below the bottom frame 101 through the two sliding plates 203.

The first fixing plate 303, the second fixing plate 304 and the third fixing plate 306 are all horizontally arranged, and the first fixing plate 303, the second fixing plate 304 and the third fixing plate 306 are parallel to each other.

A second sliding groove 302 is formed in one side of the supporting plate 301, the cross section of the second sliding groove 302 is in a semicircular structure, and the lower half part of the first sliding rod 305 is in sliding fit in the second sliding groove 302.

The top of the first fixing plate 303 is provided with a through hole, and the diameter of the cross section of the through hole is larger than that of the cross section of the second lead screw 307.

The pushing assembly 7 comprises a fixing frame 701, a push plate 702 and a third screw rod 703, the fixing frame 701 is welded at the bottom end of the main photovoltaic frame 8, the section of the fixing frame 701 is of an L-shaped structure, the third screw rod 703 penetrates through the fixing frame 701, the screw thread of the third screw rod 703 is in threaded fit connection with the fixing frame 701, one end of the third screw rod 703 is fixedly welded with a rotating handle 705, two ends of the fixing frame 701 penetrate through second slide rods 704, one ends of the two second slide rods 704 are fixedly welded with the push plate 702, one side of the push plate 702, far away from the second slide rods 704, is welded with one side of the auxiliary photovoltaic frame 9, one end of the third screw rod 703, far away from the rotating handle 705, is in rotating fit on the push plate 702, the third screw rod 703 rotates, the third screw rod 703 moves forwards through the fixing frame 701, the push plate 702 moves forwards through the third screw rod 703, the push plate 702 pushes the auxiliary photovoltaic frame 9, and then make the photovoltaic board 10 on the vice photovoltaic frame 9 show, through adjusting vice photovoltaic frame 9, make the working area of this photovoltaic module's photovoltaic board 10 can freely adjust, and then can carry out accurate control to this photovoltaic module's generated energy, make this photovoltaic module can generate electricity according to actual power consumption demand, simultaneously, through the area of nimble adjustment photovoltaic board 10, make this photovoltaic module can install and use in more different occasions, improved the scope that this photovoltaic module used.

The rotating handle 705 is composed of a rotating block 706 and a rotating drum 707, the rotating block 706 is welded at one end of the third screw rod 703, the rotating drum 707 is in rotation fit with one side of the rotating block 706, the rotating drum 707 and the rotating block 706 are integrally of an L-shaped structure, and the rotating handle 705 is enabled to rotate more conveniently by arranging the rotating drum 707, so that the use convenience of the photovoltaic assembly is improved.

The use method of the photovoltaic module for improving the lamination efficiency specifically comprises the following steps:

the method comprises the following steps: the first screw rod 103 is driven by the first motor 104 to rotate, the first screw rod 103 drives the nut 102 to rotate, the nut 102 moves on the first screw rod 103, the nut 102 drives the connecting plate 201, the connecting plate 201 can move back and forth, and further the photovoltaic panel 10 of the photovoltaic module can move back and forth, the second screw rod 307 is driven by the second motor 308 to rotate, the third fixing plate 306 moves up and down through the first sliding rod 305 by rotating the second screw rod 307, and further the photovoltaic panel 10 of the photovoltaic module can move up and down;

step two: the knob 5 is rotated to drive the main photovoltaic frame 8 to rotate, the angle of the photovoltaic panel 10 is adjusted, and the bolt 6 is screwed on the main photovoltaic frame 8 and the mounting plate 4 by rotating the bolt 6 to fix the photovoltaic panel 10;

step three: the third screw rod 703 is rotated by rotating the rotating handle 705, the third screw rod 703 moves forward by rotating on the fixing frame 701, the push plate 702 is pushed forward by the forward movement of the third screw rod 703, the sub-photovoltaic frame 9 is pushed out by the push plate 702, and the photovoltaic panel 10 on the sub-photovoltaic frame 9 is displayed.

When in use, firstly, the first lead screw 103 is driven by the first motor 104 to rotate, the first lead screw 103 drives the nut 102 to rotate, the nut 102 moves on the first lead screw 103, the nut 102 drives the connecting plate 201 to enable the connecting plate 201 to move back and forth, and further enable the photovoltaic panel 10 of the photovoltaic module to move back and forth, the second lead screw 307 is driven by the second motor 308 to rotate, the third fixing plate 306 moves up and down through the first sliding rod 305 by rotating the second lead screw 307, and further enable the photovoltaic panel 10 of the photovoltaic module to move up and down, the position of the photovoltaic panel 10 is adjusted by moving the photovoltaic panel 10 back and forth, so that the photovoltaic module can automatically correct the position in the lamination processing process, further the lamination processing accuracy of the photovoltaic module is higher, the lamination efficiency of the photovoltaic module is improved, and the height of the photovoltaic panel 10 is adjusted by moving up and down, the photovoltaic panel 10 of the photovoltaic module can better support each lamination, so that the lamination efficiency of the photovoltaic module is further improved, the photovoltaic panel 10 can better follow the mechanical arm of lamination processing by moving the photovoltaic panel 10 back and forth and moving the photovoltaic panel 10 up and down in a matching way, the reciprocating material taking process of the mechanical arm is reduced, so that the lamination efficiency of the photovoltaic module is further improved, the sliding rail 102 is arranged, the sliding block 204 is in sliding fit on the sliding rail 102, so that the movement of the connecting plate 201 is more stable, the back and forth movement of the photovoltaic panel 10 is more stable, the precision of the lamination processing of the photovoltaic module is further improved, the lamination efficiency of the photovoltaic module is further improved, the first sliding rod 305 is arranged, the first sliding rod 305 is in sliding fit on the second fixing plate 304, so that the third fixing plate 306 moves more stably, and the up and down adjustment of the photovoltaic panel 10 is more stable and smooth, further improving the laminating efficiency of the photovoltaic module, then, by rotating the knob 5, the knob 5 drives the main photovoltaic frame 8 to rotate, the angle of the photovoltaic panel 10 is adjusted, by rotating the bolt 6, the bolt 6 is screwed on the main photovoltaic frame 8 and the mounting plate 4, the photovoltaic panel 10 is fixed, by adjusting the angle of the photovoltaic panel 10 of the photovoltaic module, the photovoltaic module 10 can adjust the photovoltaic panel 10 according to the solar energy suggested mounting angle of the world meteorology bureau, thereby improving the flexibility of the use of the photovoltaic module, by adjusting the angle of the photovoltaic panel 10, the power generation amount of the photovoltaic module is as large as possible, the power generation amount of the photovoltaic module is improved, thereby improving the economic benefit of the use of the photovoltaic module, by fixing the photovoltaic panel 10 by using the bolt 6, the photovoltaic panel 10 of the photovoltaic module is adjusted and fixed more stably, and further improving the reliability of the photovoltaic module, finally, rotating the rotating handle 705 to rotate the third screw rod 703, the third screw rod 703 moves forward by rotating on the fixing frame 701, the push plate 702 is pushed forward by the forward movement of the third screw rod 703, the push plate 702 pushes the sub-photovoltaic frame 9 to push out the sub-photovoltaic frame 9, and further the photovoltaic panel 10 on the sub-photovoltaic frame 9 is displayed, by arranging the sub-photovoltaic frame 9 and installing the photovoltaic panel 10 in the sub-photovoltaic frame 9, the area of the photovoltaic panel 10 of the photovoltaic module is larger, and further the power generation amount of the photovoltaic module is improved, by adjusting the sub-photovoltaic frame 9, the working area of the photovoltaic panel 10 of the photovoltaic module can be freely adjusted, and further the power generation amount of the photovoltaic module can be accurately controlled, so that the photovoltaic module can generate power according to the actual power demand, and simultaneously, by flexibly adjusting the area of the photovoltaic panel 10, the photovoltaic module can be installed and used in more different occasions, the use range of the photovoltaic module is improved, the bottom of the main photovoltaic frame 8 and the bottom of the auxiliary photovoltaic frame 9 are welded with the bottom plate 11, the backboard 12 is fixed through the bottom plate 11, the photovoltaic plate 10 of the photovoltaic module can be assembled more conveniently, and the laminating efficiency of the photovoltaic module is further improved.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and the embodiments and descriptions given above are only illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides an improve photovoltaic module of stromatolite efficiency, includes base (1), sliding assembly (2), lifting unit (3), mounting panel (4) and photovoltaic board (10), its characterized in that: the sliding assembly (2) is in sliding fit with the base (1), the lifting assembly (3) is welded at the top of the sliding assembly (2), the mounting plate (4) is welded at one side of the top of the lifting assembly (3), the main photovoltaic frame (8) and the auxiliary photovoltaic frame (9) are mounted at one side, far away from the lifting assembly (3), of the mounting plate (4), and photovoltaic plates (10) are arranged in the main photovoltaic frame (8) and the auxiliary photovoltaic frame (9);

the base (1) comprises a bottom frame (101), a first screw rod (103) and a first motor (104), the first screw rod (103) is in running fit with the bottom frame (101), the first motor (104) is installed at one end of the bottom frame (101), the first motor (104) is connected with the first screw rod (103) through a rotating shaft, sliding rails (102) are welded on two sides of the bottom frame (101), and the sections of the two sliding rails (102) are in I-shaped structures;

the sliding assembly (2) comprises a connecting plate (201), sliding plates (203) and sliding blocks (204), the connecting plate (201) is horizontally arranged, a nut (202) is welded at the center of the top of the connecting plate (201), a first lead screw (103) is matched with an internal thread of the nut (202), the sliding plates (203) are vertically welded at two ends of the top of the connecting plate (201), the connecting plate (201) and the two sliding plates (203) are integrally of a U-shaped structure, the sliding blocks (204) are welded at one sides of the two sliding plates (203) close to the nut (202), first sliding grooves (205) are formed in one sides of the two sliding blocks (204) close to the nut (202), the cross sections of the first sliding grooves (205) are matched with the cross sections of the sliding rails (102), and the sliding blocks (204) are in sliding fit on the sliding rails (102) through the first sliding grooves (205);

the lifting component (3) comprises supporting plates (301), a first fixing plate (303) and a third fixing plate (306), the two supporting plates (301) are vertically welded at the top of a connecting plate (201), the first fixing plate (303) is sleeved on the two supporting plates (301), the first fixing plate (303) is welded and fixed with the two supporting plates (301), the second fixing plate (304) is welded at the top of the two supporting plates (301), first sliding rods (305) penetrate through two ends of the top of the second fixing plate (304), the first sliding rods (305) are in sliding fit with the second fixing plate (304), the third fixing plate (306) is welded at the top of the first sliding rods (305), a second motor (308) is installed at the top of the third fixing plate (306), and a second lead screw (307) is in rotating fit with the third fixing plate (306), the top of the second screw rod (307) is connected with a second motor (308) through a rotating shaft, the second screw rod (307) penetrates through the second fixing plate (304), and the second screw rod (307) is in threaded fit connection with the second fixing plate (304);

the mounting plate (4) is vertically arranged, the mounting plate (4) is welded at one side of the third fixing plate (306), a knob (5) is rotatably matched at one side of the mounting plate (4) close to the third fixing plate (306), one end of the knob (5) penetrates through the mounting plate (4), one end of the knob (5) penetrating through the mounting plate (4) is welded with one end of the main photovoltaic frame (8), the mounting plate (4) is provided with a slideway (401), the slideway (401) is arranged in an arc shape, a bolt (6) is matched in the slide way (401) in a sliding way, the bolt (6) is connected with the main photovoltaic frame (8) in a threaded matching way, two pushing components (7) are welded at the bottom end of the main photovoltaic frame (8), an auxiliary photovoltaic frame (9) is welded at one side of the two pushing components (7), the auxiliary photovoltaic frame (9) is movably matched below the main photovoltaic frame (8) through the pushing assembly (7);

photovoltaic board (10) are including bottom plate (11), battery piece (14) and glass piece (16), two bottom plate (11) welds respectively in the bottom of main photovoltaic frame (8) and vice photovoltaic frame (9), be fixed with backplate (12) on bottom plate (11), be equipped with a plurality of between bottom plate (11) and backplate (12) and glue the point, bottom plate (11) and backplate (12) bond through gluing the point, the top of backplate (12) is equipped with first encapsulation glued membrane (13), the top of first encapsulation glued membrane (13) is equipped with battery piece (14), the top of battery piece (14) is equipped with second encapsulation glued membrane (15), the top of second encapsulation glued membrane (15) is equipped with glass piece (16).

2. The photovoltaic module of claim 1, wherein: the cross section of the bottom frame (101) is of a square structure, and screw holes (105) are formed in four corners of the top of the bottom frame (101).

3. The photovoltaic module of claim 1, wherein: first motor (104), first lead screw (103) and slide rail (102) all are the level setting, and just first lead screw (103) are located the centre of two slide rails (102).

4. The photovoltaic module of claim 1, wherein: the two sliding plates (203) are respectively positioned at two sides of the bottom frame (101), the sliding plates (203) are in sliding fit on the sliding rails (102) through the sliding blocks (204), and the connecting plate (201) is in sliding fit below the bottom frame (101) through the two sliding plates (203).

5. The photovoltaic module of claim 1, wherein: first fixed plate (303), second fixed plate (304) and third fixed plate (306) all are the horizontal setting, and are parallel to each other between first fixed plate (303), second fixed plate (304) and third fixed plate (306).

6. The photovoltaic module of claim 1, wherein: a second sliding groove (302) is formed in one side of the supporting plate (301), the section of the second sliding groove (302) is of a semicircular structure, and the lower half part of the first sliding rod (305) is in sliding fit in the second sliding groove (302).

7. The photovoltaic module of claim 1, wherein: the top of the first fixing plate (303) is provided with a through hole, and the diameter of the cross section of the through hole is larger than that of the cross section of the second screw rod (307).

8. The photovoltaic module of claim 1, wherein: the pushing assembly (7) comprises a fixing frame (701), a pushing plate (702) and a third lead screw (703), the fixing frame (701) is welded at the bottom end of the main photovoltaic frame (8), the cross section of the fixing frame (701) is of an L-shaped structure, the third lead screw (703) penetrates through the fixing frame (701), the third lead screw (703) is in threaded fit connection with the fixing frame (701), a rotating handle (705) is fixedly welded at one end of the third lead screw (703), a second sliding rod (704) penetrates through two ends of the fixing frame (701), the pushing plate (702) is fixedly welded at one end of the two second sliding rods (704), one side, far away from the second sliding rod (704), of the pushing plate (702) is welded with one side of the auxiliary photovoltaic frame (9), and one end, far away from the rotating handle (705), of the third lead screw (703) is in rotating fit with the pushing plate (.

9. The photovoltaic module of claim 8, wherein: the rotating handle (705) is composed of a rotating block (706) and a rotating drum (707), the rotating block (706) is welded at one end of the third screw rod (703), the rotating drum (707) is in rotating fit with one side of the rotating block (706), and the rotating drum (707) and the rotating block (706) are integrally of an L-shaped structure.

10. The photovoltaic module of claim 1, wherein: the use method of the photovoltaic module for improving the lamination efficiency specifically comprises the following steps:

the method comprises the following steps: the first screw rod (103) is driven to rotate by the first motor (104), the first screw rod (103) drives the nut (102) to rotate, the nut (102) moves on the first screw rod (103), the nut (102) drives the connecting plate (201), the connecting plate (201) can move back and forth, the photovoltaic plate (10) of the photovoltaic assembly can move back and forth, the second screw rod (307) is driven by the second motor (308) to rotate, the third fixing plate (306) can move up and down through the first sliding rod (305) by rotating the second screw rod (307), and the photovoltaic plate (10) of the photovoltaic assembly can move up and down;

step two: the knob (5) is rotated to drive the main photovoltaic frame (8) to rotate, the angle of the photovoltaic panel (10) is adjusted, and the bolt (6) is screwed on the main photovoltaic frame (8) and the mounting plate (4) by rotating the bolt (6) to fix the photovoltaic panel (10);

step three: the third screw rod (703) is rotated by rotating the rotating handle (705), the third screw rod (703) moves forwards by rotating on the fixing frame (701), the third screw rod (703) moves forwards to push the push plate (702), the push plate (702) pushes the auxiliary photovoltaic frame (9) to push the auxiliary photovoltaic frame (9), and then the photovoltaic plate (10) on the auxiliary photovoltaic frame (9) is displayed.