CN118157556A - Novel solar cell panel installs fast device - Google Patents

Abstract

The invention relates to a novel solar panel rapid installation device, which aims to solve the technical problems of inconvenient disassembly and assembly and adjustment of the solar panel of the current high-rise building.

Description

Novel solar cell panel installs fast device

Technical Field

The invention relates to the technical field of photovoltaic power generation, in particular to a novel rapid solar panel mounting device.

Background

The solar cell is a photoelectric semiconductor sheet which directly generates electricity by utilizing sunlight, is also called a solar chip or a photocell, and can output voltage instantly and generate current under the condition of a loop as long as the solar cell is subjected to illuminance meeting a certain illuminance condition. Physically, solar photovoltaic, simply referred to as photovoltaic. Solar cells are devices that directly convert light energy into electrical energy through a photoelectric effect or a photochemical effect. Crystalline silicon solar cells working with photovoltaic effect are the main stream, while thin film cells working with photochemical effect are also in the germination stage.

Many public places in a cell need to use energy equipment such as illumination, heating and the like, and the use of the equipment consumes a large amount of energy, increases the energy expenditure of the cell and also generates a large amount of carbon emission. The solar panel is uniformly installed, so that solar energy resources can be utilized to convert the solar panel into heat energy or electric energy, thereby reducing energy consumption and carbon emission of a community and achieving the purposes of energy conservation and emission reduction. Due to the characteristics of the high-rise building at the present stage, the property developer basically builds a position by extending the edge of the bottom of the balcony for placing the solar cell panel, the position of the solar cell panel is fixed and cannot be adjusted along with the irradiation direction of the sun, and the energy conversion efficiency is low; in addition, the use habit of each household is different in the later house decoration use of the residents, and if a solar water heater is not used, the solar cell panel can be removed in the later period of many households; the method not only wastes the construction cost in the earlier stage, but also is complicated to adjust, install and disassemble, so that how to design a novel device which is suitable for the solar panel and is convenient to adjust and install quickly is particularly important. In view of this, we propose a novel solar panel quick mounting device.

Disclosure of Invention

The invention aims to overcome the defects of the prior art, adapt to the actual needs, and provide a novel rapid solar panel mounting device so as to solve the technical problems of inconvenient dismounting and adjustment of the solar panel of the current high-rise building.

In order to achieve the purpose of the invention, the technical scheme adopted by the invention is as follows: the novel solar panel rapid installation device comprises a solar panel, wherein a connecting support is arranged at the bottom end of the solar panel, an adjusting mechanism is connected to the bottom end of the connecting support, an installing support is arranged at the bottom end of the adjusting mechanism, and an installing mechanism is arranged at one end, far away from the adjusting mechanism, of the installing support; the installation mechanism comprises an installation shell, a sliding component and a deformation component, wherein the installation shell is connected to one end, far away from the adjusting mechanism, of the installation support, the sliding component is connected to the installation shell in a sliding mode, and the deformation component is arranged in the installation shell and is opposite to the sliding component in position. According to the invention, the connecting support is arranged at the bottom end of the solar cell panel, the adjusting mechanism is arranged at the bottom end of the connecting support, the mounting support is arranged at the bottom end of the adjusting mechanism, the mounting mechanism is arranged on the mounting support, the sliding component and the deformation component inside the mounting shell of the mounting mechanism are utilized to realize internal deformation, the two sliding blocks slide towards the center of the sliding chute in opposite directions to drive the two side plates and the limiting long holes to slide, so that the limiting block and the deformation block inside the casing are bent, the limiting block and the deformation block are formed into a cylindrical shape for being coated on the cylindrical balcony railing, and the two sliding blocks form a square shape for being coated on the square balcony railing when at the two ends of the sliding chute.

Preferably, the installation shell comprises a shell body, a hinge, a locking block, a locking hole and a sliding groove, wherein the hinge is connected with one end, far away from the adjusting mechanism, of the installation support, the shell body is symmetrically hinged and connected with one end, far away from the installation support, of the hinge, the locking block is arranged at one end, far away from the hinge, of the shell body, a plurality of locking holes are formed in the locking block, and the sliding groove is formed in the position, opposite to the sliding component, of the outer wall of the shell body. According to the balcony railing, the hinge is arranged on the mounting bracket, the shell is symmetrically arranged at the other end of the hinge, the locking blocks are symmetrically arranged at the other end of the shell, the locking holes are formed in the locking blocks, the shell is opened through the hinge during mounting, and the balcony railing is locked and connected through the locking holes through the bolt fastener.

Preferably, the sliding assembly comprises a sliding block, a connecting block, connecting holes, side plates and limiting long holes, the sliding block is slidably connected to the sliding groove, the connecting block is connected to the top end of the sliding block, the connecting holes are formed in the connecting block, the side plates are symmetrically arranged at the positions, opposite to the side surfaces of the shell, of the two ends of the connecting block, the limiting long holes are symmetrically formed in the side plates, and the two ends of the deformation assembly are connected to the limiting long holes.

Preferably, the deformation assembly comprises a connecting shaft, a limiting block and deformation blocks, wherein the connecting shaft is connected to the inner wall of the shell, the limiting block is connected to the connecting shaft at a position opposite to the inner side of the shell, two ends of the limiting block are slidably inserted into the limiting long holes, the deformation blocks are connected to the limiting block at positions opposite to the inner side of the shell, the limiting block is adaptive to the size of the limiting long holes, and the deformation blocks are of structures with inclined surfaces on two sides. According to the balcony railing, the connecting shaft is arranged on the inner wall of the shell, the limiting block and the deformation blocks are connected on the connecting shaft, the limiting block is made of a bendable material when the side plates move oppositely, the limiting block drives the deformation blocks, the deformation blocks are trapezoid, a plurality of deformation blocks form a semi-cylinder shape and are used for wrapping the cylindrical railing, when the side plates are arranged at the two ends of the sliding groove, the limiting block is flattened, and the deformation blocks are located on the same horizontal line to adapt to the balcony railing.

Preferably, the adjusting mechanism comprises an adjusting shell, a supporting component, a rotating component, a swing component and an adjusting component, wherein the adjusting shell is connected to the position, opposite to the top end of the mounting bracket, of the bottom end of the connecting bracket, the supporting component is arranged inside the adjusting shell, the rotating component is arranged on the supporting component, the swing component is arranged on the supporting component, opposite to the rotating component, and the adjusting component is arranged on the supporting component, opposite to the positions, opposite to the back surfaces of the rotating component and the swing component.

Preferably, the supporting component comprises supporting columns, supporting seats and supporting frames, the supporting columns are symmetrically arranged inside the adjusting shell, the supporting seats are connected between the two supporting columns, the supporting frames are symmetrically arranged on the supporting columns, the rotating component and the swing component penetrate through the supporting seats, and the adjusting component is arranged on the supporting frames. According to the invention, the bottom end of the connecting support is provided with the adjusting shell, the supporting component is arranged in the adjusting shell, the rotating component is arranged on the supporting component, the swing component is arranged in the rotating component, and the adjusting component is arranged on the supporting component relative to the positions of the rotating component and the swing component and is used for adjusting and selecting rotation or angle swing.

Preferably, the rotating assembly comprises a screw shaft A, a gear A, a rotating sleeve, a rotating frame and a rotating shaft, wherein the screw shaft A is rotationally connected to the supporting frame, the rotating sleeve is rotationally arranged on the supporting seat in a penetrating mode, the gear A is connected to the position, opposite to the screw shaft A, of the bottom end of the rotating sleeve, the rotating frame is connected to the top end of the rotating sleeve, the rotating shaft is rotationally connected to the rotating frame, and the connecting support is connected to the top end of the rotating shaft. According to the solar cell panel, the spiral shaft A is arranged on one of the supporting frames, the rotating sleeve is arranged on the supporting seat in a penetrating mode, the bottom end of the rotating sleeve is connected with the spiral shaft A in a meshed mode, the rotating sleeve is driven to rotate by the rotating spiral shaft A, the rotating frame is driven to rotate by the rotating sleeve, the rotating shaft is driven to rotate by the rotating frame, and the connecting frame and the solar cell panel are driven to rotate by the rotating shaft.

Preferably, the swing assembly comprises a screw shaft B, a gear B, a central shaft, a spur gear, a bevel gear A and a bevel gear B, wherein the screw shaft B is rotationally connected to the other support frame, the central shaft is rotationally arranged on the rotary sleeve in a penetrating mode, the gear B is rotationally connected to the position, relative to the screw shaft B, of the bottom end of the central shaft, the spur gear is connected to the position, relative to the rotary frame, of the top end of the central shaft, the bevel gear A is arranged on the rotary frame, relative to one side of the spur gear, the bevel gear B is sleeved on the position, relative to the top end of the bevel gear A, of the rotary shaft, and the bevel gear A is in meshed connection with the bevel gear B. According to the invention, the spiral shaft B is arranged on the other support frame, the central shaft is arranged on the rotating sleeve, the gear B is arranged at the bottom end of the central shaft, and the gear B is connected with the spiral shaft B, so that the gear B and the central shaft are driven to rotate when the spiral shaft B rotates, the central shaft drives the spur gear to rotate, and the spur gear is meshed with the bevel gear A on the rotating frame, so that the bevel gear B rotates, and the bevel gear B drives the rotating shaft to rotate on the rotating frame.

Preferably, the adjusting assembly comprises a rotating handle, a driving wheel, an idler wheel, an adjusting rod and a sliding hole, wherein the rotating handle is inserted in the position, opposite to the supporting frame, of the back surface of the adjusting shell, the driving wheel is connected to the inner end of the rotating handle, the idler wheel is rotationally arranged on the back surface of the supporting frame, the sliding hole is formed in the position, opposite to the idler wheel, of the supporting frame, one end of the adjusting rod is connected to the idler wheel, and the other end of the adjusting rod is inserted in the sliding hole in a sliding mode.

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

1. According to the invention, the structure of the existing solar panel mounting device is improved, the connecting support is arranged at the bottom end of the solar panel, the adjusting mechanism is arranged at the bottom end of the connecting support, the mounting support is provided with the mounting mechanism, the inner deformation of the mounting shell of the mounting mechanism is realized by utilizing the sliding component and the deformation component in the mounting shell, and the two side plates and the limiting long holes are driven to slide in opposite directions towards the center of the sliding groove through the two sliding blocks, so that the limiting blocks and the deformation blocks in the shell are bent, form a cylinder shape for being coated on the cylindrical balcony railing, and form a square shape for being coated on the square balcony railing when the two sliding blocks are arranged at the two ends of the sliding groove, thereby being beneficial to the rapid mounting of the solar panel and improving the mounting efficiency and the suitability.

2. According to the invention, the hinge is arranged on the mounting bracket, the shell is symmetrically arranged at the other end of the hinge, the locking block is symmetrically arranged at the other end of the shell, the locking hole is formed in the locking block, the shell is opened through the hinge during mounting, and the balcony railing is locked and connected through the locking hole by utilizing the bolt fastener, so that a building does not need to be built with more areas on a balcony for placing a solar cell panel during construction, the early construction cost is saved, the problem that an excessive area shields house lighting after later disassembly is prevented, and the mounting and dismounting efficiency is greatly improved.

3. According to the invention, the connecting shaft is arranged on the inner wall of the shell, the limiting block and the deformation blocks are connected on the connecting shaft, when the side plates move oppositely, the limiting block is made of a bendable material, the limiting block drives the deformation blocks, the deformation blocks are trapezoid, so that the deformation blocks form a semi-cylinder shape and are used for wrapping the cylindrical railing, when the side plates are arranged at the two ends of the sliding chute, the limiting block is flattened, the deformation blocks are positioned on the same horizontal line, so that the deformation blocks are adapted to the balcony railing, the installation efficiency is improved, and the adaptability is improved.

4. According to the solar panel, the bottom end of the connecting support is provided with the adjusting shell, the supporting component is arranged in the adjusting shell, the rotating component is arranged on the supporting component, the swing component is arranged in the rotating component, the adjusting component is arranged on the supporting component relative to the positions of the rotating component and the swing component and is used for adjusting and selecting rotation or angle swing, so that the solar panel has an angle adjusting function of 360 degrees, the rotation and direction can be adjusted very quickly and efficiently in the later using process of the solar panel, the sunlight irradiation angle can be met, and the conversion efficiency of the solar panel can be greatly improved.

5. According to the solar cell panel, the spiral shaft A is arranged on one of the supporting frames, the rotating sleeve is arranged on the supporting seat in a penetrating mode, the bottom end of the rotating sleeve is connected with the spiral shaft A in a meshed mode, the rotating spiral shaft A drives the rotating sleeve to rotate, the rotating sleeve drives the rotating frame to rotate, the rotating frame drives the rotating shaft to rotate, and the rotating shaft drives the connecting support and the solar cell panel to rotate, so that the solar cell panel can rotate in an omnibearing mode to adjust the angle to adapt to irradiation of sunlight, light conversion efficiency of the solar cell panel is improved, energy is saved, and energy conservation and emission reduction are facilitated.

6. According to the solar cell panel conversion device, the spiral shaft B is arranged on the other support frame, the central shaft is arranged on the rotating sleeve, the gear B is arranged at the bottom end of the central shaft, and the gear B is connected with the spiral shaft B, so that when the spiral shaft B rotates, the gear B and the central shaft are driven to rotate, the central shaft drives the spur gear to rotate, the spur gear is meshed with the bevel gear A on the rotating frame, the bevel gear B rotates, the bevel gear B drives the rotating shaft to rotate on the rotating frame, the connecting support and the solar cell panel realize angle swing, the swing angle of the solar cell panel is adjusted, the solar cell panel conversion device is suitable for sunlight irradiation conditions of different angles, and the conversion efficiency of the solar cell panel is further improved.

Drawings

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

FIG. 2 is a schematic view of the overall rear structure of the present invention;

FIG. 3 is a schematic side view of the present invention;

FIG. 4 is a schematic rear view of the present invention;

FIG. 5 is a schematic view of a mounting mechanism and mounting bracket according to the present invention;

FIG. 6 is an enlarged view of the invention at A;

FIG. 7 is a schematic side view of the mounting mechanism of the present invention in one state;

FIG. 8 is a schematic side view of a mounting mechanism according to another embodiment of the present invention;

FIG. 9 is a schematic cross-sectional view of the mounting mechanism of the present invention in one state;

FIG. 10 is a schematic cross-sectional view of the mounting mechanism of the present invention in another state;

FIG. 11 is a schematic view of an open configuration of the mounting mechanism of the present invention;

FIG. 12 is a schematic view of the internal structure of the adjusting mechanism according to the present invention;

FIG. 13 is a schematic cross-sectional view of an adjustment mechanism of the present invention;

In the figure: 1. a solar cell panel; 2. a connecting bracket; 3. an adjusting mechanism; 4. a mounting bracket; 5. a mounting mechanism;

301. An adjustment housing; 302. a support assembly; 303. a rotating assembly; 304. a swing assembly; 305. an adjustment assembly;

501. a mounting shell; 502. a sliding assembly; 503. a deformation assembly;

3021. a support column; 3022. a support base; 3023. a support frame;

3031. a screw axis A; 3032. a gear A; 3033. rotating the sleeve; 3034. a rotating frame; 3035. a rotation shaft;

3041. A screw axis B; 3042. a gear B; 3043. a central shaft; 3044. spur gears; 3045. a bevel gear A; 3046. a bevel gear B;

3051. rotating the handle; 3052. a driving wheel; 3053. an idler; 3054. an adjusting rod; 3055. a slide hole;

5011. a housing; 5012. a hinge; 5013. a locking block; 5014. a locking hole; 5015. a chute;

5021. A slide block; 5022. a connecting block; 5023. a connection hole; 5024. a side plate; 5025. a limiting slot hole;

5031. a connecting shaft; 5032. a limiting block; 5033. and (5) deforming the block.

Detailed Description

The invention is further illustrated by the following examples in conjunction with the accompanying drawings:

Example 1: the novel solar panel rapid installation device comprises a solar panel 1, wherein a connecting support 2 is arranged at the bottom end of the solar panel 1, an adjusting mechanism 3 is connected at the bottom end of the connecting support 2, a mounting support 4 is arranged at the bottom end of the adjusting mechanism 3, and a mounting mechanism 5 is arranged at one end, far away from the adjusting mechanism 3, of the mounting support 4; the mounting mechanism 5 comprises a mounting shell 501, a sliding component 502 and a deformation component 503, wherein the mounting shell 501 is connected to one end of the mounting bracket 4, which is far away from the adjusting mechanism 3, the sliding component 502 is slidably connected to the mounting shell 501, and the deformation component 503 is arranged in the mounting shell 501 at a position corresponding to the sliding component 502. According to the invention, the structure of the existing solar cell panel installation device is improved, the connecting support 2 is arranged at the bottom end of the solar cell panel 1, the adjusting mechanism 3 is arranged at the bottom end of the connecting support 2, the installation support 4 is arranged at the bottom end of the adjusting mechanism 3, the installation mechanism 5 is arranged on the installation support 4, the sliding component 502 and the deformation component 503 in the installation shell 501 of the installation mechanism 5 are utilized to realize internal deformation, the two side plates 5024 and the limiting long holes 5025 are driven to slide in opposite directions towards the center of the sliding groove 5015 through the two sliding blocks 5021, so that the limiting blocks 5032 and the deformation blocks 5033 in the shell 5011 are bent to form a cylinder shape for being coated on a cylindrical balcony railing, and the two sliding blocks 5021 form a square shape for being coated on the square balcony railing when being arranged at the two ends of the sliding groove 5015, thereby being beneficial to the rapid installation of the solar cell panel and improving the installation efficiency and the suitability.

Specifically, the mounting case 501 includes a housing 5011, a hinge 5012, a locking block 5013, a locking hole 5014 and a sliding chute 5015, the hinge 5012 is connected to one end of the mounting bracket 4 away from the adjusting mechanism 3, the housing 5011 is symmetrically hinged to one end of the hinge 5012 away from the mounting bracket 4, the locking block 5013 is arranged at one end of the housing 5011 away from the hinge 5012, the locking holes 5014 are arranged on the locking block 5013, and the sliding chute 5015 is arranged at the position of the relative sliding component 502 on the outer wall of the housing 5011. According to the invention, the hinge 5012 is arranged on the mounting bracket 4, the shell 5011 is symmetrically arranged at the other end of the hinge 5012, the locking block 5013 is symmetrically arranged at the other end of the shell 5011, the locking hole 5014 is formed in the locking block 5013, the shell 5011 is opened through the hinge 5012 during mounting, and the balcony railing is locked and connected through the locking hole 5014 by utilizing the bolt fastener, so that a building does not need to be built into a region on a balcony for placing a solar cell panel during construction, the early construction cost is saved, the problem that the excessive region shields house lighting after later disassembly is prevented, and the mounting and dismounting efficiency is greatly improved.

Further, the sliding component 502 includes a slider 5021, a connecting block 5022, a connecting hole 5023, a side plate 5024 and a limiting long hole 5025, the slider 5021 is slidably connected to the sliding groove 5015, the connecting block 5022 is connected to the top end of the slider 5021, the connecting hole 5023 is formed in the connecting block 5022, the side plate 5024 is symmetrically arranged at the positions, opposite to the side face of the shell 5011, of the two ends of the connecting block 5022, the limiting long hole 5025 is symmetrically formed in the plurality of side plates 5024, and two ends of the deformation component 503 are connected to the limiting long hole 5025. According to the invention, two sliding blocks 5021 are connected on the sliding groove 5015 in a sliding manner, the connecting blocks 5022 are connected on the sliding blocks 5021, the side plates 5024 are arranged on two sides of each connecting block 5022, the limiting long holes 5025 are formed in the side plates 5024, and the limiting long holes 5025 and the deformation components 503 are matched to generate deformation, so that two different forms are generated to be adapted to balcony rails with different shapes, and the effects of saving material cost and installation time cost are achieved.

Still further, deformation subassembly 503 includes connecting axle 5031, stopper 5032 and deformation piece 5033, connecting axle 5031 connects on casing 5011 inner wall, stopper 5032 is connected on connecting axle 5031 relative the inside position of casing 5011, stopper 5032 both ends slip is inserted and is located on spacing slot 5025, a plurality of deformation pieces 5033 connect on stopper 5032 relative the inside position of casing 5011, stopper 5032 and spacing slot 5025 size adaptation, deformation piece 5033 is the structure that both sides face had the inclined plane. According to the invention, the connecting shaft 5031 is arranged on the inner wall of the shell 5011, the limiting block 5032 and the deformation blocks 5033 are connected on the connecting shaft 5031, when the side plates 5024 move oppositely, the limiting block 5032 is made of a bendable material, the limiting block 5032 drives the deformation blocks 5033, and as the deformation blocks 5033 are in a ladder shape, a plurality of deformation blocks 5033 form a semi-cylinder shape and are used for wrapping cylindrical railings, when the side plates 5024 are arranged at two ends of the sliding grooves 5015, the limiting block 5032 is flattened, and the deformation blocks 5033 are positioned on the same horizontal line so as to adapt to the shape of the balcony railings, so that the installation efficiency is improved and the adaptability is improved.

It should be noted that, the adjusting mechanism 3 includes an adjusting housing 301, a supporting component 302, a rotating component 303, a swing component 304 and an adjusting component 305, the adjusting housing 301 is connected to a position of the bottom end of the connecting bracket 2 opposite to the top end of the mounting bracket 4, the supporting component 302 is disposed inside the adjusting housing 301, the rotating component 303 is disposed on the supporting component 302, the swing component 304 is disposed on the supporting component 302 opposite to the rotating component 303, and the adjusting component 305 is disposed on the supporting component 302 opposite to the rotating component 303 and the swing component 304. According to the solar panel, the adjusting shell 301 is arranged at the bottom end of the connecting support 2, the supporting component 302 is arranged in the adjusting shell 301, the rotating component 303 is arranged on the supporting component 302, the swing component 304 is arranged in the rotating component 303, and the adjusting component 305 is arranged on the supporting component 302 relative to the positions of the rotating component 303 and the swing component 304 and is used for adjusting and selecting rotation or angle swing, so that the solar panel has an angle adjusting function of 360 degrees, the rotation and direction adjustment in the later use process of the solar panel is very fast and efficient, and the solar panel caters for sunlight irradiation angles, so that the conversion efficiency of the solar panel is greatly improved.

It is noted that the support assembly 302 includes a support post 3021, a support base 3022 and a support frame 3023, the support post 3021 is symmetrically disposed inside the adjusting housing 301, the support base 3022 is connected between the two support posts 3021, the support frame 3023 is symmetrically disposed on the support post 3021, the rotation assembly 303 and the swing assembly 304 are disposed on the support base 3022 in a penetrating manner, and the adjusting assembly 305 is disposed on the support frame 3023. According to the invention, the supporting upright post 3021 is arranged in the adjusting housing 301, the supporting seat 3022 is arranged on the supporting upright post 3021, the supporting seat 3022 is used for bearing the rotating assembly 303 and the swing assembly 304, the supporting frame 3023 is further arranged on the supporting upright post 3021, and the supporting frame 3023 is used for bearing the adjusting assembly 305, so that reasonable arrangement of the structure is achieved, whether the swing angle or the rotating angle can be adjusted can be selected through the adjusting assembly 305, the adjusting efficiency is improved, and the market popularization is facilitated.

It is to be noted that the rotating assembly 303 includes a screw shaft a3031, a gear a3032, a rotating sleeve 3033, a rotating frame 3034 and a rotating shaft 3035, the screw shaft a3031 is rotatably connected to the supporting frame 3023, the rotating sleeve 3033 is rotatably disposed on the supporting seat 3022 in a penetrating manner, the gear a3032 is connected to a bottom end of the rotating sleeve 3033 at a position opposite to the screw shaft a3031, the rotating frame 3034 is connected to a top end of the rotating sleeve 3033, the rotating shaft 3035 is rotatably connected to the rotating frame 3034, and the connecting bracket 2 is connected to a top end of the rotating shaft 3035. According to the invention, the screw shaft A3031 is arranged on one of the supporting frames 3023, the rotating sleeve 3033 is arranged on the supporting seat 3022 in a penetrating way, the bottom end of the rotating sleeve 3033 is connected with the screw shaft A3031 in a meshed way, the rotating screw shaft A3031 drives the rotating sleeve 3033 to rotate, the rotating sleeve 3033 drives the rotating frame 3034 to rotate, the rotating frame 3034 drives the rotating shaft 3035 to rotate, and the rotating shaft 3035 drives the connecting bracket 2 and the solar panel 1 to rotate, so that the solar panel can rotate in an omnibearing way to adjust the angle so as to adapt to the irradiation of sunlight, the light conversion efficiency of the solar panel is improved, the energy is saved, and the energy conservation and the emission reduction are facilitated.

It is emphasized that the swing assembly 304 includes a spiral shaft B3041, a gear B3042, a central shaft 3043, a spur gear 3044, a bevel gear a3045 and a bevel gear B3046, the spiral shaft B3041 is rotatably connected to the other support frame 3023, the central shaft 3043 is rotatably disposed on the rotating sleeve 3033, the gear B3042 is rotatably connected to a bottom end of the central shaft 3043 opposite to the spiral shaft B3041, the spur gear 3044 is connected to a top end of the central shaft 3043 opposite to the rotating frame 3034, the bevel gear a3045 is disposed on one side of the rotating frame 3034 opposite to the spur gear 3044, the bevel gear B3046 is sleeved on the rotating shaft 3035 opposite to a top end of the bevel gear a3045, and the bevel gear a3045 is engaged with the bevel gear B3046. According to the invention, the spiral shaft B3041 is arranged on the other support frame 3023, the central shaft 3043 is arranged on the rotating sleeve 3033, the gear B3042 is arranged at the bottom end of the central shaft 3043, the gear B3042 and the central shaft 3043 are driven to rotate when the spiral shaft B3041 rotates through the connection of the gear B3042 and the spiral shaft B3041, the straight gear 3044 is driven by the central shaft 3043 to rotate, the straight gear 3044 is meshed with the bevel gear A3045 on the rotating frame 3034, the bevel gear B3046 drives the rotating shaft 3035 to rotate on the rotating frame 3034, the connecting support frame 2 and the solar cell panel 1 realize angle swing, so that the swing angle of the solar cell panel 1 is adjusted, the solar cell panel is suitable for sunlight irradiation conditions of different angles, and the conversion efficiency of the solar cell panel 1 is further improved.

In addition, the adjusting assembly 305 includes a rotating handle 3051, a driving wheel 3052, an idler 3053, an adjusting rod 3054 and a sliding hole 3055, wherein the rotating handle 3051 is inserted at a position of the back of the adjusting housing 301 opposite to the supporting frame 3023, the driving wheel 3052 is connected to an inner end of the rotating handle 3051, the idler 3053 is rotatably disposed at a back of the supporting frame 3023, the sliding hole 3055 is opened at a position of the supporting frame 3023 opposite to the idler 3053, one end of the adjusting rod 3054 is connected to the idler 3053, and the other end of the adjusting rod 3054 is slidably inserted at the sliding hole 3055. According to the invention, the rotary handle 3051 is inserted into the back of the adjusting shell 301, the driving wheel 3052 is sleeved on the rotary handle 3051, the idler wheel 3053 is sleeved at the end part of the supporting frame 3023 relative to the screw shaft A3031 and the screw shaft B3041, the driving wheel 3052 is in threaded connection with the idler wheels 3053 on two sides, the adjusting rod 3054 and the sliding hole 3055 are arranged on the outer sides of the two idler wheels 3053, so that the rotation or swing of the solar cell panel 1 can be adjusted by pulling the adjusting rod 3054 through the sliding hole 3055.

Example 2: the installation method of the novel solar panel rapid installation device comprises the following steps:

S1, mounting operation;

s101, firstly determining the shape of a balcony railing, if the balcony railing is cylindrical, arranging a connecting shaft 5031 on the inner wall of a shell 5011, connecting a limiting block 5032 and a deformation block 5033 on the connecting shaft 5031, deforming the limiting block 5032 when a side plate 5024 moves oppositely, wherein the limiting block 5032 is made of a bendable material, the limiting block 5032 drives the deformation block 5033, and a plurality of deformation blocks 5033 form a semi-cylinder shape due to the fact that the deformation block 5033 is trapezoidal and are used for wrapping the cylindrical railing;

S201, firstly determining the shape of a balcony railing, if the shape is square, arranging a connecting shaft 5031 on the inner wall of a shell 5011, connecting a limiting block 5032 and a deformation block 5033 on the connecting shaft 5031, deforming the limiting block 5032 when a side plate 5024 moves reversely, wherein the limiting block 5032 is made of a bendable material, the limiting block 5032 drives the deformation block 5033, and when the side plate 5024 is arranged at two ends of a sliding chute 5015, the limiting block 5032 is flattened, so that the deformation block 5033 is positioned on the same horizontal line to adapt to the balcony railing;

S2, adjusting operation;

If the solar panel 1 needs to be rotationally adjusted, firstly, a screw shaft a3031 is arranged on one of the support frames 3023, a rotating sleeve 3033 is arranged on the support base 3022 in a penetrating manner, the bottom end of the rotating sleeve 3033 is in meshed connection with the screw shaft a3031, the rotating sleeve 3033 is driven to rotate by the rotating screw shaft a3031, the rotating frame 3034 is driven to rotate by the rotating sleeve 3033, the rotating shaft 3035 is driven to rotate by the rotating frame 3034, and the connecting bracket 2 and the solar panel 1 are driven to rotate by the rotating shaft 3035;

S202, if the swing of the solar panel 1 needs to be adjusted, firstly, a spiral shaft B3041 is arranged on the other support frame 3023, a central shaft 3043 is arranged on the rotating sleeve 3033, a gear B3042 is arranged at the bottom end of the central shaft 3043, and the gear B3042 and the central shaft 3043 are driven to rotate through the connection of the gear B3042 and the spiral shaft B3041 when the spiral shaft B3041 rotates, the central shaft 3043 drives a straight gear 3044 to rotate, the straight gear 3044 is meshed with a bevel gear A3045 on the rotating frame 3034, the bevel gear B3046 rotates, and the bevel gear B3046 drives the rotating shaft 3035 to rotate on the rotating frame 3034, so that the connecting support 2 and the solar panel 1 realize the swing of an angle.

The embodiments of the present invention are disclosed as preferred embodiments, but not limited thereto, and those skilled in the art will readily appreciate from the foregoing description that various modifications and variations can be made without departing from the spirit of the present invention.

Claims (10)

1. The novel solar panel rapid installation device is characterized by comprising a solar panel (1), wherein a connecting support (2) is arranged at the bottom end of the solar panel (1), an adjusting mechanism (3) is connected to the bottom end of the connecting support (2), an installation support (4) is arranged at the bottom end of the adjusting mechanism (3), and an installation mechanism (5) is arranged at one end, far away from the adjusting mechanism (3), of the installation support (4);

The mounting mechanism (5) comprises a mounting shell (501), a sliding component (502) and a deformation component (503), wherein the mounting shell (501) is connected to one end of the mounting bracket (4) away from the adjusting mechanism (3), the sliding component (502) is connected to the mounting shell (501) in a sliding mode, and the deformation component (503) is arranged in the mounting shell (501) at a position opposite to the position of the sliding component (502).

2. The novel rapid solar cell panel mounting device according to claim 1, wherein the mounting case (501) comprises a case (5011), a hinge (5012), a locking block (5013), a locking hole (5014) and a sliding groove (5015), wherein the hinge (5012) is connected to the mounting bracket (4) at one end far away from the adjusting mechanism (3), the case (5011) is symmetrically hinged to the hinge (5012) at one end far away from the mounting bracket (4), the locking block (5013) is arranged at one end far away from the hinge (5012) of the case (5011), a plurality of locking holes (5014) are arranged on the locking block (5013), and the sliding groove (5015) is arranged at the position on the outer wall of the case (5011) corresponding to the sliding component (502).

3. The novel solar cell panel rapid installation device according to claim 2, wherein the sliding component (502) comprises a sliding block (5021), a connecting block (5022), a connecting hole (5023), a side plate (5024) and a limiting long hole (5025), the sliding block (5021) is slidably connected to the sliding groove (5015), the connecting block (5022) is connected to the top end of the sliding block (5021), the connecting hole (5023) is formed in the connecting block (5022), the side plates (5024) are symmetrically arranged at positions, opposite to the side face of the shell (5011), of the two ends of the connecting block (5022), the limiting long holes (5025) are symmetrically formed in a plurality of side plates (5024), and the two ends of the deformation component (503) are connected to the limiting long holes (5025).

4. The novel solar cell panel rapid installation device according to claim 3, wherein the deformation component (503) comprises a connecting shaft (5031), a limiting block (5032) and deformation blocks (5033), the connecting shaft (5031) is connected to the inner wall of the shell (5011), the limiting block (5032) is connected to the connecting shaft (5031) at a position opposite to the inner wall of the shell (5011), two ends of the limiting block (5032) are slidably inserted into the limiting long holes (5025), a plurality of deformation blocks (5033) are connected to the limiting block (5032) at positions opposite to the inner wall of the shell (5011), and the limiting block (5032) is in size adaptation with the limiting long holes (5025) and is of a structure with inclined surfaces on two sides.

5. The rapid solar panel mounting device according to claim 4, wherein the adjusting mechanism (3) comprises an adjusting housing (301), a supporting component (302), a rotating component (303), a swinging component (304) and an adjusting component (305), the adjusting housing (301) is connected to the bottom end of the connecting bracket (2) at a position opposite to the top end of the mounting bracket (4), the supporting component (302) is arranged inside the adjusting housing (301), the rotating component (303) is arranged on the supporting component (302), the swinging component (304) is arranged on the supporting component (302) at a position opposite to the rotating component (303), and the adjusting component (305) is arranged on the supporting component (302) at a position opposite to the back of the rotating component (303) and the swinging component (304).

6. The novel rapid solar panel mounting device according to claim 5, wherein the supporting component (302) comprises supporting columns (3021), supporting seats (3022) and supporting frames (3023), the supporting columns (3021) are symmetrically arranged inside the adjusting housing (301), the supporting seats (3022) are connected between the two supporting columns (3021), the supporting frames (3023) are symmetrically arranged on the supporting columns (3021), the rotating component (303) and the swing component (304) are arranged on the supporting seats (3022) in a penetrating mode, and the adjusting component (305) is arranged on the supporting frames (3023).

7. The rapid solar panel mounting device according to claim 6, wherein the rotating assembly (303) comprises a screw shaft a (3031), a gear a (3032), a rotating sleeve (3033), a rotating frame (3034) and a rotating shaft (3035), the screw shaft a (3031) is rotatably connected to the supporting frame (3023), the rotating sleeve (3033) is rotatably arranged on the supporting seat (3022) in a penetrating manner, the gear a (3032) is connected to the bottom end of the rotating sleeve (3033) at a position opposite to the screw shaft a (3031), the rotating frame (3034) is connected to the top end of the rotating sleeve (3033), the rotating shaft (3035) is rotatably connected to the rotating frame (3034), and the connecting bracket (2) is connected to the top end of the rotating shaft (3035).

8. The rapid mounting device of claim 7, wherein the swing assembly (304) comprises a screw shaft B (3041), a gear B (3042), a central shaft (3043), a spur gear (3044), a bevel gear a (3045) and a bevel gear B (3046), the screw shaft B (3041) is rotatably connected to another support frame (3023), the central shaft (3043) is rotatably arranged on the rotary sleeve (3033) in a penetrating manner, the gear B (3042) is rotatably connected to a position of a bottom end of the central shaft (3043) relative to the screw shaft B (3041), the spur gear (3044) is connected to a position of a top end of the central shaft (3043) relative to the rotary frame (3034), the bevel gear a (3045) is arranged at a position of the rotary frame (3034) relative to one side of the spur gear (3044), the bevel gear B (3046) is sleeved on the rotary shaft (3035) relative to the position of the bevel gear a (3045), and the bevel gear B (3045) is meshed with the bevel gear a (3045).

9. The novel solar panel rapid installation device according to claim 8, wherein the adjusting component (305) comprises a rotating handle (3051), a driving wheel (3052), an idler wheel (3053), an adjusting rod (3054) and a sliding hole (3055), the rotating handle (3051) is inserted at the position of the back of the adjusting shell (301) relative to the supporting frame (3023), the driving wheel (3052) is connected to the inner end of the rotating handle (3051), the idler wheel (3053) is rotatably arranged at the back of the supporting frame (3023), the sliding hole (3055) is arranged at the position of the supporting frame (3023) relative to the idler wheel (3053), one end of the adjusting rod (3054) is connected to the idler wheel (3053), and the other end of the adjusting rod (3054) is slidably inserted on the sliding hole (3055).

10. The method for installing a novel solar panel rapid installation device according to claim 9, comprising the steps of:

S1, mounting operation;

S101, firstly determining the shape of a balcony railing, if the balcony railing is cylindrical, arranging a connecting shaft (5031) on the inner wall of a shell (5011), connecting a limiting block (5032) and a deformation block (5033) on the connecting shaft (5031), deforming the limiting block (5032) when a side plate (5024) moves oppositely, wherein the limiting block (5032) is made of a bendable material, and the limiting block (5032) drives the deformation block (5033), and the deformation blocks (5033) are trapezoid, so that a plurality of deformation blocks (5033) form a semi-cylinder shape and are used for wrapping the cylindrical railing;

S201, firstly determining the shape of a balcony railing, if the balcony railing is square, arranging a connecting shaft (5031) on the inner wall of a shell (5011), connecting a limiting block (5032) and a deformation block (5033) on the connecting shaft (5031), enabling the limiting block (5032) to deform when a side plate (5024) moves reversely, enabling the limiting block (5032) to be made of a bendable material, enabling the limiting block (5032) to drive the deformation block (5033), and enabling the deformation block (5033) to be positioned on the same horizontal straight line so as to adapt to the balcony railing when the side plate (5024) is arranged at two ends of a sliding chute (5015);

S2, adjusting operation;

S201, when the solar cell panel (1) needs to be rotationally regulated, firstly, a screw shaft A (3031) is arranged on one of the supporting frames (3023), a rotating sleeve (3033) is arranged on the supporting seat (3022) in a penetrating mode, the bottom end of the rotating sleeve (3033) is connected with the screw shaft A (3031) in a meshed mode, the rotating sleeve A (3031) drives the rotating sleeve (3033) to rotate, the rotating sleeve (3033) drives the rotating frame (3034) to rotate, the rotating frame (3034) drives the rotating shaft (3035) to rotate, and the rotating shaft (3035) drives the connecting bracket (2) and the solar cell panel (1) to rotate;

S202, if the swing amplitude of the solar panel (1) needs to be adjusted, firstly, a spiral shaft (B3041) is arranged on the other supporting frame (3023), a central shaft (3043) is arranged on the rotating sleeve (3033), a gear B (3042) is arranged at the bottom end of the central shaft (3043), and the gear B (3042) is connected with the spiral shaft (B3041) through the connection of the gear B (3042), so that when the spiral shaft (B3041) rotates, the gear B (3042) and the central shaft (3043) are driven to rotate, the central shaft (3043) drives a straight gear (3044) to rotate, the straight gear (3044) is meshed with a bevel gear A (3045) on the rotating frame (3034), the bevel gear B (3046) drives the rotating shaft (3035) to rotate on the rotating frame (3034), and the connecting frame (2) and the solar panel (1) achieve the angle swing amplitude.