CN115072353A

CN115072353A - Plate storage and conveying device for testing photovoltaic module

Info

Publication number: CN115072353A
Application number: CN202210847804.XA
Authority: CN
Inventors: 周敏
Original assignee: Leapton Luminous Energy Changshu Co ltd
Current assignee: Leapton Luminous Energy Changshu Co ltd
Priority date: 2022-07-19
Filing date: 2022-07-19
Publication date: 2022-09-20

Abstract

The invention discloses a plate storage and feeding device for photovoltaic module tests, which comprises a conveying frame, plate bins and a plate feeding mechanism, wherein the conveying frame is used for conveying photovoltaic modules, the plate bins are arranged above one end of the conveying frame and are used for stacking and storing the photovoltaic modules, a plate outlet is formed in the lower part of one side of each plate bin, two groups of plate feeding mechanisms are arranged on the two sides of each plate bin and are used for pushing out the photovoltaic modules stacked in the plate bins one by one, each plate feeding mechanism comprises a push plate friction wheel which is horizontally and rotatably arranged, through holes are formed in the positions, below the two sides of each plate bin, of the push plate friction wheels and are communicated with the inner parts of the plate bins, elastic friction ribs are arranged on the outer walls of the push plate friction wheels and protrude out of the inner parts of the plate bins from the positions of the through holes, the photovoltaic modules are of plate-shaped structures, the invention is suitable for photovoltaic module production, and the device is used for carrying out plate feeding of the photovoltaic modules in a horizontal flat pushing mode, the effect of continuous and uninterrupted plate feeding detection is realized, and the detection speed and efficiency of the photovoltaic module are improved.

Description

Plate storage and conveying device for testing photovoltaic module

Technical Field

The invention belongs to the technical field of photovoltaic module production, and particularly relates to a plate storage and conveying device for photovoltaic module testing.

Background

The photovoltaic module is a solar cell module, because the output voltage of the single solar cell is low, and the electrodes of the unpackaged cells are easy to fall off due to the influence of the environment, a certain number of single cells are sealed into the photovoltaic module in a series-parallel connection mode to avoid the corrosion of the cell electrodes and interconnecting wires, and the photovoltaic module is divided into a crystalline silicon solar cell module and a thin film solar cell module according to the materials of the solar cells;

the plate storage and conveying device for the photovoltaic module test is a device which is used in the production test of the photovoltaic module and is used for storing and pushing the photovoltaic module into the detection equipment;

however, the existing board storing and feeding device is simple in structure, most of the existing board storing and feeding devices are pushed through a cylinder or a hydraulic telescopic rod, namely, the cylinder or the hydraulic telescopic rod is arranged below a board storing box, when the cylinder or the hydraulic telescopic rod operates, the bottommost photovoltaic module is pushed out of the board storing box, and the board feeding is realized.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides a plate storing and conveying device for a photovoltaic module test.

In order to achieve the purpose, the invention adopts the following technical scheme:

a plate storage and conveying device for testing a photovoltaic assembly comprises a conveying frame, plate bins and a plate conveying mechanism, wherein the conveying frame is used for conveying the photovoltaic assembly, the plate bins are installed above one end of the conveying frame and are used for stacking and storing the photovoltaic assembly in an overlapped mode, a plate outlet is formed in the lower portion of one side of each plate bin, two groups of plate conveying mechanisms are arranged on two sides of each plate bin and are used for pushing out the photovoltaic assemblies stacked in the plate bins one by one, each plate conveying mechanism comprises a push plate friction wheel which is installed in a horizontally rotating mode, through holes are formed in the positions, located on the push plate friction wheel, of the lower portions of two sides of each plate bin, the through holes are communicated with the interiors of the plate bins, elastic friction ribs are arranged on the outer wall of each push plate friction wheel and protrude out of the interiors of the plate bins from the positions of the through holes, the photovoltaic assemblies are of a plate-shaped structure, and when the device is used, the photovoltaic components to be tested are stacked and placed inside the board bin, when the board is fed, the push board friction wheels are located on two sides of the board bin, when the push board friction wheels rotate, the elastic friction ribs arranged on the outer walls of the push board friction wheels can extrude and clamp the photovoltaic components, when the push board friction wheels rotate, the photovoltaic components are pushed out from the board outlet through the friction force between the push board friction wheels and the photovoltaic components and the extrusion force between the elastic friction ribs and the photovoltaic components, after the push board friction wheels are pushed out, the upper photovoltaic components fall down when the push board friction wheels rotate until the elastic friction ribs are not in the board bin, then the push board friction wheels continue to rotate, continuous and uninterrupted board feeding is realized, the board storage and board feeding are completed, in the device, the board feeding of the photovoltaic components is carried out in a horizontal flat pushing mode, namely, the photovoltaic components stacked at the bottommost are pushed out of the board bin through the rotation of the horizontally arranged push board friction wheels, and the photovoltaic components in the whole board bin fall down after the bottommost photovoltaic components are pushed out, then, the plate is fed by the push plate again under the action of the push plate friction wheel, so that the effect of continuous and uninterrupted plate feeding detection is realized, and the detection speed and efficiency of the photovoltaic module are improved.

In a possible implementation mode, send trigger structure still includes lower mounting panel and last mounting panel, wherein, lower mounting panel set up in the top of push pedal friction pulley, go up mounting panel parallel mount in the top of lower mounting panel, go up the mounting panel with rotate on the lower mounting panel and install the pivot, vertical direction setting is followed in the pivot, the bottom of pivot with the axle center of push pedal friction pulley is connected, the top of going up the mounting panel is provided with the second motor, the output shaft of second motor with the top of pivot is connected, and when the second motor is when the operation, drives the pivot and rotates to it sends the board operation to drive the rotation of push pedal friction pulley.

In a possible implementation mode, the same group of the push plate friction wheels are provided with a plurality of push plate friction wheels which are arranged at equal intervals, and the photovoltaic modules are completely sent out of the plate bin under the combined action of the push plate friction wheels.

In a possible implementation mode, the second chain wheel is installed on the rotating shaft in a sleeved mode, the second chain wheel installed on the rotating shaft of the same group of push plate friction wheels is connected through the second chain in a transmission mode, when the second motor operates, one of the rotating shafts is driven to rotate, and all the rotating shafts rotate under the action of the second chain wheel and the second chain, so that all the push plate friction wheels in the same group rotate synchronously, and the photovoltaic modules are completely sent out of the plate bin.

In a possible implementation manner, the height of the plate outlet is a, the thickness of the photovoltaic module is h, wherein 2h is larger than or equal to a larger than h, and the plate outlet is pushed by only one photovoltaic module at each plate outlet due to the structural arrangement, so that the phenomenon that two adjacent photovoltaic modules are pushed out simultaneously is avoided, and the detection of the subsequent photovoltaic modules is facilitated.

In a possible implementation, every elasticity friction ribbing on the push pedal friction pulley all is provided with threely, three elasticity friction ribbing is annular array and distributes to the slope installation, when the push pedal friction pulley was rotatory, three elasticity friction ribbing can be in the outside in board storehouse in a position is whole, and when this position department, photovoltaic module received stopping of elasticity friction ribbing inadequately and falls.

In a possible implementation manner, the photovoltaic module conveying device further comprises a conveying mechanism which is arranged above the conveying frame and used for outputting photovoltaic modules, the conveying mechanism comprises a transmission shaft, a first chain wheel, a first chain and a first motor, wherein the transmission shaft is provided with a plurality of transmission shafts, the transmission shafts are rotatably arranged above the conveying frame in an equidistant mode, one end of each transmission shaft penetrates through and extends to the outer side of the conveying frame, the first chain wheel is sleeved at one end, located at the outer side of the conveying frame, of the transmission shaft, the first chain is sleeved on the first chain wheel, the first chain wheels on all the transmission shafts are in transmission connection, the first motor is fixedly arranged on one side of the conveying frame, an output shaft of the first motor is connected with one end of one of the transmission shafts, when the first motor operates, one of the transmission shafts is driven to rotate, and under the action of the first chain wheel and the first chain, all the transmission shafts rotate, the synchronous plate feeding function is realized.

In a possible implementation mode, support frames are installed below two ends of the conveying frame to play a role in supporting the conveying frame.

In a possible implementation mode, the transmission shaft is sleeved with the plate feeding roller shaft, the plate feeding roller shaft has the effect of increasing the friction force between the transmission shaft and the photovoltaic module, and the plate feeding process of the photovoltaic module is more stable and smooth by matching with the rotation of the friction wheel of the push plate.

The invention has the advantages that:

according to the invention, the photovoltaic components are conveyed in a horizontal flat pushing mode, namely, the photovoltaic components stacked at the bottommost are pushed out of the board bin by the rotation of the horizontally arranged push board friction wheel, the photovoltaic components in the whole board bin fall after the bottommost photovoltaic components are pushed out, and then the push board conveying is carried out again under the action of the push board friction wheel, so that the effect of continuous and uninterrupted board conveying detection is realized, the detection speed and efficiency of the photovoltaic components are improved, and meanwhile, the flat pushing mode is carried out through friction and extrusion force, so that the photovoltaic components are pushed more smoothly, and the photovoltaic components are not easily damaged.

Drawings

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

FIG. 2 is a schematic view of another embodiment of the present invention;

FIG. 3 is a schematic view of the photovoltaic module of the present invention after storage;

fig. 4 is a partial structural schematic diagram of the present invention.

Reference numerals: 1. a board bin; 2. a push plate friction wheel; 3. elastic friction ribs; 4. a lower mounting plate; 5. an upper mounting plate; 6. a carriage; 7. a support frame; 8. a first motor; 9. a plate-feeding roller shaft; 10. a drive shaft; 11. a first sprocket; 12. a first chain; 13. a second motor; 14. a second sprocket; 15. a second chain; 16. a through hole; 17. a rotating shaft; 18. and (4) a plate outlet.

Detailed Description

The following further describes a specific embodiment of the plate storing and conveying device for testing a photovoltaic module according to the present invention with reference to fig. 1 to 4. The plate storing and conveying device for the photovoltaic module test is not limited to the description of the following embodiments.

Example 1:

the embodiment provides a concrete structure of a plate storage and conveying device for testing a photovoltaic assembly, which comprises a conveying frame 6, a plate bin 1 and a plate conveying mechanism, wherein the conveying frame 6 is used for conveying the photovoltaic assembly, the plate bin 1 is installed above one end of the conveying frame 6 and is used for stacking and storing the photovoltaic assembly, a plate outlet 18 is formed below one side of the plate bin 1, two groups of plate conveying mechanisms are arranged on two sides of the plate bin 1 respectively and are used for pushing out the photovoltaic assembly stacked in the plate bin 1 one by one, the plate conveying mechanism comprises a push plate friction wheel 2 which is horizontally and rotatably installed, through holes 16 are formed in the positions, below two sides of the plate bin 1, of the push plate friction wheel 2, the through holes 16 are communicated with the inside of the plate bin 1, elastic friction ribs 3 are arranged on the outer wall of the push plate friction wheel 2, and the elastic friction ribs 3 protrude out of the inside of the plate bin 1 from the positions of the through holes 16, the photovoltaic module is of a plate-shaped structure.

By adopting the technical scheme:

when the device is used, firstly, photovoltaic components to be tested are stacked and placed in the board bin 1, when the board is fed, firstly, the push board friction wheels 2 are positioned at two sides of the board bin 1, when the push board friction wheels 2 rotate, the elastic friction ribs 3 arranged on the outer walls of the push board friction wheels 2 can extrude and clamp the photovoltaic components, and when the push board friction wheels 2 rotate, the photovoltaic components are pushed out from the board outlet 18 through the friction force between the push board friction wheels 2 and the photovoltaic components and the extrusion force between the elastic friction ribs 3 and the photovoltaic components, after the push board friction wheels 2 are pushed out, the upper photovoltaic components fall down when the push board friction wheels 2 rotate until the elastic friction ribs 3 are not in the board bin 1, then the push board friction wheels 2 continue to rotate to realize continuous and uninterrupted board feeding, the board storage and board feeding are completed, in the device, the board feeding of the photovoltaic components is carried out in a horizontal flat push mode, namely, the horizontally arranged push board friction wheels 2 rotate, the photovoltaic module who will put things in good order at the bottommost pushes out board storehouse 1, and the photovoltaic module whereabouts in whole board storehouse 1 after the photovoltaic module of bottommost pushes out, then carries out the push pedal again under the effect of push pedal friction pulley 2 and send the board, just so has realized the effect that sends the board detection in succession incessant, has promoted photovoltaic module's detection speed and efficiency.

Example 2

On the basis of embodiment 1, in this embodiment, the plate conveying mechanism further includes a lower mounting plate 4 and an upper mounting plate 5, wherein the lower mounting plate 4 is disposed above the push plate friction wheel 2, the upper mounting plate 5 is mounted above the lower mounting plate 4 in parallel, a rotating shaft 17 is rotatably mounted on the upper mounting plate 5 and the lower mounting plate 4, the rotating shaft 17 is disposed along a vertical direction, the bottom of the rotating shaft 17 is connected with the axis of the push plate friction wheel 2, a second motor 13 is disposed on the top of the upper mounting plate 5, and an output shaft of the second motor 13 is connected with the top of the rotating shaft 17.

The same group of push plate friction wheels 2 are provided with a plurality of, and a plurality of push plate friction wheels 2 equidistance are arranged, and a plurality of push plate friction wheels 2 combined action send out the photovoltaic module completely board storehouse 1.

The second chain wheel 14 is sleeved on the rotating shaft 17, the second chain wheel 14 mounted on the rotating shaft 17 of the same group of push plate friction wheels 2 is in transmission connection through the second chain 15, when the second motor 13 operates, one of the rotating shafts 17 is driven to rotate, and under the action of the second chain wheel 14 and the second chain 15, all the rotating shafts 17 rotate, so that all the push plate friction wheels 2 in the same group rotate synchronously, and the photovoltaic modules are completely sent out of the plate bin 1.

The height of the plate outlet 18 is a, the thickness of the photovoltaic module is h, and 2h ≧ a > h.

Elastic friction rib 3 on every push pedal friction wheel 2 all is provided with threely, and three elastic friction rib 3 is the annular array and distributes to the slope installation, when push pedal friction wheel 2 was rotatory, three elastic friction rib 3 can be in the outside that a position is whole to be located board storehouse 1, and when this position department, photovoltaic module received stopping of elastic friction rib 3 inadequately and falls.

By adopting the technical scheme:

when the second motor 13 is in operation, the rotating shaft 17 is driven to rotate, so that the push plate friction wheel 2 is driven to rotate to carry out plate conveying operation, the height of the plate outlet 18 in the device is a, the thickness of the photovoltaic module is h, wherein 2h is larger than or equal to a & gth, the structure enables only one photovoltaic module to push out the plate outlet 18 when the plate is discharged at each time, the phenomenon that two adjacent photovoltaic modules are simultaneously pushed out is avoided, and the follow-up detection of the photovoltaic modules is facilitated.

Example 3

On the basis of embodiment 1, in this embodiment, still include conveying mechanism, it sets up in the top of carriage 6 for export photovoltaic module, conveying mechanism includes transmission shaft 10, first sprocket 11, first chain 12 and first motor 8, wherein, transmission shaft 10 is provided with a plurality of, the equidistance rotates to be installed in the top of carriage 6, its one end passes and extends to the outside of carriage 6, first sprocket 11 cup joints the one end that transmission shaft 10 is located the outside of carriage 6, first chain 12 cup joints on first sprocket 11, with the transmission connection of all first sprocket 11 on the transmission shaft 10, first motor 8 fixed mounting is in one side of carriage 6, the output shaft of first motor 8 is connected with the one end of one of them transmission shaft 10.

And supporting frames 7 are arranged below the two ends of the conveying frame 6 and play a role in supporting the conveying frame 6.

The transmission shaft 10 is sleeved with the plate feeding roller shaft 9, the plate feeding roller shaft 9 plays a role in increasing the friction force between the transmission shaft 10 and the photovoltaic module, and the plate feeding process of the photovoltaic module is more stable and smooth by matching with the rotation of the push plate friction wheel 2.

By adopting the technical scheme:

when the first motor 8 operates, one of the transmission shafts 10 is driven to rotate, and under the action of the first chain wheel 11 and the first chain 12, all the transmission shafts 10 rotate, so that the synchronous plate conveying effect is realized.

With reference to embodiment 1 to embodiment 3 and with reference to fig. 1 to 3, the working principle of the present application is as follows:

when the device is used, firstly, photovoltaic modules to be tested are stacked and placed in a plate bin 1, when a plate is fed, firstly, the second motor 13 operates to drive one of the rotating shafts 17 to rotate, all the rotating shafts 17 rotate under the action of the second chain wheel 14 and the second chain 15, so that all the push plate friction wheels 2 in the same group synchronously rotate, the photovoltaic modules are completely fed out of the plate bin 1, the photovoltaic modules are pushed out from a plate outlet 18 through the friction force between the elastic friction ribs 3 and the photovoltaic modules and the extrusion force between the elastic friction ribs 3 and the photovoltaic modules, after being pushed out, the upper photovoltaic modules fall down when the push plate friction wheels 2 rotate until the elastic friction ribs 3 are not in the plate bin 1, at the moment, the push plate friction wheels 2 continue to rotate to realize continuous and uninterrupted plate feeding, meanwhile, the first motor 8 operates to drive all the transmission shafts 10 to rotate under the action of the first chain wheel 11 and the first chain 12, and the photovoltaic module is transferred out in a matching manner, and the plate storage and plate conveying are completed.

The foregoing is a more detailed description of the invention in connection with specific preferred embodiments and it is not intended that the invention be limited to these specific details. For those skilled in the art to which the invention pertains, several simple deductions or substitutions can be made without departing from the spirit of the invention, and all shall be considered as belonging to the protection scope of the invention.

Claims

1. The utility model provides a test of photovoltaic module is with depositing board and sending board device which characterized in that: the method comprises the following steps:

a transport rack (6) for transporting the photovoltaic modules;

the plate bin (1) is mounted above one end of the conveying frame (6) and used for stacking and storing photovoltaic modules, a plate outlet (18) is formed in the lower portion of one side of the plate bin (1), the height of the plate outlet (18) is a, the thickness of each photovoltaic module is h, and 2h is ≧ a > h;

the two groups of plate conveying mechanisms are respectively arranged on two sides of the plate bin (1) and are used for pushing out the photovoltaic modules stacked in the plate bin (1) one by one;

the plate feeding mechanism comprises a push plate friction wheel (2) which is horizontally and rotatably installed, through holes (16) are formed in the positions, located on the push plate friction wheel (2), of the lower portions of the two sides of the plate bin (1), the through holes (16) are communicated with the inside of the plate bin (1), elastic friction ribs (3) are arranged on the outer wall of the push plate friction wheel (2), and the elastic friction ribs (3) protrude out of the inside of the plate bin (1) through the positions of the through holes (16).

2. The board storing and feeding device for testing photovoltaic modules according to claim 1, wherein: send trigger to construct and still include:

the lower mounting plate (4) is arranged above the push plate friction wheel (2);

an upper mounting plate (5) mounted in parallel above the lower mounting plate (4);

wherein, go up mounting panel (5) with it installs pivot (17) to rotate on lower mounting panel (4), vertical direction setting is followed in pivot (17), the bottom of pivot (17) with the axle center of push pedal friction pulley (2) is connected, the top of going up mounting panel (5) is provided with second motor (13), the output shaft of second motor (13) with the top of pivot (17) is connected.

3. The plate storing and conveying device for the photovoltaic module test as claimed in claim 2, wherein: the same group of the push plate friction wheels (2) are provided with a plurality of push plate friction wheels (2) in equal distance.

4. The plate storing and conveying device for the photovoltaic module test as claimed in claim 2, wherein: the rotating shaft (17) is sleeved with a second chain wheel (14), and the second chain wheel (14) arranged on the rotating shaft (17) of the same group of push plate friction wheels (2) is in transmission connection through a second chain (15).

5. The plate storing and conveying device for the photovoltaic module test as claimed in claim 1, wherein: every elasticity friction ribbing (3) on push pedal friction pulley (2) all are provided with threely, three elasticity friction ribbing (3) are the annular array and distribute to the slope installation.

6. The plate storing and conveying device for the photovoltaic module test as claimed in claim 1, wherein: still include conveying mechanism, it sets up in the top of carriage (6) for export photovoltaic module, conveying mechanism includes:

a plurality of transmission shafts (10) are arranged, are rotatably arranged above the conveying frame (6) at equal intervals, and one end of each transmission shaft penetrates through and extends to the outer side of the conveying frame (6);

the first chain wheel (11) is sleeved at one end, located on the outer side of the conveying frame (6), of the transmission shaft (10);

the first chain (12) is sleeved on the first chain wheel (11) and is used for driving and connecting the first chain wheels (11) on all the transmission shafts (10);

and the first motor (8) is fixedly arranged on one side of the conveying frame (6), and an output shaft of the first motor (8) is connected with one end of one of the transmission shafts (10).

7. The plate storing and conveying device for the photovoltaic module test as claimed in claim 6, wherein: and support frames (7) are arranged below two ends of the conveying frame (6).

8. The plate storing and conveying device for the photovoltaic module test as claimed in claim 6, wherein: and a plate feeding roll shaft (9) is sleeved on the transmission shaft (10).