CN211480069U

CN211480069U - Discharging and heat dissipating device of solar photovoltaic assembly laminating machine

Info

Publication number: CN211480069U
Application number: CN201922020702.7U
Authority: CN
Inventors: 沈兴祥; 谢健; 林志松
Original assignee: Jiangsu Chuangqi Renewable Co ltd
Current assignee: Jiangsu Chuangqi Renewable Co ltd
Priority date: 2019-11-21
Filing date: 2019-11-21
Publication date: 2020-09-11
Anticipated expiration: 2029-11-21

Abstract

The utility model discloses a solar PV modules laminator ejection of compact heat abstractor, include: the solar photovoltaic module temporary storage device comprises a rack, a plurality of conveying rollers driven by a motor and movably supported at intervals in sequence from front to back along the conveying direction of a solar photovoltaic module between the left side plate and the right side plate of the rack, all the conveying rollers jointly form a conveying platform for conveying the solar photovoltaic module, a photovoltaic module temporary storage mechanism capable of supporting and supporting the solar photovoltaic module on the conveying platform is further arranged in the rack, a rear door capable of opening or closing the discharging end of the conveying platform is arranged on the rack on the rear side of the conveying platform, a plurality of air coolers for blowing and radiating the solar photovoltaic module placed on the conveying platform and the photovoltaic module temporary storage mechanism are respectively arranged on the racks on the rear door and the left side and the right side of the conveying platform, a wind collecting cover is arranged on the rack above the conveying platform, and the wind collecting cover is. The utility model has the advantages of good heat dissipation effect.

Description

Discharging and heat dissipating device of solar photovoltaic assembly laminating machine

Technical Field

The utility model relates to a solar PV modules laminator technical field, concretely relates to solar PV modules laminator ejection of compact heat abstractor.

Background

The solar 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. The solar photovoltaic module generally comprises toughened glass, EVA (ethylene vinyl acetate copolymer), a battery sheet layer, EVA, glass fiber and a back plate which are sequentially laminated from bottom to top. In the production of the solar photovoltaic module, the lamination process is an important process, and is to place the solar photovoltaic module with the laminated layer in a solar photovoltaic module laminator, pump out the air in the module by vacuumizing, and then heat to melt the EVA to bond the battery, the glass and the back plate together. After the solar photovoltaic module is laminated, the solar photovoltaic module needs to be firstly cooled by a discharging cooling device, and then can be sent to the next procedure for continuous production. The discharging heat dissipation device used at present is a belt conveyor, and the laminated solar photovoltaic module moves and conveys on the belt conveyor to dissipate heat naturally. The discharging heat dissipation device has the following defects: (1) the laminated solar photovoltaic module cannot be effectively cooled, the cooling speed is low, the cooling time is long, the production time of the module is prolonged, and the production efficiency is reduced; (2) the heat dissipation treatment can be carried out on only one laminated solar photovoltaic module at a time, and the production efficiency is low.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a solar PV modules laminator ejection of compact heat abstractor that the radiating effect is good.

In order to achieve the above purpose, the utility model adopts the following technical scheme: solar PV modules laminator ejection of compact heat abstractor includes: the solar photovoltaic module temporary storage device comprises a rack, a plurality of conveying rollers driven by a motor and movably supported at intervals in sequence from front to back along the conveying direction of a solar photovoltaic module between the left side plate and the right side plate of the rack, all the conveying rollers jointly form a conveying platform for conveying the solar photovoltaic module, a photovoltaic module temporary storage mechanism capable of supporting and supporting the solar photovoltaic module on the conveying platform is further arranged in the rack, a rear door capable of opening or closing the discharging end of the conveying platform is arranged on the rack on the rear side of the conveying platform, a plurality of air coolers for blowing and radiating the solar photovoltaic module placed on the conveying platform and the photovoltaic module temporary storage mechanism are respectively arranged on the racks on the rear door and the left side and the right side of the conveying platform, a wind collecting cover is arranged on the rack above the conveying platform, and the wind collecting cover is.

Further, aforementioned solar PV modules laminator ejection of compact heat abstractor, wherein: the specific mounting structure of back door does: the upper end of back door hinges in the frame through the pivot of controlling the trend, is connected with telescopic cylinder between back door and frame, and telescopic cylinder's cylinder body is articulated mutually with the lower extreme of back door, and telescopic cylinder's piston rod is articulated mutually with the frame, and when telescopic cylinder's piston rod stretched out or retracted, can drive the back door and revolve the rotation of axes and open or close conveying platform's discharge end.

Further, aforementioned solar PV modules laminator ejection of compact heat abstractor, wherein: the rack below the conveying platform is provided with a plurality of air coolers for blowing and radiating the solar photovoltaic modules placed on the conveying platform and the temporary photovoltaic module storage mechanism.

Further, aforementioned solar PV modules laminator ejection of compact heat abstractor, wherein: the structure of photovoltaic module temporary storage mechanism is: the solar photovoltaic module support device is characterized in that guide rail sets are vertically arranged on the frames of the left side and the right side of the conveying platform respectively, a lifting seat is arranged on each guide rail set of each side in a sliding mode respectively, each lifting seat is driven by a lifting driving assembly to move up and down along the corresponding guide rail set respectively, a plurality of vertical arms are sequentially installed at the bottom of each lifting seat from front to back at intervals, each vertical arm is aligned with a gap between two conveying rollers downwards respectively, the vertical arms on the two lifting seats correspond to one another one by one, a plurality of carrier rollers are sequentially movably supported at intervals from top to bottom between each pair of corresponding vertical arms, and the carrier rollers on all the vertical arms jointly form a plurality of layers of support and temporary storage platforms for supporting.

Further, aforementioned solar PV modules laminator ejection of compact heat abstractor, wherein: the structure of the lifting driving component comprises: the motor is arranged on the machine frame above the corresponding lifting seat, the output shaft of the motor is coaxially connected with a lead screw, the lead screw downwards penetrates through the corresponding lifting seat below and is in threaded connection with the lifting seat, and the motor drives the lead screw to rotate forwards or backwards so as to drive the corresponding lifting seat to move upwards or downwards along the corresponding guide rail group.

Further, aforementioned solar PV modules laminator ejection of compact heat abstractor, wherein: a filter is arranged in the induced draft tube.

Through the implementation of the above technical scheme, the beneficial effects of the utility model are that: (1) the laminated solar photovoltaic module can be effectively cooled, the cooling effect is good, the cooling speed is high, the cooling time is short, the production time of the module is shortened, and the production efficiency is improved; (2) the solar photovoltaic module after a plurality of layers of lamination can be subjected to heat dissipation treatment at each time, and the production efficiency is further improved.

Drawings

Fig. 1 is a schematic structural diagram of a discharging and heat dissipating device of a solar photovoltaic module laminating machine according to the present invention.

Fig. 2 is a schematic view of the position relationship between the rear door and the conveying platform in the right-hand direction of fig. 1.

Fig. 3 is a schematic view of the positional relationship between the conveying roller and the idler in the top view of fig. 1.

Fig. 4 is a schematic structural diagram of the temporary storage mechanism of the photovoltaic module shown in fig. 3.

Fig. 5 is a schematic structural view of the section a-a shown in fig. 4.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

As shown in fig. 1, 2, 3, 4 and 5, the discharging and heat dissipating device of a solar photovoltaic module laminating machine includes: a frame 1, a plurality of conveying rollers 4 driven by a motor to rotate are movably supported between a left side plate 2 and a right side plate 3 of the frame 1 at intervals from front to back in sequence along the conveying direction of the solar photovoltaic module, all the conveying rollers 4 jointly form a conveying platform for carrying the solar photovoltaic module, a photovoltaic module temporary storage mechanism 5 capable of supporting and carrying the solar photovoltaic module on the conveying platform is also arranged in the frame 1, a rear door 6 capable of opening or closing the discharging end of the conveying platform is arranged on the frame 1 at the rear side of the conveying platform, a plurality of air coolers 7 for blowing and radiating the solar photovoltaic module placed on the conveying platform and the photovoltaic module temporary storage mechanism 5 are respectively arranged on the rear door 6 and the frames 1 at the left and right sides of the conveying platform, a wind collecting cover 8 is arranged on the frame 1 above the conveying platform, and the wind collecting cover 8 is connected with a draught fan 10 through an induced draft tube 9, in this embodiment, a filter 11 is disposed in the induced draft tube 9, the filter 11 can filter hot air induced by the induced draft fan 10, and the hot air filtered by the filter 11 is clean and pollution-free hot air, so that no environmental pollution is caused after the hot air is discharged;

in the present embodiment, the specific mounting structure of the rear door 6 is: the upper end of the back door 6 is hinged on the frame 1 through a rotating shaft 12 moving left and right, a telescopic cylinder 13 is connected between the back door 6 and the frame 1, the cylinder body of the telescopic cylinder 13 is hinged with the lower end of the back door 6, the piston rod of the telescopic cylinder 13 is hinged with the frame 1, when the piston rod of the telescopic cylinder 13 extends or retracts, the rear door 6 can be driven to rotate around the rotating shaft 12 to open or close the discharge end of the conveying platform, when the solar photovoltaic module on the conveying platform and the temporary storage mechanism 5 of the photovoltaic module needs to be blown and cooled, the piston rod of the telescopic cylinder 13 is retracted inwards to drive the rear door 6 to rotate around the rotating shaft 12 to close the discharge end of the conveying platform, and at the moment, the air ports of the air coolers 7 on the rear door 6 are inwards just opposite to the solar photovoltaic modules placed on the conveying platform and the temporary storage mechanism 5 of the photovoltaic modules, so that the heat dissipation effect of the laminated solar photovoltaic modules can be improved; after the solar photovoltaic module is completely radiated, the piston rod of the telescopic cylinder 13 extends outwards to drive the rear door 6 to rotate around the rotating shaft 12 to open the discharge end of the conveying platform, and the conveying platform can output the radiated solar photovoltaic module to a subsequent process from the discharge end; in this embodiment, a plurality of air coolers 7 for blowing and dissipating heat of the solar photovoltaic modules placed on the conveying platform and the temporary photovoltaic module storage mechanism 5 are arranged on the rack 1 below the conveying platform, so that the heat dissipation effect of the laminated solar photovoltaic modules can be further improved;

in this embodiment, the temporary storage mechanism 5 of the photovoltaic module has the structure: a left guide rail group 51 is vertically arranged on the rack 1 on the left side of the conveying platform, a left lifting seat 52 is arranged on the left guide rail group 51 in a sliding manner, the left lifting seat 52 moves up and down along the left guide rail group 51 under the driving of a lifting driving assembly, a plurality of first vertical arms 53 are sequentially arranged at intervals from front to back at the bottom of the left lifting seat 52, each first vertical arm 53 is respectively and downwards aligned with a gap between two conveying rollers 4, a right guide rail group is vertically arranged on the rack 1 on the right side of the conveying platform, a right lifting seat 54 is arranged on the right guide rail group in a sliding manner, the left lifting seat 54 moves up and down along the right guide rail group under the driving of the lifting driving assembly, a plurality of second vertical arms 55 are sequentially arranged at intervals from front to back at the bottom of the right lifting seat 54, and each second vertical arm 55 is respectively and downwards; the first vertical arm 53 on the left lifting seat 52 and the second vertical arm 55 on the right lifting seat 54 are in left-right one-to-one correspondence, a plurality of carrier rollers 56 are sequentially and movably supported between each pair of corresponding first vertical arm 53 and second vertical arm 55 from top to bottom at intervals, the carrier rollers 56 on all the vertical arms jointly form a plurality of layers of supporting and temporary storage platforms for supporting solar photovoltaic modules, in the embodiment, the carrier rollers 56 on all the vertical arms jointly form five layers of supporting and temporary storage platforms, and the five layers of supporting and temporary storage platforms sequentially comprise a first supporting and temporary storage platform, a second supporting and temporary storage platform, a third supporting and temporary storage platform, a fourth supporting and temporary storage platform and a fifth supporting and temporary storage platform from top to bottom, so that the photovoltaic module temporary storage mechanism is simple in structure and convenient to install and maintain;

in the present embodiment, since the structures of the elevation driving assembly for driving the left elevation base 52 to move up and down and the elevation driving assembly for driving the right elevation base 54 to move up and down are the same, the structure of the elevation driving assembly for driving the left elevation base 52 to move up and down includes: the first motor 57 is mounted on the frame 1 above the left lifting seat 52, the output shaft of the first motor 57 is coaxially connected with a first lead screw 58, the first lead screw 58 downwards penetrates through the left lifting seat 52 below and is in threaded connection with the left lifting seat 52, and the first motor 57 drives the first lead screw 58 to rotate forwards or backwards, so that the left lifting seat 52 is driven to move upwards or downwards along the left guide rail group 51; the structure of the elevation driving assembly for driving the right elevation base 54 to move up and down includes: the second motor 59 is arranged on the frame 1 above the right lifting seat 54, the output shaft of the second motor 59 is coaxially connected with a second screw rod 510, the second screw rod 510 downwards penetrates through the right lifting seat 54 below and is in threaded connection with the right lifting seat 54, and the second motor 59 drives the second screw rod 510 to rotate forwards or backwards, so that the right lifting seat 54 is driven to move upwards or downwards along the right guide rail group; the lifting driving assembly is simple in structure and convenient to install and maintain;

the working principle of the utility model is as follows:

firstly, driving a left lifting seat 52 and a right lifting seat 54 to synchronously move downwards through each lifting driving component until the uppermost first supporting temporary storage platform is positioned below the conveying platform, then retracting a piston rod of a telescopic cylinder 13 inwards to drive a rear door 6 to rotate around a rotating shaft 12 to close the discharge end of the conveying platform;

then the conveying platform is enabled to bear a laminated solar photovoltaic assembly output by the laminating machine, when the conveying platform conveys the borne solar photovoltaic assembly to the position right above the first supporting and temporary storage platform, the conveying of the solar photovoltaic assembly is stopped, then the left lifting seat 52 and the right lifting seat 54 are driven to synchronously move upwards through the lifting driving assemblies, each layer of supporting and temporary storage platform is synchronously driven to move upwards, until the first supporting and temporary storage platform moves to the position above the conveying platform and the second supporting and temporary storage platform is positioned below the conveying platform, the movement of the supporting and temporary storage platform by the lifting driving assemblies is stopped, and at the moment, the first supporting and temporary storage platform can support the solar photovoltaic assembly on the conveying platform; repeating the above actions until the first supporting temporary storage platform, the second supporting temporary storage platform, the third supporting temporary storage platform, the fourth supporting temporary storage platform and the fifth supporting temporary storage platform are all moved to the upper part of the conveying platform and respectively temporarily store one laminated solar photovoltaic module; then the conveying platform receives a laminated solar photovoltaic assembly output by the laminating machine, and the conveying of the solar photovoltaic assembly is stopped until the solar photovoltaic assembly moves to the position above the fifth supporting temporary storage platform at the lowest layer; at the moment, 6 laminated solar photovoltaic modules to be radiated are temporarily stored in the device;

in the process of transferring and conveying the laminated solar photovoltaic modules by the conveying platform and the temporary storage mechanism of the photovoltaic modules, all the air coolers 7 and the draught fans 10 are started, each air cooler 7 can simultaneously blow cold air to dissipate heat of the solar photovoltaic modules placed on the conveying platform and each layer of supporting temporary storage platform from different directions, and meanwhile, the draught fans 10 can lead hot air to the outside through the air collecting cover 8, the induced air pipes 9 and the filters 11, so that the heat dissipation speed of the solar photovoltaic modules is greatly increased;

after each solar photovoltaic module is cooled, the piston rod of the telescopic cylinder 13 extends outwards to drive the rear door 6 to rotate around the rotating shaft 12 to open the discharge end of the conveying platform;

then the conveying platform outputs the cooled solar photovoltaic components on the conveying platform, after the solar photovoltaic components are output, the left lifting seat 52 and the right lifting seat 54 are driven by each lifting driving component to synchronously move downwards, each layer of supporting and temporary storage platform is synchronously driven to move downwards until the fifth supporting and temporary storage platform moves to the lower part of the conveying platform and the fourth supporting and temporary storage platform is positioned above the conveying platform, the movement of each lifting driving component to the supporting and temporary storage platform is stopped, at the moment, the solar photovoltaic components on the fifth supporting and temporary storage platform fall on the conveying platform, and then the conveying platform outputs the cooled solar photovoltaic components falling on the conveying platform; and repeating the actions until the solar photovoltaic modules on the fifth supporting temporary storage platform, the fourth supporting temporary storage platform, the third supporting temporary storage platform, the second supporting temporary storage platform and the first supporting temporary storage platform sequentially fall to the conveying platform and are output by the conveying platform.

The utility model has the advantages that: (1) the laminated solar photovoltaic module can be effectively cooled, the cooling effect is good, the cooling speed is high, the cooling time is short, the production time of the module is shortened, and the production efficiency is improved; (2) the solar photovoltaic module after a plurality of layers of lamination can be subjected to heat dissipation treatment at each time, and the production efficiency is further improved.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention in any way, and any modifications or equivalent changes made in accordance with the technical spirit of the present invention are also within the scope of the present invention.

Claims

1. Solar PV modules laminator ejection of compact heat abstractor includes: the frame, its characterized in that: a plurality of conveying rollers driven by a motor to rotate are movably supported at intervals in sequence from front to back along the conveying direction of the solar photovoltaic assembly between the left side plate and the right side plate of the rack, all the conveying rollers jointly form a conveying platform for carrying the solar photovoltaic assembly, a photovoltaic assembly temporary storage mechanism capable of supporting and holding the solar photovoltaic assembly on the conveying platform is further arranged in the rack, a rear door capable of opening or closing the discharging end of the conveying platform is arranged on the rack at the rear side of the conveying platform, a plurality of air coolers for blowing and radiating the solar photovoltaic assembly placed on the conveying platform and the photovoltaic assembly temporary storage mechanism are respectively arranged on the racks at the rear door and the left side and the right side of the conveying platform, a wind collecting cover is arranged on the rack above the conveying platform and is connected with an induced draft fan through an induced draft tube.

2. The discharging and heat dissipating device of a solar photovoltaic module laminating machine according to claim 1, wherein: the specific mounting structure of back door does: the upper end of back door hinges in the frame through the pivot of controlling the trend, is connected with telescopic cylinder between back door and frame, and telescopic cylinder's cylinder body is articulated mutually with the lower extreme of back door, and telescopic cylinder's piston rod is articulated mutually with the frame, and when telescopic cylinder's piston rod stretched out or retracted, can drive the back door and revolve the rotation of axes and open or close conveying platform's discharge end.

3. The discharging and heat dissipating device of the solar photovoltaic module laminating machine according to claim 1 or 2, wherein: the rack below the conveying platform is provided with a plurality of air coolers for blowing and radiating the solar photovoltaic modules placed on the conveying platform and the temporary photovoltaic module storage mechanism.

4. The discharging and heat dissipating device of a solar photovoltaic module laminating machine according to claim 1, wherein: the structure of photovoltaic module temporary storage mechanism is: the solar photovoltaic module support device is characterized in that guide rail sets are vertically arranged on the frames of the left side and the right side of the conveying platform respectively, a lifting seat is arranged on each guide rail set of each side in a sliding mode respectively, each lifting seat is driven by a lifting driving assembly to move up and down along the corresponding guide rail set respectively, a plurality of vertical arms are sequentially installed at the bottom of each lifting seat from front to back at intervals, each vertical arm is aligned with a gap between two conveying rollers downwards respectively, the vertical arms on the two lifting seats correspond to one another one by one, a plurality of carrier rollers are sequentially movably supported at intervals from top to bottom between each pair of corresponding vertical arms, and the carrier rollers on all the vertical arms jointly form a plurality of layers of support and temporary storage platforms for supporting.

5. The discharging and heat dissipating device of a solar photovoltaic module laminating machine according to claim 4, wherein: the structure of the lifting driving component comprises: the motor is arranged on the machine frame above the corresponding lifting seat, the output shaft of the motor is coaxially connected with a lead screw, the lead screw downwards penetrates through the corresponding lifting seat below and is in threaded connection with the lifting seat, and the motor drives the lead screw to rotate forwards or backwards so as to drive the corresponding lifting seat to move upwards or downwards along the corresponding guide rail group.

6. The discharging and heat dissipating device of a solar photovoltaic module laminating machine according to claim 1, wherein: a filter is arranged in the induced draft tube.