CN215203907U - Continuous cooling device for laminated solar cell panel - Google Patents

Abstract

A continuous cooling device for laminated solar panels comprises a longitudinal belt conveying mechanism and a transverse belt conveying mechanism; the longitudinal belt conveying mechanism comprises a first support, a first belt conveyor is arranged on the first support, and a plurality of groups of first belt conveyors are coaxially arranged and driven by a first motor; the transverse belt conveying mechanism comprises a second support, an air cylinder is mounted on the second support, the driving end of the air cylinder is connected with a third support, a plurality of groups of second belt conveyors and transmission wheel assemblies are mounted at the upper end of the third support, the plurality of groups of second belt conveyors are transversely arranged, and the plurality of groups of transmission wheel assemblies are longitudinally arranged; the second belt conveyor and the transmission wheel assembly are driven by a synchronous belt transmission mechanism; and a plurality of groups of fans are arranged on the third support, and the air outlets of the fans face upwards. The utility model provides a pair of continuous cooling device behind solar cell panel lamination can be to continuous cooling and switching-over behind the solar cell panel lamination.

Description

Continuous cooling device for laminated solar cell panel

Technical Field

The utility model relates to a solar cell panel processing equipment, especially a continuous cooling device behind solar cell panel lamination.

Background

The solar cell panel comprises six layers of toughened glass, an upper EVA (ethylene vinyl acetate copolymer), a cell, a lower EVA and a back plate from top to bottom. And (5) after the processing is finished, finally, putting the frame on the warehouse, and detecting to be qualified. And cooling is needed after vacuum-pumping hot-press molding of the EVA and the cell. The existing solar panel cooling devices are generally based on solar panel cooling during use, and few devices are concerned with continuous solar panel cooling during production.

Disclosure of Invention

The utility model aims to solve the technical problem that a solar cell panel lamination back cooling device in succession is provided, can cool off and the switching-over in succession the solar cell panel semi-manufactured goods after the lamination.

In order to solve the technical problem, the utility model discloses the technical scheme who adopts is:

a continuous cooling device for laminated solar panels comprises a longitudinal belt conveying mechanism and a transverse belt conveying mechanism;

the longitudinal belt conveying mechanism comprises a first support, a plurality of groups of first belt conveyors longitudinally arranged are mounted on the first support, and the plurality of groups of first belt conveyors are coaxially mounted and driven to rotate by a first motor;

the transverse belt conveying mechanism comprises a second support, a plurality of air cylinders are mounted on the second support, the driving ends of the air cylinders are connected with a third support, and a plurality of groups of second belt conveyors and a plurality of groups of transmission wheel assemblies are mounted at the upper end of the third support; the second belt conveyor and the transmission wheel assembly are driven by a synchronous belt transmission mechanism;

and a plurality of groups of fans are arranged on the third support, and the air outlets of the fans face upwards.

The first belt conveyors are arranged in four groups at intervals, the interval between the middle two groups of first belt conveyors is large, and the interval between the first group of first belt conveyors and the second group of first belt conveyors or the interval between the third group of first belt conveyors and the fourth group of first belt conveyors which are sequentially arranged is small.

The second belt conveyors are divided into four groups and transversely arranged between the middle two groups of first belt conveyors, and the driving wheel assemblies are arranged between the first belt conveyors on the outer sides left and right.

The transmission wheel assembly comprises a transmission shaft, and a plurality of transmission wheels are mounted on the transmission shaft.

The synchronous belt transmission mechanism comprises a first synchronous belt wheel arranged at the end of the conveying shaft, a second synchronous belt wheel coaxially arranged with a plurality of groups of second belt conveyors, a third synchronous belt wheel and a fourth synchronous belt wheel symmetrically arranged on the left and right of the third support, and the synchronous belt bypasses the first synchronous belt wheel, the second synchronous belt wheel, the third synchronous belt wheel and the fourth synchronous belt wheel and is driven by a second motor.

The utility model relates to a continuous cooling device after solar cell panel lamination has following technological effect:

1) through setting up vertical belt transport mechanism, horizontal belt transport mechanism, because horizontal belt transport mechanism can go up and down, can connect the material and cool off like this after solar cell panel lamination, and export after cooling the vertical belt transport mechanism of accessible carries out the switching-over. Due to the fact that the laminating machine is long, the layout length of the equipment can be reduced through reversing.

2) Through set up the fan on horizontal belt transport mechanism, when production, through a plurality of these equipment of tandem connection, the semi-manufactured goods that laminator sent out in succession can carry out continuous transport and through the fan cooling.

Drawings

The invention will be further explained with reference to the following figures and examples:

fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural diagram of the present invention.

Fig. 3 is a schematic structural view of the middle transverse belt conveying mechanism of the present invention.

Fig. 4 is a schematic structural view of the middle transverse belt conveying mechanism of the present invention.

In the figure: the device comprises a longitudinal belt conveying mechanism 1, a transverse belt conveying mechanism 2, a first support 1.1, a first belt conveyor 1.2, a first motor 1.3, a second support 2.1, a cylinder 2.2, a third support 2.3, a second belt conveyor 2.4, a driving wheel component 2.5, a synchronous belt transmission mechanism 2.6, a fan 2.7, a conveying shaft 2.5.1, a conveying wheel 2.5.2, a first synchronous belt wheel 2.6.1, a second synchronous belt wheel 2.6.2, a third synchronous belt wheel 2.6.3, a fourth synchronous belt wheel 2.6.4, a synchronous belt 2.6.5 and a second motor 2.6.6.

Detailed Description

As shown in fig. 1, a continuous cooling device after lamination of solar panels comprises a longitudinal belt conveying mechanism 1 and a transverse belt conveying mechanism 2. The longitudinal belt conveying mechanism 1 can longitudinally convey the solar cell panel, and the transverse belt conveying mechanism 2 can transversely convey the solar cell panel.

As shown in fig. 2, the longitudinal belt transmission mechanism 1 includes a first support 1.1, four sets of first belt conveyors 1.2 arranged longitudinally are mounted on the first support 1.1, a housing of the first belt conveyor 1.2 is fixed on the first support 1.1 through a bolt, driving belt pulleys of the four sets of first belt conveyors 1.2 are coaxially connected with a driving shaft, driven belt pulleys of the four sets of first belt conveyors 1.2 are connected with a driven shaft, the driving shaft and the driven shaft are mounted on the first support 1.1 through a bearing assembly, and the driving shaft is driven by a first motor 1.3. When the first motor 1.3 is driven, the four groups of first belt conveyors 1.2 rotate synchronously.

Here, the four groups of first belt conveyors 1.2 are arranged at intervals, the interval between the two middle groups of first belt conveyors 1.2 is large, and the interval between the first group and the second group of first belt conveyors 1.2 or the interval between the third group and the fourth group of first belt conveyors 1.2 arranged in sequence is small.

As shown in fig. 3-4, the transverse belt conveyor 2 comprises a second support 2.1, the second support 2.1 being located inside the first support 1.1. Four cylinders 2.2 are symmetrically arranged on the second support 2.1 in front, back, left and right directions, and the driving ends of the four cylinders 2.2 are connected with the third support 2.3. Four groups of second belt conveyors 2.4 and two groups of driving wheel assemblies 2.5 are arranged at the upper end of the third bracket 2.3.

Wherein, four groups of second belt conveyors 2.4 transversely set up and lie in first belt conveyor 1.2's middle interval, and four groups of second belt conveyors 2.4's driving pulley and driving shaft coaxial coupling, driven pulley are connected with the driven shaft, and driving shaft, driven shaft pass through bearing assembly and install on third support 2.3.

The four groups of second belt conveyors 2.4 are arranged at intervals, fans 2.7 are installed in the intervals, and air outlets of the fans 2.7 face upwards. The solar cell panel can be air-cooled when passing by.

Two sets of drive wheel assemblies 2.5 are arranged longitudinally and in the outer space of the first belt conveyor 1.2. Each set of driving wheel assemblies 2.5 comprises a transmission shaft 2.5.1, a plurality of transmission wheels 2.5.2 are arranged on the transmission shaft 2.5.1, and the height of the uppermost edge of the transmission wheel 2.5.2 is consistent with the height of the working surface of the belt of the second belt conveyor 2.4. The transmission shaft 2.5.1 is mounted at both ends on the third bracket 2.3 by means of bearing assemblies.

As shown in fig. 3-4, here the four sets of second belt conveyors 2.4, the two sets of drive wheel assemblies 2.5 are driven by a synchronous belt drive 2.6. The synchronous belt transmission mechanism 2.6 comprises first synchronous belt pulleys 2.6.1 (two) arranged at the ends of two transmission shafts 2.5.1, second synchronous belt pulleys 2.6.2 (two) coaxially arranged with four groups of second belt conveyors 2.4, third synchronous belt pulleys 2.6.3 (two) and fourth synchronous belt pulleys 2.6.4 (two) symmetrically arranged on the left and right of a third support 2.3, and a synchronous belt 2.6.5 wound on the first synchronous belt pulley 2.6.1, the second synchronous belt pulley 2.6.2, the third synchronous belt pulley 2.6.3 and the fourth synchronous belt pulley 2.6.4. The fourth synchronous pulley 2.6.4 is coaxially connected with the second electric machine 2.6.6. When the second motor 2.6.6 is driven, each synchronous belt wheel can be driven to synchronously act, and then the four groups of second belt conveyors 2.4 and the two groups of transmission wheel assemblies 2.5 are driven to synchronously act.

The working principle is as follows: the output direction of the laminator is the same as the conveying direction of the transverse belt conveying mechanism 2, after lamination is completed, the controller controls the cylinder 2.2 to extend out, the third support 2.3 is lifted, the working end face of the second belt conveyor 2.4 is higher than the working end face of the first belt conveyor 1.2, and the working end face of the second belt conveyor 2.4 is consistent with the height of the conveying belt of the laminator. Thus, the semi-finished product of the solar cell panel falls onto the second belt conveyor 2.4, the second motor 2.6.6 can rotate in a circulating forward and reverse direction, and then the semi-finished product of the solar cell panel is enabled to move left and right by a small section for overall cooling. After cooling, the cylinder 2.2 contracts, the third support 2.3 descends, the working end face of the second belt conveyor 2.4 is lower than the working end face of the first belt conveyor 1.2, and the semi-finished solar cell panel falls onto the first belt conveyor 1.2. And starting the first motor 1.3, and conveying the semi-finished product of the solar cell panel forward by the first belt conveyor 1.2 and driving the semi-finished product of the solar cell panel to output forward along the longitudinal direction. Because the equipment can be provided with a plurality of groups and is arranged in series along the length direction of the first belt conveyor 1.2, the equipment can also be directly and continuously conveyed by the first belt conveyor 1.2 and cooled subsequently.

Claims (5)

1. The utility model provides a continuous cooling device behind solar cell panel lamination which characterized in that: comprises a longitudinal belt conveying mechanism (1) and a transverse belt conveying mechanism (2);

the longitudinal belt conveying mechanism (1) comprises a first support (1.1), a plurality of groups of first belt conveyors (1.2) which are longitudinally arranged are mounted on the first support (1.1), and the plurality of groups of first belt conveyors (1.2) are coaxially mounted and driven to rotate by a first motor (1.3);

the transverse belt conveying mechanism (2) comprises a second support (2.1), a plurality of cylinders (2.2) are mounted on the second support (2.1), the driving ends of the cylinders (2.2) are connected with a third support (2.3), a plurality of groups of second belt conveyors (2.4) and a plurality of groups of transmission wheel assemblies (2.5) are mounted at the upper end of the third support (2.3), wherein the groups of second belt conveyors (2.4) are transversely arranged and located in the middle gaps of the first belt conveyors (1.2), and the groups of transmission wheel assemblies (2.5) are longitudinally arranged and located in the outer side gaps of the first belt conveyors (1.2); the second belt conveyor (2.4) and the driving wheel assembly (2.5) are driven by a synchronous belt transmission mechanism (2.6);

and a plurality of groups of fans (2.7) are arranged on the third support (2.3), and air outlets of the fans (2.7) face upwards.

2. The post-lamination continuous cooling apparatus for a solar panel according to claim 1, wherein: the first belt conveyors (1.2) are arranged in four groups at intervals, the interval between the middle two groups of first belt conveyors (1.2) is large, and the interval between the first group of first belt conveyors and the second group of first belt conveyors (1.2) or the interval between the third group of first belt conveyors and the fourth group of first belt conveyors (1.2) which are sequentially arranged is small.

3. A post-lamination continuous cooling apparatus for a solar panel according to claim 2, wherein: the second belt conveyors (2.4) are divided into four groups and transversely arranged between the middle two groups of first belt conveyors (1.2), and the transmission wheel assemblies (2.5) are arranged between the first belt conveyors (1.2) on the outer sides from left to right.

4. The post-lamination continuous cooling apparatus for a solar panel according to claim 1, wherein: the transmission wheel assembly (2.5) comprises a transmission shaft (2.5.1), and a plurality of transmission wheels (2.5.2) are mounted on the transmission shaft (2.5.1).

5. The post-lamination continuous cooling device for the solar panel according to claim 4, wherein: synchronous belt drive mechanism (2.6) is including installing first synchronous pulley (2.6.1) at transmission shaft (2.5.1) end, with second synchronous pulley (2.6.2) of multiunit second belt conveyor (2.4) coaxial arrangement, third synchronous pulley (2.6.3), fourth synchronous pulley (2.6.4) about third support (2.3) are installed to the symmetry, first synchronous pulley (2.6.1) are walked around in synchronous belt (2.6.5), second synchronous pulley (2.6.2), third synchronous pulley (2.6.3), fourth synchronous pulley (2.6.4) and through second motor (2.6.6) drive.

Images