CN114464696A - Laminating mechanism of silicon-based solar cell module - Google Patents

Abstract

The invention relates to a laminating mechanism of a silicon-based solar cell module, which comprises the following components: the laminating machine comprises a base and fixing plates which are fixedly arranged on the base and symmetrically arranged, wherein a first transverse plate and a second transverse plate are fixed on the fixing plates, and the laminating machine is also fixedly arranged on the base; the base and the first transverse plate are also provided with a driving mechanism for receiving and driving materials to move, and a guide mechanism connected with the driving mechanism is also arranged between the fixed plates; the second transverse plate is also provided with a reciprocating assembly connected with the guide mechanism, and the reciprocating assembly drives the guide mechanism to reciprocate in the vertical direction; a rotating mechanism connected with the driving mechanism is further arranged between the fixed plates and connected with the reciprocating assembly; the first transverse plate is further provided with an elastic mechanism connected with the guide mechanism and the rotating mechanism, and a sucker is fixed on the elastic mechanism.

Description

Laminating mechanism of silicon-based solar cell module

Technical Field

The invention relates to the field of solar panels, in particular to a laminating mechanism of a silicon-based solar cell module.

Background

The solar laminating machine is applied to a solar cell photovoltaic production line, and the principle of the solar laminating machine is that certain pressure is applied to the outer surface of each layer of material, the materials are tightly pressed together in a heating state, the traditional laminating machine is not provided with a material conveying device, materials need to be added manually, the precision of the manual material adding is not high, and the materials are difficult to align, so that the laminating mechanism of the silicon-based solar cell module is provided.

Disclosure of Invention

The present invention is directed to a lamination mechanism for a silicon-based solar cell module, which solves the above problems.

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

a lamination mechanism for a silicon-based solar cell module, the lamination mechanism comprising:

the laminating machine comprises a base and fixing plates which are fixedly arranged on the base and symmetrically arranged, wherein a first transverse plate and a second transverse plate are fixed on the fixing plates, and a laminating machine is also fixedly arranged on the base;

the base and the first transverse plate are also provided with a driving mechanism for receiving and driving materials to move, and a guide mechanism connected with the driving mechanism is also arranged between the fixed plates;

the second transverse plate is also provided with a reciprocating assembly connected with the guide mechanism, and the reciprocating assembly drives the guide mechanism to reciprocate in the vertical direction;

a rotating mechanism connected with the driving mechanism and the guide mechanism is further arranged between the fixed plates, and the rotating mechanism is connected with the reciprocating assembly;

the first transverse plate is further provided with an elastic mechanism connected with the guide mechanism and the rotating mechanism, and a sucker is fixed on the elastic mechanism.

As a further scheme of the invention: actuating mechanism includes fixed mounting and installs the board of accepting on the diaphragm is installed with rotating the board of accepting and be fixed with No. two dwangs and fixed mounting of gag lever post on the board just set up with No. two hollow poles of the spacing groove of gag lever post adaptation on the guiding mechanism, still be provided with on the base with the subassembly of accepting that No. two dwangs are connected, No. two hollow poles with the slewing mechanism is connected.

As a still further scheme of the invention: accept the subassembly and install including rotating transfer line and fixed mounting on the base just are multiunit material case and fixed mounting that circumference equidistance set up on the transfer line action wheel on the second number dwang, still be fixed with on the transfer line with from the driving wheel of action wheel adaptation.

As a still further scheme of the invention: guiding mechanism is including seting up spout and slidable mounting on the fixed plate are in sliding block and fixed mounting on the spout between the sliding block and with the dead lever that elastic mechanism connects, still be provided with on the dead lever with the supporting component that No. two dwang are connected, the supporting component with reciprocal subassembly with slewing mechanism connects.

As a still further scheme of the invention: the supporting component comprises a fixed sleeve and a fixed sleeve, wherein the fixed sleeve and the fixed sleeve are fixedly mounted on the fixed rod and symmetrically arranged, the fixed sleeve is arranged between the fixed sleeves, the rotating mechanism is connected with a reciprocating component, the baffle and the fixed sleeve are fixedly mounted on the fixed rod, and the supporting sleeve is provided with a second rotating rod.

As a still further scheme of the invention: reciprocating assembly installs including rotating No. two diaphragm on and be fixed with bellied carousel and fixed mounting just be the backup pad and the fixed mounting that the symmetry set up on the baffle just set up between the backup pad with the connecting rod in the groove of protruding adaptation, the backup pad still with slewing mechanism connects.

As a still further scheme of the invention: slewing mechanism includes fixed mounting and is in a bevel gear and rotation on No. two dwangs are installed No. three dwangs and fixed mounting on the baffle are in No. three dwangs on and with No. two bevel gear of a bevel gear meshing, still be provided with in the backup pad with the driven subassembly that No. three dwangs are connected, driven subassembly with elastic mechanism connects.

As a still further scheme of the invention: driven subassembly is installed including rotating a dwang and fixed mounting on the baffle are in a dwang on and with half gear and a pot head that elastic mechanism connects are established No. one the dwang is gone up another pot head and is established belt on No. three dwangs.

As a still further scheme of the invention: elastic mechanism includes movable mounting and is in movable sleeve and fixed mounting on the dead lever movable sleeve last and with half gear engagement's rack board and cover are established just one end is fixed on the dead lever fixed sleeve is last the other end to be fixed a spring on the movable sleeve, still be provided with spacing subassembly on the movable sleeve, spacing subassembly is fixed with the sucking disc.

As a still further scheme of the invention: spacing subassembly includes fixed mounting and is in just be fixed with a cavity pole and the movable mounting of stopper on the movable sleeve just be fixed with on the cavity pole No. one the movable rod of sucking disc and fix in the cavity pole No. one and with No. two springs that the movable rod is connected, still be fixed with on the diaphragm with the stop sleeve that the stopper is connected.

Compared with the prior art, the invention has the beneficial effects that: when using, place the material that needs processing on actuating mechanism, actuating mechanism work this moment, and drive slewing mechanism motion, thereby drive elastic mechanism moves on guiding mechanism, and simultaneously, reciprocating assembly still can drive guiding mechanism motion, make the sucking disc move in vertical direction when the horizontal direction motion, when the sucking disc adsorbs the material on with actuating mechanism, reciprocating assembly motion this moment, and drive elastic mechanism motion, make the sucking disc move to the laminator top, reciprocating assembly continues the motion, and carry the material to the laminator through elastic mechanism drive sucking disc.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of a lamination mechanism of a silicon-based solar cell module.

Fig. 2 is a schematic structural view of another angle in an embodiment of a lamination mechanism of a silicon-based solar cell module.

Fig. 3 is a schematic connection diagram of a part of the driving mechanism and a part of the rotating mechanism in an embodiment of the laminating mechanism of the silicon-based solar cell module.

Fig. 4 is a schematic diagram of a partially exploded structure of an embodiment of a lamination mechanism for a silicon-based solar cell module.

In the figure: 1-base, 2-fixed plate, 3-chute, 4-first transverse plate, 5-second transverse plate, 6-sliding block, 7-fixed rod, 8-fixed sleeve, 9-baffle, 10-movable sleeve, 11-rack plate, 12-first spring, 13-supporting plate, 14-first rotating rod, 15-half gear, 16-first hollow rod, 17-second spring, 18-movable rod, 19-sucker, 20-limiting sleeve, 21-rotary table, 22-connecting rod, 23-driving rod, 24-material box, 25-driven wheel, 26-driving wheel, 27-second rotating rod, 28-second hollow rod, 29-first bevel gear, 30-second bevel gear, 31-supporting sleeve, 32-third rotating rod, 33-belt and 34-laminating machine.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In addition, an element of the present invention may be said to be "fixed" or "disposed" to another element, either directly on the other element or with intervening elements present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Referring to fig. 1 to 4, in an embodiment of the present invention, a laminating mechanism of a silicon-based solar cell module includes:

the device comprises a base 1 and fixing plates 2 which are fixedly arranged on the base 1 and symmetrically arranged, wherein a first transverse plate 4 and a second transverse plate 5 are fixed on the fixing plates 2, and a laminating machine 34 is also fixedly arranged on the base 1;

the base 1 and the first transverse plate 4 are also provided with a driving mechanism for receiving and driving the materials to move, the driving mechanism comprises a bearing plate fixedly arranged on the first transverse plate 4, a second rotating rod 27 which is rotatably arranged on the bearing plate and is fixedly provided with a limiting rod, and a second hollow rod 28 which is fixedly arranged on the guide mechanism and is provided with a limiting groove matched with the limiting rod, the base 1 is also provided with a bearing component connected with the second rotating rod 27, the second hollow rod 28 is connected with the rotating mechanism, wherein, accept the subassembly including rotate the installation drive rod 23 and fixed mounting on the base 1 on the drive rod 23 and be the multiunit material case 24 and fixed mounting that circumference equidistance set up drive wheel 26 on No. two dwang 27, still be fixed with on the drive rod 23 with the driven wheel 25 of drive wheel 26 adaptation.

It should be noted that the bottom of the transmission rod 23 is a cylinder, the middle of the transmission rod is a pentagonal prism, the upper of the transmission rod is a cylinder, the material tanks 24 are fixed on each surface of the pentagonal prism, the number of the material tanks 24 is five, and each material tank 24 is filled with materials to be used, when the second rotating rod 27 rotates, the driving wheel 26 is driven to rotate, so that the driven wheel 25 is driven to rotate intermittently, under the action of the limiting groove and the limiting rod, the second hollow rod 28 is driven to rotate, so that the rotating mechanism is driven to move, wherein the driving wheel 26 and the driven wheel 25 form a maltese cross movement assembly, when the driving wheel 26 rotates for one circle, the driven wheel 25 rotates for one fifth of a circle, and the receiving plate is provided with a first motor (not shown in the figure) connected with the second rotating rod 27, and when the first motor works, the second rotating rod 27 is driven to rotate.

Still be provided with between fixed plate 2 with guiding mechanism that actuating mechanism connects, guiding mechanism is including seting up spout 3 and slidable mounting on the fixed plate 2 are in sliding block 6 and fixed mounting on the spout 3 between the sliding block 6 and with dead lever 7 that elastic mechanism connects, still be provided with on the dead lever 7 with the supporting component that No. two dwang 27 are connected, the supporting component with reciprocal subassembly with slewing mechanism connects, wherein, the supporting component includes fixed mounting and is in on the dead lever 7 and be the fixed sleeve 8 and the fixed mounting that the symmetry set up fixed sleeve 8 between the fixed sleeve 8 and with slewing mechanism with baffle 9 and fixed mounting that reciprocal subassembly is connected just rotate on the dead lever 7 and install No. two dwang 27's supporting sleeve 31.

Further, when the reciprocating assembly moves, the baffle 9 is driven to reciprocate in the vertical direction, so that the sliding block 6 is driven to slide on the sliding chute 3, and the fixing rod 7 is driven to move, so that the fixing sleeve 8 and the supporting sleeve 31 move in the vertical direction, and the supporting sleeve 31 also drives the second hollow rod 28 to reciprocate on the second rotating rod 27.

No. two diaphragm 5 on still be provided with the reciprocal subassembly that guiding mechanism connects, reciprocal subassembly drive guiding mechanism is reciprocating motion in vertical direction, reciprocal subassembly is installed including rotating No. two diaphragm 5 is gone up and is fixed with bellied carousel 21 and fixed mounting just be backup pad 13 and the fixed mounting that the symmetry set up on the baffle 9 between the backup pad 13 and seted up with the connecting rod 22 in the groove of protruding adaptation, backup pad 13 still with rotating mechanism connects.

Still further, a second motor (not shown in the figure) is fixed on the second transverse plate 5, an output shaft of the second motor is coaxially connected with the rotary plate 21, when the second motor works, the rotary plate 21 is driven to rotate and drive the protrusion to move, the connecting rod 22 is driven to move under the action of the protrusion, so that the supporting plate 13 is driven to reciprocate in the vertical direction, and the baffle plate 9 reciprocates, wherein the groove formed in the connecting rod 22 is divided into two parts, one part is an arc groove, the other part is a straight groove, when the protrusion moves to the arc groove, the connecting rod 22 is in a static state, and when the protrusion moves to the straight groove, the connecting rod 22 is driven to move in the vertical direction.

A rotating mechanism connected with the driving mechanism and the guiding mechanism is also arranged between the fixed plates 2, the rotating mechanism is connected with the reciprocating component, the rotating mechanism comprises a first bevel gear 29 fixedly arranged on the second rotating rod 27, a third rotating rod 32 rotatably arranged on the baffle plate 9, and a second bevel gear 30 fixedly arranged on the third rotating rod 32 and meshed with the first bevel gear 29, the support plate 13 is also provided with a driven component connected with the third rotating rod 32, the driven component is connected with the elastic mechanism, wherein, driven subassembly is installed including rotating a dwang 14 and fixed mounting on the baffle 9 are in a dwang 14 on and with half gear 15 and a pot head that elastic mechanism connects are established another pot head is established on a dwang 14 belt 33 on No. three dwang 32.

It should be noted that when the second rotating rod 27 rotates, the first bevel gear 29 is driven to rotate, and the second bevel gear 30 is driven to rotate, so that the third rotating rod 32 is driven to rotate, and the first rotating rod 14 is driven to rotate and the half gear 15 is driven to rotate under the action of the belt 33.

Still be provided with on diaphragm 4 with guiding mechanism with the elastic mechanism that slewing mechanism connects, be fixed with sucking disc 19 on the elastic mechanism, elastic mechanism includes movable sleeve 10 and fixed mounting on the dead lever 7 movable sleeve 10 on and with rack plate 11 and the cover that the pinion 15 meshed are established on the dead lever 7 and one end is fixed on the dead lever 7 spring 12 on the fixed sleeve 10 is fixed to the other end on the fixed sleeve 8, still be provided with spacing subassembly on the movable sleeve 10, spacing subassembly is fixed with sucking disc 19, wherein, spacing subassembly includes fixed mounting on the movable sleeve 10 and fixed with the spacing piece hollow rod 16 and movable mounting on hollow rod 16 and be fixed with sucking disc 19 movable rod 18 and fix in hollow rod 16 and with No. two spring 17 that movable rod 18 is connected, and a limiting sleeve 20 connected with the limiting block is further fixed on the first transverse plate 4.

Finally, the limiting sleeve 20 is provided with an inverted-L-shaped through groove, the diameter of the fixed block is smaller than the width of the through groove, the half gear 15 is one fourth of a complete gear, the transmission ratio of the rotary table 22 to the first rotating rod 14 is 2:1, in an initial state, the connecting rod 22 is at the maximum stroke position close to the direction of the base 1, when the connecting rod 22 moves a small distance away from the direction of the base 1, the half gear 15 moves to the position attached to the rack plate 11 and drives the movable sleeve 10 fixed with the rack plate 11 to move along the length direction of the fixed rod 7, so that the first spring 12 is stretched and the first hollow rod 16 is driven to move, when the connecting rod 22 moves to the maximum stroke position away from the direction of the base 1, the fixed block just moves into the through groove, when the connecting rod 22 moves towards the direction of the base 1, the fixed block moves to the position where the through groove is opened towards the direction of the base 1, because the diameter of the fixed block is smaller than the width of the through groove, the fixed block cannot interfere with the through groove, at the moment, the half gear 15 is separated from the rack plate 11, the turntable 22 continues to move and drives the first hollow rod 16 to continue to move towards the direction of the base 1, so that the movable rod 18 is driven to move, the sucker 19 is attached to the material, the material is adsorbed on the sucker 19,

wherein, because No. two springs 17 are provided, the movable rod 18 can not interfere with the material, when the connecting rod 22 moves towards the direction away from the base 1 again, at this time, the hollow rod 16 in the first position will move to the maximum stroke position away from the base 1, and under the effect of the spring 12, the movable sleeve 10 is driven to move towards the laminator 34, and meanwhile, the transmission rod 23 will drive the other material box 24 to rotate to the position matched with the suction cup 19, when moving to the maximum stroke position, the connecting rod 22 continues to move towards the base 1 direction at this time, and conveys the material to the laminator 34, the above steps are repeated until all the materials in the five material boxes 24 are conveyed to the laminator 34, it should be noted that the laminator 34 is used for laminating the solar panel, which is an application of the prior art, and no further description is given in this application.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (10)

1. A lamination mechanism of a silicon-based solar cell module, characterized in that the lamination mechanism of the silicon-based solar cell module comprises:

the laminating machine comprises a base (1) and fixing plates (2) which are fixedly arranged on the base (1) and symmetrically arranged, wherein a first transverse plate (4) and a second transverse plate (5) are fixed on the fixing plates (2), and a laminating machine (34) is also fixedly arranged on the base (1);

the base (1) and the first transverse plate (4) are also provided with a driving mechanism for receiving and driving materials to move, and a guide mechanism connected with the driving mechanism is also arranged between the fixed plates (2);

the second transverse plate (5) is also provided with a reciprocating assembly connected with the guide mechanism, and the reciprocating assembly drives the guide mechanism to reciprocate in the vertical direction;

a rotating mechanism connected with the driving mechanism and the guide mechanism is further arranged between the fixed plates (2), and the rotating mechanism is connected with the reciprocating assembly;

the first transverse plate (4) is further provided with an elastic mechanism connected with the guide mechanism and the rotating mechanism, and a sucker (19) is fixed on the elastic mechanism.

2. The laminating mechanism for silicon-based solar cell modules according to claim 1, wherein the driving mechanism comprises a receiving plate fixedly mounted on the first transverse plate (4), a second rotating rod (27) rotatably mounted on the receiving plate and fixed with a limiting rod, and a second hollow rod (28) fixedly mounted on the guiding mechanism and provided with a limiting groove adapted to the limiting rod, the base (1) is further provided with a receiving assembly connected with the second rotating rod (27), and the second hollow rod (28) is connected with the rotating mechanism.

3. The laminating mechanism for silicon-based solar cell modules according to claim 2, wherein the receiving module comprises a transmission rod (23) rotatably mounted on the base (1), a plurality of sets of material tanks (24) fixedly mounted on the transmission rod (23) and arranged at equal intervals on the circumference, and a driving wheel (26) fixedly mounted on the second rotating rod (27), and a driven wheel (25) adapted to the driving wheel (26) is further fixed on the transmission rod (23).

4. The laminating mechanism for silicon-based solar cell modules according to claim 2, wherein the guiding mechanism comprises a sliding groove (3) formed on the fixing plate (2), a sliding block (6) slidably mounted on the sliding groove (3), and a fixing rod (7) fixedly mounted between the sliding blocks (6) and connected with the elastic mechanism, and a supporting assembly connected with the second rotating rod (27) is further disposed on the fixing rod (7), and the supporting assembly is connected with the reciprocating assembly and the rotating mechanism.

5. The lamination mechanism for silicon-based solar cell module as claimed in claim 4, wherein the support module comprises symmetrically disposed fixing sleeves (8) fixedly mounted on the fixing rods (7), a baffle plate (9) fixedly mounted between the fixing sleeves (8) and connected to the rotation mechanism and the reciprocating module, and a support sleeve (31) fixedly mounted on the fixing rods (7) and rotatably mounted with the second rotation rod (27).

6. The laminating mechanism for silicon-based solar cell modules according to claim 5, wherein the reciprocating assembly comprises a rotating disc (21) rotatably mounted on the second transverse plate (5) and fixed with protrusions, supporting plates (13) fixedly mounted on the baffle plate (9) and symmetrically arranged, and a connecting rod (22) fixedly mounted between the supporting plates (13) and provided with a groove adapted to the protrusions, and the supporting plates (13) are further connected with the rotating mechanism.

7. The laminating mechanism for silicon-based solar cell modules according to claim 6, wherein the rotating mechanism comprises a first bevel gear (29) fixedly mounted on the second rotating rod (27), a third rotating rod (32) rotatably mounted on the baffle plate (9), and a second bevel gear (30) fixedly mounted on the third rotating rod (32) and engaged with the first bevel gear (29), and the supporting plate (13) is further provided with a driven assembly connected with the third rotating rod (32), and the driven assembly is connected with the elastic mechanism.

8. The laminating mechanism for silicon-based solar cell modules according to claim 7, wherein the driven module comprises a first rotating rod (14) rotatably installed on the baffle plate (9), a half gear (15) fixedly installed on the first rotating rod (14) and connected with the elastic mechanism, and a belt (33) which is installed on the first rotating rod (14) and is installed on the third rotating rod (32) at the other end.

9. The lamination mechanism for silicon-based solar cell modules as claimed in claim 8, wherein the elastic mechanism comprises a movable sleeve (10) movably mounted on the fixed rod (7), a rack plate (11) fixedly mounted on the movable sleeve (10) and engaged with the half gear (15), and a spring (12) sleeved on the fixed rod (7) and having one end fixed on the fixed sleeve (8) and the other end fixed on the movable sleeve (10), wherein the movable sleeve (10) is further provided with a limiting assembly, and the sucking disc (19) is fixed on the limiting assembly.

10. The laminating mechanism for silicon-based solar cell modules according to claim 9, wherein the limiting assembly comprises a first hollow rod (16) fixedly mounted on the movable sleeve (10) and fixedly provided with a limiting block, a movable rod (18) movably mounted on the first hollow rod (16) and fixedly provided with the suction cup (19), and a second spring (17) fixed in the first hollow rod (16) and connected with the movable rod (18), and a limiting sleeve (20) connected with the limiting block is further fixed on the first transverse plate (4).

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