CN219949770U - Clamping mechanism of solar photovoltaic panel sorting equipment - Google Patents

Abstract

The utility model discloses a clamping mechanism of solar photovoltaic panel sorting equipment, which comprises photovoltaic glass and a frame, wherein the frame is arranged around the photovoltaic glass, a supporting part which is arranged opposite to the photovoltaic glass is arranged in the frame, a space is reserved between the supporting part and the photovoltaic glass, and the clamping mechanism comprises a first traversing assembly, a second traversing assembly, a lifting frame and a clamping assembly for clamping the supporting part; the first transverse moving assembly and the second transverse moving assembly are respectively arranged at two ends of the lifting frame in the width direction and are connected with the lifting frame in a relatively sliding manner, and the first transverse moving assembly and the second transverse moving assembly can be gradually close to or gradually far away from each other; one side of the first traversing assembly and one side of the second traversing assembly, which are far away from each other, are respectively provided with a clamping assembly. According to the utility model, the solar photovoltaic panel is locally clamped in a transversely moving and clamping mode, so that the deformation risk of the solar photovoltaic panel is reduced.

Description

Clamping mechanism of solar photovoltaic panel sorting equipment

Technical Field

The utility model relates to the technical field of photovoltaic panel production, in particular to a clamping mechanism of solar photovoltaic panel sorting equipment.

Background

The existing photovoltaic glass sorting equipment generally adopts clamping jaws to transversely clamp the frame of a solar photovoltaic panel from the outside of the solar photovoltaic panel and carry the solar photovoltaic panel, but because the dead weight of the solar photovoltaic panel is large, if the solar photovoltaic panel is carried in the mode, the clamping jaws are required to have large clamping force, the efficiency can be improved, but the frame of the solar photovoltaic panel is easy to deform, and a semiconductor is difficult to be installed in the photovoltaic panel.

Disclosure of Invention

The technical problems to be solved by the utility model are as follows: the clamping mechanism of the solar photovoltaic panel sorting equipment is provided, and the risk of compression deformation of the solar photovoltaic panel in the carrying process is reduced.

In order to solve the technical problems, the utility model adopts the following technical scheme:

the clamping mechanism of the solar photovoltaic panel sorting equipment comprises photovoltaic glass and a frame, wherein the frame is arranged around the photovoltaic glass, a supporting part which is arranged opposite to the photovoltaic glass is arranged in the frame, a space is reserved between the supporting part and the photovoltaic glass, and the clamping mechanism comprises a first traversing assembly, a second traversing assembly, a lifting frame and a clamping assembly for clamping the supporting part;

the first traversing assembly and the second traversing assembly are respectively arranged at two ends of the lifting frame in the width direction and are connected with the lifting frame in a relatively sliding manner, and the first traversing assembly and the second traversing assembly can be gradually close to or gradually far away from each other;

one side of the first traversing assembly, which is far away from the second traversing assembly, is respectively provided with a clamping assembly.

Further, the clamping assembly comprises a pressing cylinder, angle steel and a pressing piece;

the lower ends of the first transverse moving assembly and the second transverse moving assembly are respectively connected with one angle steel, the lower pressing cylinder and the pressing piece are respectively connected with the upper end and the lower end of the corresponding angle steel, and the movable end of the lower pressing cylinder and the pressing piece are oppositely arranged to clamp the supporting part.

Further, two opposite sides of the angle steel are respectively provided with a pressing component, and the movable end of the pressing component is lower than the bottom of the angle steel so as to be propped against the solar photovoltaic panel.

Further, the compressing assembly comprises a compressing piece, a supporting piece and a limiting piece;

the pressing piece comprises a free end and a pressing end used for pressing the solar photovoltaic panel;

the pressing piece is connected with the angle steel through the supporting piece, the pressing piece is hinged with the supporting piece, the hinge point is located at the position, close to the free end, on the pressing piece, the limiting piece is connected with the supporting piece and located above the pressing piece, and the limiting piece is arranged at one end, close to the pressing end, of the hinge point.

Further, the compressing assemblies are provided with at least two compressing assemblies, and the compressing assemblies are uniformly distributed along the length direction of the angle steel.

Further, the first traversing assembly comprises a linear motion assembly, a traversing bracket and a sliding assembly;

the upper end of the transverse moving support is connected with the lifting frame in a relatively sliding manner through the sliding component, the fixed end of the linear motion component is arranged on the lifting frame, and the movable end of the linear motion component is connected with the transverse moving support.

Further, the lower end of the traversing bracket extends towards a direction far away from the lifting frame, and the clamping component is connected with the lower end of the traversing bracket.

Further, the clamping mechanism further comprises an induction component, two ends of the lifting frame are respectively provided with one induction component in the width direction of the lifting frame, and a movable space for the first traversing component and the second traversing component to move is arranged between the induction component and the lifting frame.

Further, the induction component comprises an extension rod and an inductor, wherein the extension rod is provided with a first horizontal part, a second horizontal part and a vertical part which are sequentially connected, and the first horizontal part and the second horizontal part are respectively and mutually perpendicular to the vertical part and are arranged at the upper end and the lower end of the vertical part;

the sensor is arranged on the second horizontal part;

the first horizontal part extends outwards in the width direction of the lifting frame, and the length of the second horizontal part is smaller than that of the second horizontal part, so that a yielding space is formed between the second horizontal part, the vertical part and the clamping assembly.

The utility model has the beneficial effects that: adopt two sideslip subassemblies to drive the clamping assembly that corresponds and insert between supporting part and the photovoltaic glass to cooperate clamping assembly to carry out the mode of centre gripping to the supporting part, avoid following the outside direct centre gripping of solar photovoltaic board, make solar photovoltaic board in width direction and the ascending deformation risk of length direction reduce, ensure solar photovoltaic board's outward appearance roughness, and then be convenient for follow-up semiconductor assembly.

Drawings

Fig. 1 is a schematic view of a partial structure of a solar photovoltaic panel sorting apparatus according to the present utility model;

fig. 2 is a schematic structural diagram of a clamping mechanism of a solar photovoltaic panel sorting apparatus according to the present utility model;

FIG. 3 is a side view of FIG. 2;

fig. 4 is a schematic structural diagram of a clamping mechanism of the solar photovoltaic panel sorting device and a partial enlarged view;

fig. 5 is a schematic structural view and a partial enlarged view of a clamping mechanism of a solar photovoltaic panel sorting device in the utility model.

Description of the reference numerals:

1. a solar photovoltaic panel; 11. photovoltaic glass; 12. a frame; 121. a support part;

2. a lifting assembly; 21. a screw rod; 22. a nut seat; 23. a lifting motor; 24. a chain; 25. a sprocket;

3. a first traversing assembly; 31. a linear motion assembly; 32. a traversing support; 33. a sliding assembly;

4. a second traversing assembly;

5. a lifting frame;

6. a clamping assembly; 61. a pressing cylinder; 62. angle steel; 63. a pressing member;

7. a compression assembly; 71. a pressing member; 711. a pressing end; 72. a support; 73. a limiting piece;

8. an induction assembly; 81. an extension rod; 811. a first horizontal portion; 812. a second horizontal portion; 813. a vertical portion; 82. an inductor;

9. a guide rod; 91. a connecting frame; 92. a guide seat; 10. and a transfer mechanism.

Detailed Description

In order to describe the technical contents, the achieved objects and effects of the present utility model in detail, the following description will be made with reference to the embodiments in conjunction with the accompanying drawings.

Referring to fig. 1-5, a clamping mechanism of a solar photovoltaic panel sorting device, the solar photovoltaic panel comprises photovoltaic glass and a frame, the frame is arranged around the photovoltaic glass, a supporting part opposite to the photovoltaic glass is arranged in the frame, a space is arranged between the supporting part and the photovoltaic glass, and the clamping mechanism comprises a first traversing assembly, a second traversing assembly, a lifting frame and a clamping assembly for clamping the supporting part;

the first transverse moving assembly and the second transverse moving assembly are respectively arranged at two ends of the lifting frame in the width direction and are connected with the lifting frame in a relatively sliding manner, and the first transverse moving assembly and the second transverse moving assembly can be gradually close to or gradually far away from each other;

one side of the first traversing assembly and one side of the second traversing assembly, which are far away from each other, are respectively provided with a clamping assembly.

From the above description, the beneficial effects of the utility model are as follows: adopt two sideslip subassemblies to drive the clamping assembly that corresponds and insert between supporting part and the photovoltaic glass to cooperate clamping assembly to carry out the mode of centre gripping to the supporting part, avoid following the outside direct centre gripping of solar photovoltaic board, make solar photovoltaic board in width direction and the ascending deformation risk of length direction reduce, ensure solar photovoltaic board's outward appearance roughness, and then be convenient for follow-up semiconductor assembly.

Further, the clamping assembly comprises a pressing cylinder, angle steel and a pressing piece;

the lower ends of the first transverse moving assembly and the second transverse moving assembly are respectively connected with angle steel, the lower pressing cylinder and the pressing piece are respectively connected with the upper end and the lower end of the corresponding angle steel, and the movable end of the lower pressing cylinder and the pressing piece are oppositely arranged to clamp the supporting part.

According to the description, the lower pressing cylinder is matched with the pressing piece, the supporting portion can be clamped in a surface contact mode, the acting force applied to the solar photovoltaic panel is located in the thickness direction in the carrying process, the clamping force requirement is lowered, and the deformation risk of the solar photovoltaic panel is reduced.

Further, two opposite sides of angle steel are provided with respectively and compress tightly the subassembly, compress tightly the bottom that the loose end of subassembly is less than the angle steel in order to support and press on solar photovoltaic board.

According to the description, the pressing assembly is used for applying a pressing force to the solar photovoltaic panel in the carrying process of the solar photovoltaic panel, so that the shaking amplitude in the carrying process of the solar photovoltaic panel is reduced, and the stability is improved.

Further, the compressing assembly comprises a compressing piece, a supporting piece and a limiting piece;

the pressing piece comprises a free end and a pressing end used for pressing the solar photovoltaic panel;

the compressing piece is connected with the angle steel through the supporting piece, the compressing piece is hinged with the supporting piece, the hinge point is located at a position, close to the free end, on the compressing piece, the limiting piece is connected with the supporting piece and located above the compressing piece, and the limiting piece is arranged at one end, close to the pressing end, of the hinge point.

As can be seen from the above description, since the hinge point is located at the position on the pressing member near the free end, the pressing end is always located at a position lower than the free end when the pressing member is not acted by an external force, and the limiting member is used for limiting the pressing member.

Further, the compressing assemblies are provided with at least two, and the compressing assemblies are uniformly distributed along the length direction of the angle steel.

From the above description, the compressing assembly is provided with at least two compressing assemblies, so that the stability of the solar photovoltaic panel is further improved.

Further, the first traversing assembly comprises a linear motion assembly, a traversing bracket and a sliding assembly;

the upper end of the transverse moving support is connected with the lifting frame in a relatively sliding way through a sliding component, the fixed end of the linear motion component is arranged on the lifting frame, and the movable end of the linear motion component is connected with the transverse moving support.

Further, the lower end of the traversing bracket extends towards the direction far away from the lifting frame, and the clamping component is connected with the lower end of the traversing bracket.

According to the description, the clamping assembly is driven to move in or out of the space between the supporting part and the photovoltaic glass through the cooperation of the linear motion assembly, the transverse moving support and the sliding assembly, so that automatic feeding and discharging of the solar photovoltaic panel can be realized.

Further, the clamping mechanism further comprises an induction component, the two ends of the lifting frame are respectively provided with an induction component in the width direction of the lifting frame, and a movable space for the first traversing component and the second traversing component to move is arranged between the induction component and the lifting frame.

As can be seen from the above description, the sensing component is used for detecting the position of the solar photovoltaic panel to determine the distance between the solar photovoltaic panel and the clamping component, so as to adjust the position of the clamping component.

Further, the induction component comprises an extension rod and an inductor, wherein the extension rod is provided with a first horizontal part, a second horizontal part and a vertical part which are sequentially connected, and the first horizontal part and the second horizontal part are respectively and mutually perpendicular to the vertical part and are arranged at the upper end and the lower end of the vertical part;

the sensor is arranged on the second horizontal part;

the first horizontal part extends outwards in the width direction of the lifting frame, and the length of the second horizontal part is smaller than that of the second horizontal part, so that a yielding space is formed between the second horizontal part, the vertical part and the clamping assembly.

As can be seen from the above description, the arrangement of the extension rod can only enable the sensor to detect the position of the solar photovoltaic panel, but also avoid interference with the movement of the traversing assembly.

Referring to fig. 1 to 5, a first embodiment of the present utility model is as follows:

the clamping mechanism of the solar photovoltaic panel sorting equipment comprises photovoltaic glass 11 and a frame 12, wherein the frame 12 is arranged around the photovoltaic glass 11, a supporting part 121 which is arranged opposite to the photovoltaic glass 11 is arranged in the frame 12, a space is reserved between the supporting part 121 and the photovoltaic glass 11, the clamping mechanism is arranged on a transfer mechanism 10 of the solar photovoltaic panel sorting equipment, and the clamping mechanism comprises a lifting assembly 2, a first traversing assembly 3, a second traversing assembly 4, a lifting frame 5 and a clamping assembly 6 used for clamping the supporting part 121; the first traversing assembly 3 and the second traversing assembly 4 are respectively arranged at two ends of the lifting frame 5 in the width direction and are connected with the lifting frame 5 in a relatively sliding manner, and the first traversing assembly 3 and the second traversing assembly 4 can gradually approach or gradually separate; one side of the first traversing assembly 3, which is far away from the second traversing assembly 4, is respectively provided with a clamping assembly 6; the fixed end of the lifting assembly 2 is connected with the transfer mechanism 10, and the movable end of the lifting assembly 2 passes through the transfer mechanism 10 to be in transmission connection with the lifting frame 5. The second traversing assembly 4 has the same structure as the first traversing assembly 3, and will not be described herein.

In this embodiment, the lifting assembly 2 includes a screw 21, a nut seat 22 and a lifting motor 23, the screw 21 is connected with the lifting frame 5, the fixed end of the lifting motor 23 and the nut seat 22 are installed at the top of the transfer mechanism 10, and the movable end of the lifting motor 23 is in transmission connection with the nut seat 22 through a chain 24 and two sprockets 25, so as to control the screw 21 to move up and down relative to the nut seat 22, so as to drive the first traversing assembly 3, the second traversing assembly 4, the lifting frame 5 and the clamping assembly 6 to lift.

In the present embodiment, the clamping assembly 6 includes a pressing cylinder 61, angle steel 62, and a pressing piece 63; the lower ends of the first traversing assembly 3 and the second traversing assembly 4 are respectively connected with an angle steel 62, the lower pressing cylinder 61 and the pressing piece 63 are respectively connected with the upper end and the lower end of the corresponding angle steel 62, and the movable end of the lower pressing cylinder 61 is arranged opposite to the pressing piece 63 to clamp the supporting part 121.

In this embodiment, two opposite sides of the angle steel 62 are respectively provided with a pressing component 7, and the movable end of the pressing component 7 is lower than the bottom of the angle steel 62 to press against the solar photovoltaic panel 1.

In the present embodiment, the pressing assembly 7 includes a pressing member 71, a supporting member 72, and a stopper 73; the pressing piece 71 includes a free end and a pressing end 711 for pressing the solar photovoltaic panel 1; the hold-down piece 71 is connected with the angle steel 62 through the support piece 72, and the hold-down piece 71 is articulated with the support piece 72, and the pin joint is located the position that is close to the free end on the hold-down piece 71, and the locating part 73 is connected with the support piece 72 and is located the top of holding-down piece 71, and the locating part 73 sets up in the pin joint and is close to the one end of pressing end 711. Wherein, the pressing end 711 is provided with a roller, and the lower edge of the roller is lower than the bottom of the angle steel 62.

In this embodiment, the pressing assemblies 7 are provided in at least two, and the pressing assemblies 7 are uniformly distributed along the length direction of the angle steel 62.

In the present embodiment, the first traversing assembly 3 includes a linear motion assembly 31, a traversing carriage 32, and a sliding assembly 33; the upper end of the traversing bracket 32 is connected with the lifting frame 5 in a relatively sliding way through a sliding component 33, the fixed end of the linear motion component 31 is arranged on the lifting frame 5, and the movable end of the linear motion component 31 is connected with the traversing bracket 32. The linear motion assembly 31 is a linear push rod or a linear cylinder.

In the present embodiment, the lower end of the traverse bracket 32 extends in a direction away from the lift frame 5, and the clamp assembly 6 is connected to the lower end of the traverse bracket 32.

In this embodiment, the clamping mechanism further includes an induction component 8, in the width direction of the lifting frame 5, two ends of the lifting frame 5 are respectively provided with an induction component 8, and a movable space for the first traversing component 3 and the second traversing component 4 to move is provided between the induction component 8 and the lifting frame 5. The sensing component 8 is used for sensing the height difference between the solar photovoltaic panel 1 and the clamping component 6 on one hand and then can control the lifting height through the lifting component 2, and is used for sensing the distance between the solar photovoltaic panel 1 and the clamping component 6 in the width direction on the other hand so as to adjust the position of the lifting frame 5 through the transfer mechanism 10, so that the lifting frame 5 is arranged in the width direction relatively to the solar photovoltaic panel 1 in the middle.

In this embodiment, the sensing assembly 8 includes an extension rod 81 and an inductor 82, wherein the extension rod 81 has a first horizontal portion 811, a second horizontal portion 812 and a vertical portion 813 connected in sequence, and the first horizontal portion 811 and the second horizontal portion 812 are respectively mounted at the upper and lower ends of the vertical portion 813 and are respectively perpendicular to the vertical portion 813; the first horizontal portion 811 extends outwards in the width direction of the lifting frame 5, the length of the second horizontal portion 812 is smaller than that of the second horizontal portion 812, a space for giving way is formed between the second horizontal portion 812 and the vertical portion 813 and the clamping assembly 6, so that when the clamping assembly 6 descends, the frame 12 of the solar photovoltaic panel 1 falls into the space for giving way, the lower end of the vertical portion 813 extends downwards and is connected with the bottom of the clamping assembly 6, the inductor 82 is arranged on the second horizontal portion 812, and the induction ends of the two inductors 82 are arranged oppositely.

In this embodiment, the clamping mechanism further includes at least two vertically disposed guide rods 9, the transfer mechanism 10 is provided with at least two guide holders 92 coaxially disposed with the guide rods 9, and the guide rods 9 are connected with the lifting frame 5 and are disposed through the guide holders 92 so as to relatively slide in the axial direction of the guide rods 9. In this embodiment, four guide rods 9 are provided, and in order to improve stability of the lifting assembly 2, the upper ends of the screw rods 21 are respectively connected to the four guide rods 9 through a connecting frame 91.

The working principle of the embodiment is as follows:

the lifting assembly 2 controls the lifting frame 5 to descend, the first traversing assembly 3 and the second traversing assembly 4 move towards opposite directions and enable the pressing piece 63 of the clamping assembly 6 to extend between the supporting portion 121 and the photovoltaic glass 11, at this time, the pressing end 711 of the pressing piece 71 presses against the solar photovoltaic panel 1 and lifts up, the lifting assembly 2 controls the lifting frame 5 to ascend while the lower pressing cylinder 61 acts, the supporting portion 121 is clamped, the lifting assembly 2 ascends gradually, after the transfer mechanism 10 moves the solar photovoltaic panel 1 to a designated area, the lifting assembly 2 controls the lifting frame 5 to descend, the clamping assembly 6 releases, the first traversing assembly 3 and the second traversing assembly 4 move towards each other, and the lifting assembly 2 ascends and resets for the next action.

The foregoing description is only illustrative of the present utility model and is not intended to limit the scope of the utility model, and all equivalent changes made by the specification and drawings of the present utility model, or direct or indirect application in the relevant art, are included in the scope of the present utility model.

Claims (9)

1. The clamping mechanism of the solar photovoltaic panel sorting equipment comprises photovoltaic glass and a frame, wherein the frame is arranged around the photovoltaic glass, a supporting part which is arranged opposite to the photovoltaic glass is arranged in the frame, and a space is reserved between the supporting part and the photovoltaic glass;

the first traversing assembly and the second traversing assembly are respectively arranged at two ends of the lifting frame in the width direction and are connected with the lifting frame in a relatively sliding manner, and the first traversing assembly and the second traversing assembly can be gradually close to or gradually far away from each other;

one side of the first traversing assembly, which is far away from the second traversing assembly, is respectively provided with a clamping assembly.

2. The clamping mechanism of solar photovoltaic panel sorting equipment according to claim 1, wherein the clamping assembly comprises a pressing cylinder, angle steel and a pressing piece;

the lower ends of the first transverse moving assembly and the second transverse moving assembly are respectively connected with one angle steel, the lower pressing cylinder and the pressing piece are respectively connected with the upper end and the lower end of the corresponding angle steel, and the movable end of the lower pressing cylinder and the pressing piece are oppositely arranged to clamp the supporting part.

3. The clamping mechanism of solar photovoltaic panel sorting equipment according to claim 2, wherein two opposite sides of the angle steel are respectively provided with a pressing component, and the movable end of the pressing component is lower than the bottom of the angle steel so as to be propped against the solar photovoltaic panel.

4. A clamping mechanism of a solar photovoltaic panel sorting apparatus according to claim 3, wherein the compression assembly comprises a compression member, a support member and a limit member;

the pressing piece comprises a free end and a pressing end used for pressing the solar photovoltaic panel;

the pressing piece is connected with the angle steel through the supporting piece, the pressing piece is hinged with the supporting piece, the hinge point is located at the position, close to the free end, on the pressing piece, the limiting piece is connected with the supporting piece and located above the pressing piece, and the limiting piece is arranged at one end, close to the pressing end, of the hinge point.

5. A clamping mechanism of a solar photovoltaic panel sorting device according to claim 3, wherein at least two pressing assemblies are provided, and the pressing assemblies are uniformly distributed along the length direction of the angle steel.

6. The clamping mechanism of a solar photovoltaic panel sorting apparatus according to claim 1, wherein the first traversing assembly comprises a linear motion assembly, a traversing carriage, and a sliding assembly;

the upper end of the transverse moving support is connected with the lifting frame in a relatively sliding manner through the sliding component, the fixed end of the linear motion component is arranged on the lifting frame, and the movable end of the linear motion component is connected with the transverse moving support.

7. The clamping mechanism of a solar photovoltaic panel sorting apparatus according to claim 6, wherein the lower end of the traversing carriage extends in a direction away from the lifting carriage, and the clamping assembly is connected to the lower end of the traversing carriage.

8. The clamping mechanism of claim 1, further comprising an induction component, wherein in the width direction of the lifting frame, two ends of the lifting frame are respectively provided with the induction component, and a movable space for the first traversing component and the second traversing component to move is provided between the induction component and the lifting frame.

9. The clamping mechanism of solar photovoltaic panel sorting equipment according to claim 8, wherein the induction assembly comprises an extension rod and an inductor, the extension rod is provided with a first horizontal part, a second horizontal part and a vertical part which are sequentially connected, and the first horizontal part and the second horizontal part are respectively arranged at the upper end and the lower end of the vertical part in a mutually perpendicular manner with the vertical part;

the sensor is arranged on the second horizontal part;

the first horizontal part extends outwards in the width direction of the lifting frame, and the length of the second horizontal part is smaller than that of the second horizontal part, so that a yielding space is formed between the second horizontal part, the vertical part and the clamping assembly.