CN220011299U - Movable sucker assembly - Google Patents

Abstract

The utility model discloses a movable sucker assembly, which belongs to the technical field of photovoltaic panel processing equipment, and comprises a buffering sucker; the buffering adsorption piece comprises a driving cylinder, a first sucker, a guide rail and a moving plate which are mutually connected in a sliding manner in the vertical direction; one end of the moving plate in the moving direction is provided with a first sucking disc, and the other end of the moving plate is connected with the movable end of the driving cylinder; the driving cylinder applies force opposite to the movement direction of the downward-moving photovoltaic panel, and the moving panel is in sliding connection with the guide rail, so that the slow blanking of the photovoltaic panel can be realized through the gradual decompression of the driving cylinder; the problem of current adsorption equipment, when blanking speed is too fast, impact force is too big, lead to the photovoltaic board damaged easily is solved.

Description

Movable sucker assembly

Technical Field

The utility model belongs to the technical field of photovoltaic panel processing equipment, and particularly relates to a movable sucker assembly.

Background

In order to avoid that the photovoltaic panel is shaken during the assembly of the frame to affect the final installation effect, a certain number of adsorption devices are usually arranged below the photovoltaic panel.

The existing adsorption device is generally embedded with a sucker directly in a supporting plate so as to achieve the effect of positioning and adsorption. But the following problems exist in the actual use process:

1) Because the texture of backup pad is harder, if the speed that the photovoltaic board moved down is faster, makes photovoltaic board take place violently striking with the backup pad and scrape the photovoltaic board surface easily, causes even whole fracture to indirectly increase manufacturing cost.

2) Because the size of the photovoltaic panel can change along with the change of production requirement, so the optimal adsorption point positions of different batches of photovoltaic panels are also different, and because the structure of the existing adsorption device is that the sucker is embedded in the supporting plate, the position of the sucker is relatively fixed, and in order to ensure the adsorption reliability of the photovoltaic panel, a special adsorption device is required to be designed for the photovoltaic panels with different sizes, which increases the additional production cost.

Therefore, there is a need to design a movable chuck assembly that can not only effectively secure the photovoltaic panel, but also improve the flexibility of the chuck.

Disclosure of Invention

In order to overcome the defects in the prior art, the technical problems to be solved by the utility model are as follows: how to provide a movable sucker assembly which can not only effectively fix a photovoltaic panel, but also improve the flexibility of a sucker.

In order to solve the technical problems, the utility model adopts the following technical scheme: a movable sucker assembly comprises a buffering sucker; the buffering adsorption piece comprises a driving cylinder, a first sucker, a guide rail and a moving plate which are mutually connected in a sliding manner in the vertical direction; the upper end of the moving plate in the moving direction is provided with a first sucker; the lower end of the moving plate in the moving direction is connected with the movable end of the driving cylinder.

The device also comprises a supporting plate which is horizontally arranged, and at least three sliding absorption parts which are arranged on the supporting plate along the length direction of the supporting plate; the buffer absorbing parts are arranged between the sliding absorbing parts.

Wherein, the supporting plate is also provided with a first supporting column; the orientation of the first support column is consistent with that of the first sucker; the end face of the first support column far away from the support plate is a spherical surface.

The sliding adsorption piece comprises a base, a sliding plate and a second sucker; the base is in sliding connection with the sliding plate, and the displacement direction of the sliding plate is parallel to the horizontal plane; the second sucking disc sets up on the sliding plate and the orientation of second sucking disc is unanimous with first sucking disc.

Wherein, one side of the base is provided with a guide post with an axis direction consistent with the moving direction of the sliding plate; limiting blocks are arranged at two ends of the guide post; the limiting block is connected with the base; the base is provided with a guide block; and the guide block is connected with the guide column between the two limiting blocks in a sliding manner.

Wherein, the periphery of the second sucker is provided with a second support column; the second support column is oriented in the same direction as the second sucker.

Wherein, the two ends of the length direction of the supporting plate are also provided with connecting rods; the connecting rod is provided with a plurality of fixing holes matched with the supporting plate.

The utility model has the beneficial effects that: the movable sucker assembly provided by the utility model is simple in structure and convenient to use, when the photovoltaic panel falls, the driving cylinder can apply force opposite to the movement direction of the photovoltaic panel, and the movable panel is in sliding connection with the guide rail, so that after the photovoltaic panel is completely pressed on the first sucker, the driving cylinder gradually releases pressure to drive the photovoltaic panel to further move downwards, slow blanking is realized, and the condition of damage of the photovoltaic panel is avoided.

Drawings

FIG. 1 is a schematic view of a movable chuck assembly according to an embodiment of the present utility model;

FIG. 2 shows an enlarged view at A of FIG. 1;

FIG. 3 is a schematic view showing the structure of a sliding adsorption member according to an embodiment of the present utility model;

FIG. 4 is a schematic view of another movable chuck assembly according to an embodiment of the present utility model;

description of the reference numerals:

1. a buffer adsorption member; 11. a driving cylinder; 12. a first suction cup; 13. a guide rail; 14. a moving plate;

2. a support plate;

3. a sliding suction member; 31. a base; 32. a sliding plate; 33. a second suction cup; 34. a guide post; 35. a limiting block; 36. a guide block; 37. second support column

4. A first support column;

5. a connecting rod; 51. and a fixing hole.

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.

The most critical concept of the utility model is as follows: the driving cylinder applies force opposite to the movement direction of the downward-moving photovoltaic panel, and the moving panel is in sliding connection with the guide rail, so that the slow blanking can be realized through gradual decompression of the driving cylinder, and the damage condition of the photovoltaic panel is avoided.

Referring to fig. 1 to 3, the movable suction cup assembly provided by the present utility model includes a buffer suction member 1; the buffer adsorption member 1 includes a driving cylinder 11, a first suction cup 12, and a guide rail 13 and a moving plate 14 slidably connected to each other in a vertical direction; the upper end of the moving plate 14 in the moving direction is provided with a first sucker 12; the lower end of the moving plate in the moving direction is connected to the movable end of the driving cylinder 11.

From the above description, the beneficial effects of the utility model are as follows: the movable sucker assembly is provided, the driving air cylinder 11 applies force opposite to the movement direction of the downward moving photovoltaic panel, and the moving panel 14 is in sliding connection with the guide rail 13, so that the slow blanking of the photovoltaic panel can be realized through the gradual decompression of the driving air cylinder 11; the device simple structure, convenient operation compare with current adsorption equipment, can effectively avoid the damaged condition of photovoltaic board because of blanking speed is too fast, impact force is too big and arouse.

Further, the movable sucker assembly further comprises a horizontally arranged supporting plate 2 and at least three sliding suction members 3 arranged on the supporting plate 2 along the length direction of the supporting plate 2; the buffer absorbing part 1 is arranged between the sliding absorbing parts 3; the guide rail 13 is vertically connected with the support plate 2.

Further, a first support column 4 is also arranged on the support plate 2; the orientation of the first support column 4 is consistent with the orientation of the first sucker 12; the end surface of the first support column far away from the support plate 2 is a spherical surface.

Further, the sliding suction member 3 includes a base 31, a sliding plate 32, and a second suction cup 33; the base 31 is slidably connected with the sliding plate 32, and the displacement direction of the sliding plate 32 is parallel to the horizontal plane; the second suction cup 33 is provided on the slide plate 32 and the second suction cup 33 is oriented in line with the first suction cup 12.

From the above description, it is known that this design provides a sliding suction member 3 capable of freely changing the suction position in the horizontal plane, so that the worker can adjust the position of the sliding suction member 3 according to the actual size of the photovoltaic panel, thereby optimizing the overall suction effect; the first support column 4 can provide certain holding power when the photovoltaic board falls completely, and spherical terminal surface can reduce the area of contact with the photovoltaic board when the location to avoid appearing the problem of excessive location.

Further, a guide post 34 whose axis is oriented in accordance with the moving direction of the slide plate 32 is provided on one side of the base 31; limiting blocks 35 are arranged at two ends of the guide post 34; the limiting block 35 is connected with the base 31; the base 31 is provided with a guide block 36; the guide block 36 is slidably connected to the guide post 34 between the two stoppers 35.

As can be seen from the above description, the design can effectively limit the displacement distance of the sliding plate 32, and avoid the situation that the sliding plate 32 falls off from the base 31 due to the sliding travel of the sliding plate 32.

Further, a second support column 37 is provided on the periphery of the second suction cup 33; the second support column 37 is oriented in line with the second suction cup 33.

From the above description, after the photovoltaic panel slowly descends on the second adsorption disc, the support column can provide a certain supporting force for the photovoltaic panel before the second suction disc 33 adsorbs the photovoltaic panel, so as to avoid the condition that the photovoltaic panel falls down.

Further, connecting rods 5 are further arranged at two ends of the supporting plate 2 in the length direction; the connecting rod 5 is provided with a plurality of fixing holes 51 which are matched with the supporting plate 2.

From the above description, the design can enable the staff to set up a plurality of groups of movable sucker assemblies along the length direction of the connecting rod 5 according to the actual requirement, thereby further improving the adsorption stability of the photovoltaic panel.

The movable sucker assembly can assist in the adsorption positioning work of the panel, and is particularly suitable for fragile materials such as glass and photovoltaic panels.

The first embodiment of the utility model is as follows:

referring to fig. 1 to 3, a movable suction cup assembly includes a support plate 2 and a buffer suction member 1; the buffer adsorption member 1 includes a driving cylinder 11, a first suction cup 12, and a guide rail 13 and a moving plate 14 slidably connected to each other in a vertical direction; the upper end of the moving plate 14 in the moving direction is provided with a first sucker 12; the lower end of the moving plate in the moving direction is connected with the movable end of the driving cylinder 11; three sliding absorption parts 3 are arranged along the length direction of the supporting plate 2; the buffer absorbing part 1 is arranged between the sliding absorbing parts 3; the guide rail 13 is vertically connected with the support plate 2; the supporting plate 2 is also provided with a first supporting column 4; the orientation of the first support column 4 is consistent with the orientation of the first sucker 12; the end surface of the first support column 4 far away from the support plate 2 is a spherical surface; the sliding suction member 3 includes a base 31, a sliding plate 32, and a second suction cup 33; the base 31 is slidably connected with the sliding plate 32, and the displacement direction of the sliding plate 32 is parallel to the horizontal plane; the second suction cup 33 is arranged on the sliding plate 32 and the second suction cup 33 is oriented in accordance with the first suction cup 12; a guide post 34 whose axis is oriented in the same direction as the moving direction of the slide plate 32 is provided on one side of the base 31; limiting blocks 35 are arranged at two ends of the guide post 34; the limiting block 35 is connected with the base 31; the base 31 is provided with a guide block 36; the guide block 36 is in sliding connection with the guide post 34 between the two limiting blocks 35; a second support column 37 is arranged on the periphery of the second sucker 33; the second support column 37 is oriented in line with the second suction cup 33.

Referring to fig. 4, the second embodiment of the present utility model is different from the first embodiment in that the two ends of the support plate 2 in the length direction of the second embodiment are further provided with connecting rods 5; the connecting rod 5 is provided with a plurality of fixing holes 51 matched with the supporting plate 2; the staff can set up the activity sucking disc subassembly of multiunit utility model along the length direction of connecting rod 5 according to actual demand to further improve the adsorption stability of photovoltaic board.

The working principle of the utility model is as follows:

and (3) adjusting: according to the size of the photovoltaic panel produced, the worker moves the sliding plate 32 relative to the base 31 along the direction of the guide posts 34 by moving the sliding plate 32 so that the second suction cup 33 reaches a proper suction position; then, the driving cylinder 11 is inflated by the peripheral inflation equipment, so that the driving cylinder 11 has a certain supporting force.

Adsorption positioning: when the photovoltaic panel descends and is in contact with the first sucker 12 of the buffer absorption part 1, the pressure borne by the driving cylinder 11 is gradually increased until the force which can be applied by the driving cylinder 11 reaches a limit, the driving cylinder 11 slowly decompresses, and the photovoltaic panel is driven to further move downwards by the relative sliding of the moving plate 14 and the guide rail 13 until the photovoltaic panel is in contact with the second sucker 33 on the sliding absorption part 3; at this time, the photovoltaic panel is in a relatively stable state with the cooperation of the first support column 4 and the second support column 37; and then, the first sucker 12 and the second sucker 33 firmly adsorb the photovoltaic panel by the air suction effect of peripheral air suction equipment connected with the first sucker 12 and the second sucker 33, so that the photovoltaic panel can be kept stable during processing, and the high-quality production of the photovoltaic panel is ensured.

In summary, the movable sucker assembly provided by the utility model has the advantages of simple overall structure and convenience in operation; the driving cylinder applies force opposite to the movement direction of the downward-moving photovoltaic panel, and the moving panel is in sliding connection with the guide rail, so that the slow blanking of the photovoltaic panel can be realized through the gradual decompression of the driving cylinder; the defect that the photovoltaic panel is easy to damage when the blanking speed is too high and the impact force is too large in the existing adsorption device is overcome.

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 (7)

1. A movable sucker assembly, which is characterized by comprising a buffering sucker; the buffering adsorption piece comprises a driving cylinder, a first sucker, a guide rail and a moving plate which are mutually connected in a sliding manner in the vertical direction; the upper end of the moving plate in the moving direction is provided with a first sucker; the lower end of the moving plate in the moving direction is connected with the movable end of the driving cylinder.

2. The movable suction cup assembly of claim 1, further comprising a horizontally disposed support plate, and at least three sliding suction members disposed on the support plate along a length of the support plate; the buffer absorbing parts are arranged between the sliding absorbing parts; the guide rail is vertically connected with the supporting plate.

3. The movable suction cup assembly according to claim 2, wherein a first support column is further provided on the support plate; the orientation of the first support column is consistent with that of the first sucker; the end face of the first support column far away from the support plate is a spherical surface.

4. The movable suction cup assembly of claim 2 wherein the sliding suction attachment comprises a base, a sliding plate, and a second suction cup; the base is in sliding connection with the sliding plate, and the displacement direction of the sliding plate is parallel to the horizontal plane; the second sucking disc sets up on the sliding plate and the orientation of second sucking disc is unanimous with first sucking disc.

5. The movable sucker assembly of claim 4, wherein one side of the base is provided with a guide post with an axis oriented in line with the moving direction of the sliding plate; limiting blocks are arranged at two ends of the guide post; the limiting block is connected with the base; the base is provided with a guide block; and the guide block is connected with the guide column between the two limiting blocks in a sliding manner.

6. The movable suction cup assembly of claim 4 wherein a second support post is provided on the periphery of the second suction cup; the second support column is oriented in the same direction as the second sucker.

7. The movable sucker assembly of claim 2, wherein the two ends of the length direction of the support plate are also provided with connecting rods; the connecting rod is provided with a plurality of fixing holes matched with the supporting plate.