CN222289663U - A processing device for aluminum shell for new energy battery - Google Patents

Abstract

The utility model relates to the technical field of aluminum shell processing, in particular to a processing device of an aluminum shell for a new energy battery, by arranging a feeding mechanism, a worker places the aluminum shell at the top of a box body, a screw rod rotates to drive a connecting rod to rise, the box body drives the aluminum shell to rise between two clamping strips, the electric push rod drives the clamping strip to extend out to clamp the aluminum shell, the box body supports the aluminum shell at the bottom, and the polishing roller descends to polish the aluminum shell. The dust collection device comprises a base, wherein a portal frame is arranged at the top of the base, a moving mechanism is arranged on the portal frame, an electric cylinder is arranged on the moving mechanism, a polishing roller is arranged below the electric cylinder, the output end of the electric cylinder is connected with the polishing roller through a dust collection mechanism, a clamping turnover mechanism is arranged on the side wall of the portal frame, and a feeding mechanism with dust collection and support functions is arranged below the clamping turnover mechanism.

Description

Processing device of aluminum shell for new energy battery

Technical Field

The utility model relates to the technical field of aluminum shell processing, in particular to a processing device of an aluminum shell for a new energy battery.

Background

With the development of science and technology, new energy batteries have become mainstream, and in the application field of new energy batteries, an aluminum shell with a protection function is arranged outside the battery.

Publication No.: CN212044002U relates to new energy battery technical field, specifically is a new energy battery aluminum hull grinding device, including base, frame, upset subassembly, clamping component, lifting unit, moving assembly, adjusting part and grinding device polish, the frame of polishing is L type, the fixed intermediate position that sets up at the base of one end of frame of polishing, the fixed rear that sets up the frame of polishing on the base of upset subassembly, clamping unit is fixed to be set up on the upset subassembly, lifting unit is fixed to be set up at the top of frame of polishing, moving assembly is fixed to be set up on lifting unit, adjusting part is fixed to be set up on moving assembly, grinding device is fixed to be set up on adjusting part, the cooperation through each subassembly of the utility model can be with the operation of new energy battery aluminum hull automatic upset of polishing, need not manual upset, has improved work efficiency, and the practicality is higher.

The applicant finds that the clamping cylinder drives the clamping plate to clamp the aluminum shell in use, but the bottom of the aluminum shell is not supported, the aluminum shell is not stable enough in polishing, and because of the lack of a dust removing function, dust particles and dust generated in polishing can be scattered in the air to pollute the environment.

Therefore, the utility model designs a processing device of an aluminum shell for a new energy battery to solve the problems in the prior art.

Disclosure of utility model

The utility model aims to provide a processing device of an aluminum shell for a new energy battery, which aims to solve the problems in the background technology.

The processing device for the aluminum shell for the new energy battery comprises a base, wherein a portal frame is arranged at the top of the base, a moving mechanism is arranged on the portal frame, an electric cylinder is arranged on the moving mechanism, a polishing roller is arranged below the electric cylinder, the output end of the electric cylinder is connected with the polishing roller through a dust suction mechanism, a clamping turnover mechanism is arranged on the side wall of the portal frame, and a feeding mechanism with dust suction and supporting functions is arranged below the clamping turnover mechanism.

Preferably, the moving mechanism comprises a screw rod, the screw rod is rotatably arranged between two side walls above the portal frame, a screw block is arranged on the outer side wall of the screw rod through a threaded sliding fit, the top of the screw block is in sliding connection with the top inner wall of the portal frame, a mounting groove is formed in the bottom of the screw block, the electric cylinder is arranged in the mounting groove, the screw rod positively and negatively rotates, the screw block is driven to transversely move left and right, and a polishing roller can be made to move back and forth to polish different positions of an aluminum shell.

Preferably, the dust collection mechanism comprises a dust collection box, the top of the dust collection box is connected with the output end of the electric cylinder, a plurality of suction nozzles are arranged in the middle of the bottom of the dust collection box, a square cylinder is arranged on the periphery of the bottom of the dust collection box, the polishing roller is rotatably arranged between the two ends of the square cylinder, and the suction nozzles collect dust and debris generated by polishing, so that the dust is prevented from being scattered into the air to pollute the environment.

Preferably, the clamping turnover mechanism comprises two electric push rods, the two electric push rods are respectively and rotatably arranged on side walls of two sides of the portal frame, the output end of each electric push rod is connected with a holding strip, each electric push rod drives the holding strip to extend out, the aluminum shell can be clamped, and the electric push rods can turn over the aluminum shell by 180 degrees.

Preferably, the feeding mechanism comprises a box body, grooves are formed in the lower portions of the inner walls of two sides of the portal frame, a screw rod which is rotatably installed with the portal frame is arranged in the grooves, connecting rods are slidably installed on the outer side walls of the screw rod through threads, the two connecting rods are respectively connected with the two sides of the box body, the screw rod rotates to drive the connecting rods to rise, the box body is driven to rise, the bottom support of the aluminum shell can be achieved, and the stability of the aluminum shell during polishing is improved.

Preferably, a plurality of round holes are formed in the top of the box body, when the aluminum shell is turned over, scraps drop downwards, and the round holes can collect scraps again, so that the dust collection effect is improved.

Compared with the prior art, the utility model has the following beneficial effects:

1. According to the utility model, through the arrangement of the feeding mechanism, a worker places the aluminum shell on the top of the box body, the screw rod rotates to drive the connecting rod to ascend, so that the box body drives the aluminum shell to ascend between the two clamping bars, the electric push rod drives the clamping bars to extend out to clamp the aluminum shell, the box body supports the aluminum shell at the bottom, and the polishing roller descends to polish the aluminum shell, so that compared with a comparison document, the aluminum shell is more stable during polishing through the support of the bottom of the aluminum shell;

2. According to the utility model, through the arrangement of the feeding mechanism and the dust collection mechanism, when polishing, the suction nozzle sucks a part of dust into the dust collection box to prevent the dust and dust from being scattered in the air to pollute the environment, and a part of uninflated dust is adhered to the surface of the aluminum shell, the aluminum shell falls downwards when turned over, and the round holes absorb the fallen dust, so that the dust collection effect is further improved.

Drawings

FIG. 1 is a schematic view in front cross-section of the present utility model;

FIG. 2 is a schematic side cross-sectional view of a vacuum mechanism of the present utility model;

fig. 3 is a schematic top view of the case structure of the present utility model.

The device comprises a base, a portal frame, a moving mechanism, an electric cylinder, a grinding roller, a dust suction mechanism, a clamping turnover mechanism, a feeding mechanism, a 301, a screw rod, a 302, a wire block, a 303, a mounting groove, a 601, a dust suction box, a 602, a suction nozzle, a 603, a square cylinder, a 701, an electric push rod, a 702, a holding strip, a 801, a box, a 802, a groove, a 803, a screw rod, a 804, a connecting rod, a 805 and a round hole.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-3, the processing device for the aluminum shell for the new energy battery comprises a base 1, wherein a portal frame 2 is arranged at the top of the base 1, a moving mechanism 3 is arranged on the portal frame 2, an electric cylinder 4 is arranged on the moving mechanism 3, a grinding roller 5 is arranged below the electric cylinder 4, an output end of the electric cylinder 4 is connected with the grinding roller 5 through a dust suction mechanism 6, a clamping turnover mechanism 7 is arranged on the side wall of the portal frame 2, and a feeding mechanism 8 with dust suction and supporting functions is arranged below the clamping turnover mechanism 7.

Referring to fig. 1, in the present embodiment, the moving mechanism 3 includes a screw rod 301, the screw rod 301 is rotatably installed between two side walls above the gantry 2, a screw block 302 is slidably installed on an outer side wall of the screw rod 301 through threads, a mounting groove 303 is formed in the bottom of the screw block 302, an electric cylinder 4 is disposed in the mounting groove 303, one side of the screw rod is connected with an output end of the moving motor, a limit bar is installed on the top of the screw block, a limit groove is formed in the bottom inner wall of the gantry, and the limit bar slides in the limit groove.

Referring to fig. 1-2, in the present embodiment, the dust collection mechanism 6 includes a dust collection box 601, a top of the dust collection box 601 is connected with an output end of the electric cylinder 4, a plurality of suction nozzles 602 are provided in a middle of a bottom of the dust collection box 601, a square cylinder 603 is mounted on a periphery of the bottom of the dust collection box 601, a polishing roller 5 is rotatably mounted between two ends of the square cylinder 603, a first dust collector is mounted on a top of the portal frame, the first dust collector is communicated with one end of the dust collection box through a hose, two ends of the square cylinder are rotatably mounted with rotating shafts, two ends of the polishing roller are connected with the rotating shafts, and one end of one rotating shaft is connected with an output end of the polishing motor.

Referring to fig. 1-3, in this embodiment, the clamping and turning mechanism 7 includes two electric push rods 701, the two electric push rods 701 are rotatably mounted on two side walls of the gantry 2, an output end of each electric push rod 701 is connected with a clamping strip 702, a rubber strip is arranged on one side of each clamping strip, friction force with an aluminum shell can be improved, clamping stability is improved, and one side of each electric push rod is connected with an output end of a turning motor.

Referring to fig. 1, in the present embodiment, a feeding mechanism 8 includes a box 801, grooves 802 are formed below inner walls of two sides of a gantry 2, a screw 803 rotatably mounted on the gantry 2 is disposed in the grooves 802, a connecting rod 804 is slidably mounted on an outer side wall of the screw 803 through threads, the two connecting rods 804 are respectively connected with two sides of the box 801, a motor groove is formed in a base, a motor is mounted in the motor groove, and a bottom of the screw penetrates through the motor groove and is connected with an output end of the motor.

Referring to fig. 1-3, in this embodiment, a plurality of round holes 805 are formed in the top of the case 801, and a second vacuum cleaner is mounted on one side of the gantry, and the second vacuum cleaner is communicated with one end of the case through a hose, so that the round holes generate negative pressure to perform dust collection.

The aluminum shell is placed on the box body 801, the screw 803 synchronously rotates to drive the connecting rod 804 to rise, the box body 801 rises, the aluminum shell is sent between the two clamping bars 702, the electric push rod 701 drives the clamping bars 702 to stretch out to clamp two sides of the aluminum shell, the electric cylinder 4 drives the grinding roller 5 to descend to grind the surface of the aluminum shell, the box body 801 plays a role in supporting the aluminum shell, the stability of the aluminum shell during grinding is improved, after one surface of the aluminum shell is ground, the box body 801 descends, the electric push rod 701 rotates 180 degrees to turn over the aluminum shell, the box body 801 rises to continuously support the aluminum shell after turning over, and the grinding roller 5 continuously grinds the aluminum shell;

During polishing, the suction nozzle 602 generates negative pressure, and the scraps are sucked into the suction box 601 and then enter the dust collector at the top of the portal frame 2 to be collected, when the aluminum shell is turned over, some scraps which are attached to the aluminum shell and are not sucked away drop downwards, the round hole 805 generates negative pressure, and the scraps are sucked into the box 801 and then enter the dust collector at one side of the portal frame 2 to be collected, so that the scraps are prevented from being scattered into the air to pollute the environment, and the matters which are not described in detail in the specification belong to the prior art known to the person skilled in the art.

Although the present utility model has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present utility model.

Claims (6)

1. A processing device for aluminum shells for new energy batteries, comprising: a base (1), characterized in that: a gantry (2) is installed on the top of the base (1), a moving mechanism (3) is provided on the gantry (2), an electric cylinder (4) is provided on the moving mechanism (3), a grinding roller (5) is provided below the electric cylinder (4), the output end of the electric cylinder (4) is connected to the grinding roller (5) through a dust suction mechanism (6), a clamping and flipping mechanism (7) is provided on the side wall of the gantry (2), and a feeding mechanism (8) with dust suction and supporting functions is provided below the clamping and flipping mechanism (7). 2. A processing device for an aluminum shell for a new energy battery according to claim 1, characterized in that: the moving mechanism (3) includes a screw rod (301), the screw rod (301) is rotatably installed between the two side walls above the gantry (2), the outer wall of the screw rod (301) is slidably installed with a screw block (302) through a thread, the top of the screw block (302) is slidably connected to the top inner wall of the gantry (2), the bottom of the screw block (302) is provided with a mounting groove (303), and the electric cylinder (4) is arranged in the mounting groove (303). 3. According to claim 1, a processing device for an aluminum shell for a new energy battery is characterized in that: the dust suction mechanism (6) includes a dust suction box (601), the top of the dust suction box (601) is connected to the output end of the electric cylinder (4), a plurality of suction nozzles (602) are provided in the middle of the bottom of the dust suction box (601), a square tube (603) is installed on the outer periphery of the bottom of the dust suction box (601), and the grinding roller (5) is rotatably installed between the two ends of the square tube (603). 4. According to claim 1, a processing device for aluminum shells for new energy batteries is characterized in that: the clamping and flipping mechanism (7) includes two electric push rods (701), and the two electric push rods (701) are rotatably installed on the side walls of the gantry (2) respectively, and the output end of the electric push rod (701) is connected to a clamping strip (702). 5. According to claim 1, a processing device for an aluminum shell for a new energy battery is characterized in that: the feeding mechanism (8) includes a box body (801), and grooves (802) are provided below the inner walls on both sides of the gantry (2), and a screw (803) rotatably mounted with the gantry (2) is provided in the groove (802), and a connecting rod (804) is installed on the outer wall of the screw (803) through a threaded sliding, and the two connecting rods (804) are respectively connected to the two sides of the box body (801). 6. The processing device for an aluminum shell for a new energy battery according to claim 5 is characterized in that a plurality of circular holes (805) are opened on the top of the box body (801).