CN117817050B - Aluminum shell cutting device for battery aluminum shell production - Google Patents

Abstract

The invention relates to the technical field of battery aluminum shell processing, in particular to an aluminum shell cutting device for battery aluminum shell production, which comprises a carrying platform, wherein a feeding structure is arranged at the top end of the carrying platform, an adjusting structure is arranged at the bottom end of the carrying platform, a locking structure is arranged on the adjusting structure, a frame body is arranged at the side end of the carrying platform, a plurality of conveying rollers which are parallel to each other are rotationally connected to the frame body, a conveying belt is rotationally connected to the outer parts of the conveying rollers, and a cutting structure and a blanking structure are arranged on the frame body; through the setting of cutting structure, the person of facilitating the use changes the cutting knife, through installing the unloading structure, can promote the unloading with the battery aluminum hull after the cutting finishes.

Description

Aluminum shell cutting device for battery aluminum shell production

Technical Field

The invention relates to the technical field of battery aluminum shell processing, in particular to an aluminum shell cutting device for battery aluminum shell production.

Background technique

Aluminum shells are an important component of power batteries. At present, factories often need to use cutting devices when processing battery aluminum shells.

However, the cutting knife of the current battery aluminum shell cutting device is usually fixed by bolts, that is, multiple bolts are used to lock the handle of the cutting knife to the bottom end of the knife holder. This method requires repeated turning of multiple bolts during installation and disassembly, and the cutting knife is a vulnerable component, so it is inconvenient to install and disassemble the cutting knife.

Summary of the invention

In view of the problems in the prior art, the present invention provides an aluminum shell cutting device for producing battery aluminum shells.

The technical solution adopted by the present invention to solve its technical problems is: an aluminum shell cutting device for battery aluminum shell production, comprising a carrying platform, a feeding structure is installed on the top of the carrying platform, an adjusting structure is installed on the bottom of the carrying platform, a locking structure is arranged on the adjusting structure, a frame is arranged on the side end of the carrying platform, a plurality of mutually parallel conveying rollers are rotatably connected to the frame, a plurality of conveying rollers are rotatably connected to the outside with a conveyor belt, and a cutting structure and a unloading structure are installed on the frame.

Specifically, the cutting structure includes a mounting frame, a mounting frame is installed on the frame body, a first cylinder is installed on the mounting frame, a tool holder is installed on the telescopic end of the first cylinder, the tool holder is slidably connected between the mounting frames, a second cylinder is fixedly connected above the tool holder, a slide plate is fixedly connected to the output end of the second cylinder, two sliders are slidably connected inside the tool holder, a movable plate is fixedly connected to the bottom of the two sliders, a sliding block is slidably connected inside the two movable plates, the two sliding blocks are fixedly connected to the two ends of the slide plate respectively, a slot is provided at the bottom end of the two movable plates, and a cutting knife is engaged and connected in the slot.

Specifically, limiting blocks are fixedly connected to both sides of the output end of the second cylinder, and rubber pads are fixedly connected in the two slots.

Specifically, the feeding structure includes a vertical plate, and the top of the carrying platform is fixedly connected to two vertical plates in a symmetrical relationship, and a first guide roller and a second guide roller are rotatably connected between the two vertical plates.

Specifically, the unloading structure includes a first rotating shaft, which is rotatably connected to the side end of the frame, a pulley is fixedly connected to the outside of one of the conveying rollers and the first rotating shaft, and the two pulleys are driven by a transmission belt, and a turntable is also fixedly connected to the outside of the first rotating shaft, an extension plate is fixedly connected to the end of the frame, a moving block is slidably connected to the extension plate through a slide groove, a lifting rod is detachably connected to the side end of the moving block, the turntable and the moving block are connected by a rotating rod, and the two ends of the rotating rod are rotatably connected to the turntable and the moving block respectively.

Specifically, the slide groove is arranged obliquely, and the rotation point of the rotating rod and the rotating disk is located at the edge of the rotating disk.

Specifically, the adjustment structure includes a bracket, a bracket is provided at the bottom end of the carrying platform, a fixing sleeve is fixedly connected to the bottom end of the bracket, a lifting column is slidably connected inside the fixing sleeve, and the top end of the lifting column is fixed to the bottom end of the carrying platform, a first rack is fixedly connected to the side end of the lifting column, and a second rack is fixedly connected to the other side of the lifting column, a gear is rotatably connected inside the fixing sleeve, the gear is meshed with the second rack, a crank is fixedly connected to the center of the gear, and the crank extends to the outside of the fixing sleeve

Specifically, the locking structure includes a stopper, the stopper is slidably connected inside the fixing sleeve, a spring is sleeved outside the stopper, and a pull rod is fixedly connected to one end of the stopper.

Specifically, one end of the stopper is in a trapezoidal structure, and the upper end of the stopper abuts against the bottom end of the first rack.

The beneficial effects of the present invention are:

(1) The aluminum shell cutting device for producing battery aluminum shells described in the present invention can guide the battery aluminum shells by installing a feeding structure on a carrying platform, thereby preventing the battery aluminum shells from being offset during the conveying process.

(2) The aluminum shell cutting device for battery aluminum shell production described in the present invention facilitates the disassembly and assembly between the cutting knife and the knife holder through the cutting structure, making it convenient for the user to replace the cutting knife.

(3) The aluminum shell cutting device for battery aluminum shell production described in the present invention can push the battery aluminum shells that are placed on the conveyor belt after cutting to avoid bridging of the cut battery aluminum shells by installing a material discharge structure.

(4) The aluminum shell cutting device for battery aluminum shell production described in the present invention can appropriately raise and lower the guide assembly by setting an adjustment structure at the bottom end of the carrying platform so as to facilitate appropriate adjustment according to different usage environments, thereby achieving better connection of the conveying guide and increasing the conveying guide effect.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is further described below in conjunction with the accompanying drawings and embodiments.

FIG1 is a schematic diagram of the overall structure provided by the present invention;

FIG2 is an enlarged schematic diagram of the structure of section A shown in FIG1 ;

FIG3 is a schematic diagram of the connection structure between the mounting bracket and the first cylinder of the present invention;

FIG4 is an enlarged schematic diagram of the structure of part B shown in FIG3 ;

FIG5 is a schematic diagram of the connection structure between the conveyor roller and the pulley of the present invention;

FIG6 is a schematic diagram of the connection structure between the ejector rod and the moving block of the present invention;

FIG7 is a schematic cross-sectional view of the bracket and the fixing sleeve of the present invention;

FIG8 is an enlarged schematic diagram of the C portion structure shown in FIG7 ;

FIG9 is an enlarged schematic diagram of the D portion structure shown in FIG7 ;

In the figure: 1, carrying platform; 2, frame; 3, conveyor roller; 4, conveyor belt; 5, feeding structure; 501, vertical plate; 502, first guide roller; 503, second guide roller; 6, cutting structure; 601, mounting frame; 602, first cylinder; 603, knife holder; 604, second cylinder; 605, limit block; 606, slide plate; 607, slider; 608, moving plate; 609, cutting knife; 610, sliding block; 611, slot; 612, rubber pad; 7, lower Material structure; 701, pulley; 702, first rotating shaft; 703, transmission belt; 704, turntable; 705, extension plate; 706, slide groove; 707, moving block; 708, ejector rod; 709, rotating rod; 8, adjustment structure; 801, bracket; 802, fixing sleeve; 803, lifting column; 804, first rack; 805, second rack; 806, gear; 807, crank; 9, locking structure; 901, block; 902, spring; 903, pull rod.

Detailed ways

In order to make the technical means, creative features, objectives and effects achieved by the present invention easy to understand, the present invention is further explained below in conjunction with specific implementation methods.

As shown in Figures 1 to 9, an aluminum shell cutting device for battery aluminum shell production described in the present invention includes a carrying platform 1, a feeding structure 5 is installed on the top of the carrying platform 1, an adjusting structure 8 is installed on the bottom end of the carrying platform 1, a locking structure 9 is arranged on the adjusting structure 8, a frame 2 is arranged on the side end of the carrying platform 1, a plurality of mutually parallel conveying rollers 3 are rotatably connected to the frame 2, a plurality of conveying rollers 3 are rotatably connected to the outside with a conveyor belt 4, and a cutting structure 6 and a blanking structure 7 are installed on the frame 2.

Specifically, the cutting structure 6 includes a mounting frame 601, the mounting frame 601 is installed on the frame body 2, the first cylinder 602 is installed on the mounting frame 601, a tool holder 603 is installed at the telescopic end of the first cylinder 602, the tool holder 603 is slidably connected between the mounting frames 601, a second cylinder 604 is fixedly connected above the tool holder 603, a slide plate 606 is fixedly connected at the output end of the second cylinder 604, two sliders 607 are slidably connected inside the tool holder 603, a moving plate 608 is fixedly connected to the bottom of the two sliders 607, a sliding block 610 is slidably connected inside the two moving plates 608, the two sliding blocks 610 are fixedly connected to the two ends of the slide plate 606, respectively, a card slot 611 is provided at the bottom of the two moving plates 608, and a card slot 611 is carded and connected inside When the cutting knife 609 needs to be removed, the second cylinder 604 is started, and the second cylinder 604 drives the slide plate 606 to slide downward, and then the sliding blocks 610 at both ends of the slide plate 606 that are slidably connected in the moving plate 608 also slide downward, thereby driving the moving plate 608 to slide toward both sides of the knife holder 603, so that the distance of the card slot 611 at the bottom end of the moving plate 608 is increased, so that the cutting knife 609 is no longer engaged, and it is convenient to take the cutting knife 609 out of the card slot 611. Similarly, when installing the cutting knife 609, first put the cutting knife 609 into the card slot 611, start the second cylinder 604, and then drive the slide plate 606 to slide upward, and then the sliding blocks 610 at both ends of the slide plate 606 drive the moving plate 608 to slide relatively inward, thereby engaging and fixing the cutting knife 609 in the card slot 611.

Specifically, the limiting blocks 605 are fixedly connected to both sides of the output end of the second cylinder 604, and the two slots 611 are fixedly connected with rubber pads 612. By installing the limiting blocks 605, the slide plate 606 can slide more smoothly and ensure safety. At the same time, the rubber pads 612 are installed to increase the friction force on the cutting knife 609, so that the cutting knife 609 is more securely engaged.

Specifically, the feeding structure 5 includes a vertical plate 501, and the top of the carrying platform 1 is symmetrically fixedly connected to two vertical plates 501, and a first guide roller 502 and a second guide roller 503 are rotatably connected between the two vertical plates 501. Since the first guide roller 502 and the second guide roller 503 are rotatably connected between the two vertical plates 501, the battery aluminum shell passing therethrough can be rolled and guided, thereby avoiding the deviation of the conveyed battery aluminum shell.

Specifically, the unloading structure 7 includes a first rotating shaft 702, which is rotatably connected to the side end of the frame 2, a pulley 701 is fixedly connected to the outside of one of the conveying rollers 3 and the first rotating shaft 702, and the two pulleys 701 are driven by a transmission belt 703, and a turntable 704 is also fixedly connected to the outside of the first rotating shaft 702, an extension plate 705 is fixedly connected to the end of the frame 2, and a moving block 707 is slidably connected to the extension plate 705 through a slide groove 706, and a lifting rod 708 is detachably connected to the side end of the moving block 707, and the turntable 704 and the moving block 707 are connected by a rotating rod 709, and the two ends of the rotating rod 709 are respectively connected to the turntable 704 and the moving block 707. Dynamic connection, while the conveying roller 3 rotates, it will also drive the first rotating shaft 702 to rotate synchronously through the two pulleys 701 and the transmission belt 703. The rotation of the first rotating shaft 702 can drive the turntable 704 to rotate. Since there is a rotating rod 709 rotatably connected at the edge of the turntable 704, and the other end of the rotating rod 709 is rotatably connected to the moving block 707 sliding inside the slide groove 706, therefore, through the mechanical principle of the crank connecting rod, it can drive the moving block 707 to reciprocate left and right inside the slide groove 706, and can drive the ejecting rod 708 rotating on the moving block 707 to reciprocate left and right. Through the left and right pushing of the ejecting rod 708, the battery aluminum shells placed on the conveyor belt 4 after cutting can be pushed for unloading.

Specifically, the slide groove 706 is inclined, and the rotation point of the rotating rod 709 and the turntable 704 is located at the edge of the turntable 704. By locating the rotation point of the rotating rod 709 and the turntable 704 at the edge of the turntable 704, it is convenient to drive the ejecting rod 708 to move back and forth.

Specifically, the adjustment structure 8 includes a bracket 801, and a bracket 801 is provided at the bottom end of the carrying platform 1. A fixing sleeve 802 is fixedly connected to the bottom end of the bracket 801, and a lifting column 803 is slidably connected inside the fixing sleeve 802, and the top of the lifting column 803 is fixed to the bottom end of the carrying platform 1, and a first rack 804 is fixedly connected to the side end of the lifting column 803, and a second rack 805 is fixedly connected to the other side of the lifting column 803. A gear 806 is rotatably connected inside the fixing sleeve 802, and the gear 806 is meshed with the second rack 805. A crank 807 is fixedly connected to the center of the gear 806, and the crank 807 extends outside the fixing sleeve 802. When the height of the battery aluminum shell to be transported needs to be adjusted to adapt to subsequent processes, the crank 807 is shaken to drive the gear 806 to rotate, so that the gear 806 drives the second rack 805 to move, and then the lifting column 803 slides up and down to achieve adjustment of the carrying platform 1.

Specifically, the locking structure 9 includes a stopper 901, which is slidably connected inside the fixing sleeve 802, a spring 902 is sleeved outside the stopper 901, and a pull rod 903 is fixedly connected to one end of the stopper 901. Since the stopper 901 is also slidably connected inside the fixing sleeve 802, when the lifting column 803 rises, the first rack 804 on the lifting column 803 will be automatically limited and blocked by the stopper 901, that is, the lifting column 803 will be limited and fixed at this time, and will not automatically slide down, thereby realizing the locking function. When it is necessary to lower the carrying platform 1, it is only necessary to pull the stopper 901 so that the stopper 901 no longer blocks the first rack 804, which saves time and effort and is convenient and quick to operate.

Specifically, one end of the stopper 901 is in a trapezoidal structure, and the upper end of the stopper 901 abuts against the bottom end of the first rack 804. Since one end of the stopper 901 is in a trapezoidal structure and the stopper 901 abuts against the first rack 804, the limiting effect of the lifting column 803 is better.

When the present invention is in use, since the first guide roller 502 and the second guide roller 503 are rotatably connected between the two vertical plates 501, the battery aluminum shell passing therethrough can be rolled and guided, thereby preventing the conveyed battery aluminum shell from being offset. When the cutting knife 609 needs to be removed, the second cylinder 604 is started, and the second cylinder 604 drives the slide plate 606 to slide downward, and then the sliding blocks 610 at both ends of the slide plate 606 that are slidably connected in the moving plate 608 also slide downward, thereby driving the moving plate 608 to slide toward both sides of the knife holder 603, thereby increasing the distance between the card slots 611 at the bottom end of the moving plate 608, so that the cutting knife 609 is no longer subjected to the pressure. The cutting blade 609 is engaged with the card slot 611 to facilitate the removal of the cutting blade 609 from the card slot 611. Similarly, when installing the cutting blade 609, the cutting blade 609 is first placed in the card slot 611, and the second cylinder 604 is started, thereby driving the slide plate 606 to slide upward, and then the sliding blocks 610 at both ends of the slide plate 606 drive the moving plate 608 to slide relatively inward, so that the cutting blade 609 is engaged and fixed in the card slot 611. When the conveying roller 3 rotates, the first rotating shaft 702 is driven to rotate synchronously through the two pulleys 701 and the transmission belt 703. The rotation of the first rotating shaft 702 can drive the turntable 704 to rotate. Since there is a rotating connection at the edge of the turntable 704 The rotating rod 709, and the other end of the rotating rod 709 is rotatably connected to the moving block 707 sliding inside the slide groove 706. Therefore, through the mechanical principle of the crank connecting rod, the moving block 707 can be driven to reciprocate left and right inside the slide groove 706, and the ejecting rod 708 rotating on the moving block 707 can be driven to reciprocate left and right. By pushing the ejecting rod 708 left and right, the battery aluminum shells placed on the conveyor belt 4 after cutting can be pushed for unloading. When the height of the battery aluminum shell to be transported is adjusted to adapt to the subsequent process, the crank handle 807 is shaken to drive the gear 806 to rotate, so that the gear 806 drives The second rack 805 moves, and then the lifting column 803 slides up and down to adjust the carrying platform 1. Since a stopper 901 is slidably connected inside the fixing sleeve 802, and one end of the stopper 901 is a trapezoidal structure, when the lifting column 803 rises, the first rack 804 on the lifting column 803 will be automatically limited and blocked by the stopper 901, that is, the lifting column 803 will be limited and fixed at this time, and will not automatically slide down, thereby realizing the locking function. When the carrying platform 1 needs to be lowered, it is only necessary to pull the stopper 901 through the pull rod 903 so that the stopper 901 no longer blocks the first rack 804, which saves time and effort and is convenient and quick to operate.

It will be apparent to those skilled in the art that the invention is not limited to the details of the exemplary embodiments described above and that the invention can be implemented in other specific forms without departing from the spirit or essential features of the invention. Therefore, the embodiments should be considered exemplary and non-limiting in all respects, and the scope of the invention is defined by the appended claims rather than the foregoing description, and it is intended that all variations within the meaning and scope of the equivalent elements of the claims be included in the invention. Any reference numeral in a claim should not be considered as limiting the claim to which it relates.

In addition, it should be understood that although the present specification is described according to implementation modes, not every implementation mode contains only one independent technical solution. This description of the specification is only for the sake of clarity. Those skilled in the art should regard the specification as a whole. The technical solutions in each embodiment may also be appropriately combined to form other implementation modes that can be understood by those skilled in the art.

Claims (4)

1. An aluminum shell cutting device for battery aluminum shell production, characterized in that it comprises a carrying platform (1), a feeding structure (5) is installed at the top of the carrying platform (1), an adjusting structure (8) is installed at the bottom of the carrying platform (1), a locking structure (9) is arranged on the adjusting structure (8), a frame (2) is arranged at the side end of the carrying platform (1), a plurality of mutually parallel conveying rollers (3) are rotatably connected to the frame (2), a plurality of conveying rollers (3) are rotatably connected to the outside of the plurality of conveying rollers (3), and a cutting structure (6) and a material discharge structure (7) are installed on the frame (2); The cutting structure (6) comprises a mounting frame (601), the mounting frame (601) being mounted on the frame body (2), the mounting frame (601) being mounted on a first cylinder (602), a tool holder (603) being mounted on the telescopic end of the first cylinder (602), the tool holder (603) being slidably connected between the mounting frames (601), a second cylinder (604) being fixedly connected above the tool holder (603), a slide plate (606) being fixedly connected at the output end of the second cylinder (604), two sliders (607) being slidably connected inside the tool holder (603), a moving plate (608) being fixedly connected at the bottom of the two sliders (607), a sliding block (610) being slidably connected inside the two moving plates (608), the two sliding blocks (610) being fixedly connected to two ends of the slide plate (606) respectively, a clamping groove (611) being provided at the bottom of the two moving plates (608), a cutting knife (609) being clamped and connected in the clamping groove (611); Limiting blocks (605) are fixedly connected to both sides of the output end of the second cylinder (604), and rubber pads (612) are fixedly connected in the two slots (611); The feeding structure (5) comprises a vertical plate (501), the top of the carrying platform (1) is symmetrically and fixedly connected to two vertical plates (501), and a first guide roller (502) and a second guide roller (503) are rotatably connected between the two vertical plates (501); The unloading structure (7) comprises a first rotating shaft (702), which is rotatably connected to the side end of the frame (2), a pulley (701) is fixedly connected to the outside of one of the conveying rollers (3) and the first rotating shaft (702), and the two pulleys (701) are driven by a transmission belt (703), a turntable (704) is also fixedly connected to the outside of the first rotating shaft (702), an extension plate (705) is fixedly connected to the end of the frame (2), a moving block (707) is slidably connected to the extension plate (705) via a slide groove (706), a ejecting rod (708) is detachably connected to the side end of the moving block (707), the turntable (704) and the moving block (707) are connected via a rotating rod (709), and the two ends of the rotating rod (709) are rotatably connected to the turntable (704) and the moving block (707), respectively. The slide groove (706) is arranged in an inclined manner, and the rotation point of the rotating rod (709) and the rotating disk (704) is located at the edge of the rotating disk (704). 2. An aluminum shell cutting device for battery aluminum shell production according to claim 1, characterized in that: the adjustment structure (8) includes a bracket (801), a bracket (801) is provided at the bottom end of the carrying platform (1), a fixing sleeve (802) is fixedly connected to the bottom end of the bracket (801), a lifting column (803) is slidably connected inside the fixing sleeve (802), and the top of the lifting column (803) is fixed to the bottom end of the carrying platform (1), a first rack (804) is fixedly connected to the side end of the lifting column (803), and a second rack (805) is fixedly connected to the other side of the lifting column (803), a gear (806) is rotatably connected inside the fixing sleeve (802), the gear (806) is meshed with the second rack (805), and a crank (807) is fixedly connected to the center of the gear (806), and the crank (807) extends outside the fixing sleeve (802). 3. An aluminum shell cutting device for battery aluminum shell production according to claim 2, characterized in that: the locking structure (9) includes a stopper (901), the stopper (901) is slidably connected inside the fixing sleeve (802), a spring (902) is sleeved outside the stopper (901), and a pull rod (903) is fixedly connected to one end of the stopper (901). 4. An aluminum shell cutting device for battery aluminum shell production according to claim 3, characterized in that one end of the stopper (901) is a trapezoidal structure, and the upper end of the stopper (901) is in contact with the bottom end of the first rack (804).