CN216104158U - Automatic stacking device for aluminum plate strip production wafers - Google Patents

Abstract

The utility model discloses an automatic stacking device for producing wafers by aluminum strips, which comprises a first motor, a first bevel gear, a second bevel gear, a screw rod, a fixed shaft, a sleeve block and a cylinder, wherein the first motor is fixedly arranged at the top end of a support frame, the output end of the first motor is fixedly connected with the first bevel gear, the top end of the support frame is connected with the second bevel gear in a shaft mode, the bottom side of the second bevel gear is connected with the first bevel gear, the shaft end of the second bevel gear is connected with the screw rod, the top end of the support frame is fixedly provided with the fixed shaft, the fixed shaft and the outer end of the screw rod are connected with the sleeve block, and the outer end of the sleeve block is fixedly provided with the cylinder. This automatic pile device that stacks of aluminum plate area production disk is provided with screw rod and cover block, makes the screw rod carry out the simultaneous movement through the rotation that the motor drove bevel gear group, and the cover block drives bearing mechanism and carries out the ascending displacement of horizontal direction, drives bearing mechanism through the promotion of cylinder and carries out the ascending displacement of vertical side for bearing mechanism stabilizes the efficient transport to the aluminum disk that conveys the conveyer belt output.

Description

Automatic stacking device for aluminum plate strip production wafers

Technical Field

The utility model relates to the technical field of aluminum industry aluminum wafer production, in particular to an automatic stacking device for aluminum plate strip production wafers.

Background

The aluminum plate strip can be used for manufacturing a large number of aluminum wafers in production, can be used in industries such as electric appliances, mechanical manufacturing, automobiles and the like, and has excellent tensile strength and processing performance, the aluminum wafers are required to be automatically stacked through a stacking device in the production process, but the existing stacking device has certain defects, such as defects;

the automatic pile device that stacks of present aluminium slab band production disk is when using, and is unstable to the transport of aluminium disk, and the aluminium disk piles up neatly, and the protectiveness when receiving the striking is relatively poor simultaneously, easily takes place to pile up the deformation, and the aluminium disk after piling up easily appears scattering when transporting simultaneously.

Aiming at the problems, innovative design is urgently needed on the basis of the original automatic stacking device.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an automatic stacking device for aluminum plate strip production wafers, which solves the problems that the existing automatic stacking device for aluminum plate strip production wafers in the background art is unstable in conveying of aluminum wafers, irregular in stacking of aluminum wafers, poor in protection when impacted, prone to stacking deformation and prone to scattering during transportation of stacked aluminum wafers.

In order to achieve the purpose, the utility model provides the following technical scheme: an automatic stacking device for aluminum plate strip production wafers mainly comprises a conveyor belt, a support frame and a fixed block, wherein the support frame is arranged at the side end of the conveyor belt, and the fixed block for loading products is arranged at the inner side of the support frame;

the method comprises the following steps:

the first motor is fixedly arranged at the top end of the support frame, the output end of the first motor is fixedly connected with a first bevel gear, the top end of the support frame is connected with a second bevel gear, the bottom side of the second bevel gear is connected with the first bevel gear, the shaft end of the second bevel gear is connected with a screw rod, the top end of the support frame is fixedly provided with a fixed shaft, the fixed shaft and the outer end of the screw rod are connected with a sleeve block, the outer end of the sleeve block is fixedly provided with a cylinder, the output end of the cylinder is connected with a support rod, the bottom end of the support rod is fixedly connected with a top block, the upper end of the top block is fixedly provided with a second motor, the inner end of the top block is provided with a fixed gear, the shaft end of the fixed gear is connected with the output end of the second motor, the inner end of the top block is provided with a movable block, the inner side of the movable block is provided with a rack, and the rack is in meshed connection with the fixed gear, the bottom end of the movable block is fixedly provided with a bearing rod, and the bottom end of the movable block is provided with a clamping groove;

and the limiting shaft is arranged at the upper end of the fixing block, and a supporting disk is fixedly arranged at the upper end of the fixing block.

Preferably, the first bevel gear is in meshed connection with the second bevel gear, the second bevel gear shaft end is fixedly connected with the head end of the screw, the screw is in threaded connection with the sleeve block, and the screw is driven to rotate through meshed transmission of the bevel gear set, so that the sleeve block on the outer surface of the screw moves in the horizontal direction.

Preferably, the collets are in sliding connection with the fixed shaft, the air cylinder is fixedly mounted at the outer end of the collets, the supporting rod and the ejecting block form a lifting structure through the air cylinder output end and the supporting frame, and the supporting structure is driven to move in the vertical direction through the air cylinder.

Preferably, the supporting rod and the top block are of a fixed integrated structure, two groups of movable blocks are arranged at the inner ends of the top block, racks are mounted on the inner sides of the two groups of movable blocks, and the racks are meshed with the fixed gear.

Preferably, the bottom welded connection of movable block has the bearing rod, and the bearing rod top constitutes the block structure through draw-in groove and another group of movable block, is connected through the meshing of gear and rack and drives the movable block and remove and make the bearing structure open or closed.

Preferably, four groups of limiting shafts are uniformly distributed and mounted at the upper end of the fixing block, the inner sides of the limiting shafts are attached to the outer surface of the aluminum wafer, a supporting disc for supporting the aluminum wafer is fixedly mounted at the upper end of the fixing block, and the aluminum wafer is limited and stacked through the limiting shafts.

Compared with the prior art, the utility model has the beneficial effects that: the automatic stacking device for the aluminum plate strip production wafers;

1. the device is provided with a screw rod and a sleeve block, the screw rod is driven to synchronously move by a motor to drive a bevel gear set to rotate, the sleeve block drives a bearing mechanism to displace in the horizontal direction, the bearing mechanism is driven to displace in the vertical direction by the pushing of an air cylinder, and the bearing mechanism is enabled to stably and efficiently convey the aluminum wafer at the output end of a conveying belt;

2. be provided with spacing axle and supporting disk, carry out the bearing to the aluminium disk through the supporting disk, the rethread multiunit spacing axle is piled up the aluminium disk and is placed, makes it neatly pile up, has both played the effect of striking protection to the aluminium disk, avoids stacked structure to warp, and the follow-up shipment of also being convenient for is difficult for scattering.

Drawings

FIG. 1 is a schematic view of the overall front view structure of the present invention;

FIG. 2 is a side cross-sectional structural view of the top block of the present invention;

FIG. 3 is a schematic top view of the movable block of the present invention;

FIG. 4 is a schematic bottom view of the support plate of the present invention;

fig. 5 is a schematic perspective view of a spacing shaft according to the present invention.

In the figure: 1. a conveyor belt; 2. a support frame; 3. a first motor; 4. a first bevel gear; 5. a second bevel gear; 6. a screw; 7. a fixed shaft; 8. sleeving blocks; 9. a cylinder; 10. a support bar; 11. a top block; 12. a second motor; 13. fixing a gear; 14. a movable block; 15. a rack; 16. a support rod; 17. a card slot; 18. a fixed block; 19. a limiting shaft; 20. and (4) supporting the disc.

Detailed Description

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

Referring to fig. 1-5, the present invention provides a technical solution: an automatic stacking device for aluminum plate strip production wafers mainly comprises a conveyor belt 1, a support frame 2 and a fixing block 18, wherein the support frame 2 is arranged at the side end of the conveyor belt 1, and the fixing block 18 for loading products is arranged at the inner side of the support frame 2;

the method comprises the following steps:

the first motor 3 is fixedly arranged at the top end of the support frame 2, the output end of the first motor 3 is fixedly connected with a first bevel gear 4, the top end of the support frame 2 is connected with a second bevel gear 5 through a shaft, the bottom side of the second bevel gear 5 is connected with the first bevel gear 4, the shaft end of the second bevel gear 5 is connected with a screw 6, the top end of the support frame 2 is fixedly provided with a fixed shaft 7, the fixed shaft 7 is connected with the outer end of the screw 6 and is provided with a sleeve block 8, the outer end of the sleeve block 8 is fixedly provided with a cylinder 9, the output end of the cylinder 9 is connected with a support rod 10, the bottom end of the support rod 10 is fixedly connected with a top block 11, the upper end of the top block 11 is fixedly provided with a second motor 12, the inner end of the top block 11 is provided with a fixed gear 13, the shaft end of the fixed gear 13 is connected with the output end of the second motor 12, the inner end of the top block 11 is provided with a movable block 14, and the inner side of the movable block 14 is provided with a rack 15, the rack 15 is meshed with the fixed gear 13, the bottom end of the movable block 14 is fixedly provided with a bearing rod 16, and the bottom end of the movable block 14 is provided with a clamping groove 17;

and the limiting shaft 19 is arranged at the upper end of the fixing block 18, and a supporting disc 20 is fixedly arranged at the upper end of the fixing block 18.

First bevel gear 4 is connected for the meshing with second bevel gear 5, and 5 axle heads of second bevel gear are fixed connection with the 6 head ends of screw rod, and screw rod 6 is threaded connection with set piece 8, set piece 8 is sliding connection with fixed axle 7, and 8 outer end fixed mounting of set piece have cylinder 9, bracing piece 10 and kicking block 11 pass through cylinder 9 output and support frame 2 constitution elevation structure, bracing piece 10 and kicking block 11 are fixed integral structure, and kicking block 11 the inner is provided with two sets of movable block 14, and rack 15 is all installed to two sets of movable block 14's inboard, rack 15 is connected for the meshing with fixed gear 13 simultaneously, the bottom welded connection of movable block 14 has bearing rod 16, and bearing rod 16 top passes through draw-in groove 17 and constitutes the block structure with another set of movable block 14.

The aluminum wafer is conveyed by the conveyor belt 1 after being manufactured, at the moment, the second motor 12 can be started to enable the output end of the second motor to drive the fixed gear 13 to rotate, the rack 15 meshed and connected with the outer side of the fixed gear 13 rotates to drive the two movable blocks 14 to move, the two movable blocks 14 move oppositely at the inner end of the top block 11 and contract towards the center, finally the bearing rod 16 at the bottom end of the movable block 14 is in clamping and butt joint with the bottom end of the other movable block 14 through the clamping groove 17 to form a bearing structure, the first motor 3 is started to drive the first bevel gear 4 and the second bevel gear 5 to carry out meshing transmission so that the screw 6 rotates, the sleeve block 8 in threaded connection with the outer surface of the screw 6 drives the cylinder 9, the support rod 10 and the bottom end structure to synchronously move to the output end of the conveyor belt 1, at the moment, the bearing structure formed by the two movable blocks 14 and the bearing rod 16 can bear the aluminum wafer, and the aluminum wafer is prevented from falling off in the conveying process through the extrusion effect of the bottom ends of the two groups of movable blocks 14 on the aluminum wafer.

Four groups of limiting shafts 19 are uniformly distributed and mounted at the upper end of the fixing block 18, the inner sides of the limiting shafts 19 are attached to the outer surface of the aluminum wafer, and a supporting disc 20 for supporting the aluminum wafer is fixedly mounted at the upper end of the fixing block 18.

Through the work of controlling first motor 3 and cylinder 9 for the aluminium disk that bearing rod 16 and movable block 14 bore moves down through the center of four sets of spacing axles 19, when bearing rod 16 reachd spacing axle 19 bottoms, the aluminium disk will be born by supporting disk 20, start second motor 12 this moment and carry out the reversal, can make two sets of movable blocks 14 leave after reseing, carry out the pile through the spacing axle 19 of multiunit to the aluminium disk, make it neatly place, the follow-up shipment of also being convenient for is transported, difficult scatter.

The working principle is as follows: when the automatic stacking and stacking device for producing the wafers by using the aluminum plate strip is used, according to the graph shown in fig. 1-5, the device is firstly placed at a position needing to work, the output end of the second motor 12 drives the fixed gear 13 to be meshed and connected with the rack 15 to drive the two groups of movable blocks 14 to move oppositely, the supporting rod 16 at the bottom end of each movable block 14 forms a supporting structure to bear the aluminum wafers at the output end of the conveyor belt 1, the first motor 3 drives the first bevel gear 4 to be meshed and connected with the second bevel gear 5, so that the screw 6 drives the sleeve block 8 to move horizontally, and the aluminum wafers move to the upper end of the fixed block 18;

supporting disk 20 carries out the bearing to the aluminium disk to spacing pile is carried out to spacing axle 19 of the spacing of multiunit all around of aluminium disk, neatly places, has increased holistic practicality.

Those not described in detail in this specification are within the skill of the art.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. An automatic stacking device for aluminum plate strip production wafers mainly comprises a conveyor belt (1), a support frame (2) and fixing blocks (18), wherein the support frame (2) is arranged at the side end of the conveyor belt (1), and the fixing blocks (18) for loading products are arranged on the inner side of the support frame (2);

it is characterized by comprising:

the first motor (3) is fixedly installed at the top end of the support frame (2), the output end of the first motor (3) is fixedly connected with a first bevel gear (4), the top end of the support frame (2) is connected with a second bevel gear (5) in a shaft mode, the bottom side of the second bevel gear (5) is connected with the first bevel gear (4), the shaft end of the second bevel gear (5) is connected with a screw (6), meanwhile, the top end of the support frame (2) is fixedly provided with a fixed shaft (7), the outer ends of the fixed shaft (7) and the screw (6) are connected with a sleeve block (8), the outer end of the sleeve block (8) is fixedly provided with a cylinder (9), the output end of the cylinder (9) is connected with a support rod (10), the bottom end of the support rod (10) is fixedly connected with a top block (11), the upper end of the top block (11) is fixedly provided with a second motor (12), and the inner end of the top block (11) is provided with a fixed gear (13), the shaft end of the fixed gear (13) is connected with the output end of the second motor (12), the inner end of the top block (11) is provided with a movable block (14), the inner side of the movable block (14) is provided with a rack (15), the rack (15) is meshed with the fixed gear (13), the bottom end of the movable block (14) is fixedly provided with a bearing rod (16), and the bottom end of the movable block (14) is provided with a clamping groove (17);

and the limiting shaft (19) is arranged at the upper end of the fixing block (18), and a supporting disc (20) is fixedly arranged at the upper end of the fixing block (18).

2. The automatic stacking and stacking device for aluminum plate and strip production wafers as recited in claim 1, wherein the first bevel gear (4) and the second bevel gear (5) are in meshed connection, the shaft end of the second bevel gear (5) is fixedly connected with the head end of the screw (6), and the screw (6) is in threaded connection with the sleeve block (8).

3. The automatic stacking and stacking device for the aluminum plate and strip production wafers as claimed in claim 2, wherein the sleeve block (8) is slidably connected with the fixed shaft (7), the outer end of the sleeve block (8) is fixedly provided with the cylinder (9), and the support rod (10) and the top block (11) form a lifting structure with the support frame (2) through the output end of the cylinder (9).

4. The automatic stacking and stacking device for the aluminum plate and strip production wafers as claimed in claim 3, wherein the support rod (10) and the top block (11) are of a fixed integrated structure, two sets of movable blocks (14) are arranged at the inner end of the top block (11), racks (15) are mounted on the inner sides of the two sets of movable blocks (14), and the racks (15) are meshed with the fixed gear (13).

5. The automatic stacking and stacking device for aluminum plate and strip production wafers as claimed in claim 4, wherein a support rod (16) is welded to the bottom end of the movable block (14), and the top end of the support rod (16) forms a clamping structure with the other set of movable blocks (14) through a clamping groove (17).

6. The automatic stacking and stacking device for aluminum plate and strip production disks as claimed in claim 1, wherein four sets of limiting shafts (19) are uniformly distributed and mounted at the upper end of the fixing block (18), the inner sides of the limiting shafts (19) are attached to the outer surfaces of the aluminum disks, and a supporting disk (20) for supporting the aluminum disks is fixedly mounted at the upper end of the fixing block (18).

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