CN210681309U - Magnetic stacking system for blanking - Google Patents

Abstract

The utility model discloses a magnetism stack system for unloading, including sheet material conveyer belt, fixed frame, conveying motor, the sheet material conveyer belt with conveying motor installs in the fixed frame, the sheet material conveyer belt with conveying motor's output shaft, the pay-off end of sheet material conveyer belt is corresponding with the feed end of stack hold-in range, the cover is equipped with the integral key shaft that quantity is two on the stack hold-in range, stack hold-in range and servo motor's output shaft, servo motor fixes on magnetic control stack portal frame. Has the advantages that: when the finished product transported the packing district, the iron plate in the standing groove of telescopic cylinder one end will be kept away from, and the layer board is out of balance, and the product on the layer board glides along the inclined plane, makes things convenient for the unloading, and when the layer board inclination was not enough, the product gliding speed on the layer board was slow, can drive the push rod through telescopic cylinder and carry out work, and the push rod carries out the unloading to the product on the layer board for the time of unloading, thereby strengthened work efficiency.

Description

Magnetic stacking system for blanking

Technical Field

The utility model relates to an intelligence makes technical field, particularly, relates to a magnetism stack system for unloading.

Background

With the constant development of the automotive industry, the manufacturing precision of many parts is more and more demanding, for example: modern sheet metal product parts such as automobile doors, trunk lids, engine covers, door panels, pillar inner panels, longitudinal beam parts, floor parts, automobile wheel covers and the like all need high standard processing precision, forming precision and manufacturing precision, the existing large sheet metal processing equipment processes by using stamping as power, the operation links for processing parts are multiple, the existing processed sheet metal needs to be conveyed to a finished product area for packaging and transported by a transport vehicle, the existing transport vehicle does not have a blanking mechanism, and labor and time are greatly spent for blanking through manpower, and then finished product packaging is carried out, so that the working efficiency is low.

An effective solution to the problems in the related art has not been proposed yet.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a magnetism stack system for unloading to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme:

a magnetic stacking system for blanking comprises a plate conveying belt, a fixed frame and a conveying motor, wherein the plate conveying belt and the conveying motor are installed on the fixed frame, the plate conveying belt is connected with an output shaft of the conveying motor, a feeding end of the plate conveying belt corresponds to a feeding end of a stacking synchronous belt, the stacking synchronous belt is sleeved with two spline shafts, the stacking synchronous belt is connected with an output shaft of a servo motor, the servo motor is fixed on a magnetic control stacking portal frame, two groups of stacking clapper mechanisms are arranged at the bottom of the magnetic control stacking portal frame, each group of stacking clapper mechanisms comprises two magnetic control stacking cylinders, output ends of the magnetic control stacking cylinders are connected with magnetic control stacking clappers, hydraulic lift trucks are arranged among the stacking magnetic control clapper boards, and the bottom ends of the hydraulic lift trucks are in sliding connection with track wheels, the upper part of the magnetic control stacking portal frame is provided with a permanent magnet and controllable magnet device, the stacking synchronous belt is sleeved outside the permanent magnet and controllable magnet device, a support rod is fixedly arranged at the top end of the hydraulic lifting car, a ball is fixedly arranged at the top end of the support rod, a supporting plate is arranged above the round ball, an elliptical hole is arranged at the bottom end of the supporting plate, the round ball is slidably arranged in the elliptical hole, two return springs are fixedly arranged at the top end of the hydraulic lift truck, the top ends of the return springs are fixed at the bottom end of the supporting plate, square plates are fixedly arranged on two sides of the bottom end of the supporting plate, square holes are formed in the square plates, a placing groove is fixedly arranged at the bottom end of the inner wall of each square hole, a magnetic bar is fixed at the bottom end of the groove wall of the placing groove, iron blocks which are mutually attracted are placed in the magnetic bar, the hydraulic lifting car is characterized in that a telescopic cylinder is fixedly arranged at the top end of the hydraulic lifting car, and the output end of the telescopic cylinder is connected with a push rod.

Further, the weights of the iron blocks are the same.

Furthermore, inductors are arranged on the magnetic control stacking clappers.

Furthermore, limiting rods are fixedly arranged at the positions, corresponding to the top ends of the hydraulic lift truck, of the bottom end of the supporting plate, and the limiting rods are respectively sleeved on the corresponding reset springs.

Further, the magnetic control stacking gantry is characterized in that a shock absorber is fixedly arranged at the bottom end of the magnetic control stacking gantry.

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

the plate conveyer belt conveys the cut products to a stacking synchronous belt by a laser cutting bed, the stacking synchronous belt and a servo motor which are arranged on a magnetic control stacking portal frame move along the direction of a permanent magnet and controllable magnet device through PLC control, the products of the stacking synchronous belt move to a permanent magnet area to absorb the finished products, so that the finished products suspended on the stacking synchronous belt do not drop midway, when a controllable magnet part area senses a blanking signal, the products can be demagnetized and fall on a supporting plate of a hydraulic lift truck, when the finished products fall on the supporting plate of the hydraulic lift truck, a magnetic control stacking cylinder operates to enable a magnetic control stacking clapper to operate to clap the products, so that the products are stacked orderly, the finished products are automatically conveyed to a packaging area to be packaged, when the finished products are conveyed to the packaging area, iron blocks in a placing groove far away from one end of a telescopic cylinder, the layer board is out of balance, and the product on the layer board glides along the inclined plane, makes things convenient for the unloading, and when the layer board inclination was not enough, the product gliding speed on the layer board was slow, can drive the push rod through telescopic cylinder and carry out work, and the push rod carries out the unloading to the product on the layer board for the time of unloading, thereby strengthened work efficiency.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a front view of a magnetic stacking system for blanking according to an embodiment of the present invention;

fig. 2 is a schematic view of a hydraulic lift truck of a magnetic stacking system for blanking according to an embodiment of the present invention;

fig. 3 is a schematic diagram of a square plate of a magnetic stacking system for blanking according to an embodiment of the present invention.

Reference numerals:

1. a sheet material conveying belt; 2. fixing the frame; 3. a conveying motor; 4. stacking the synchronous belts; 5. a spline shaft; 6. a servo motor; 7. magnetically controlled stacking portal frames; 8. a stacking clapper mechanism; 9. a magnetic control stacking cylinder; 10. magnetically controlled stacking clappers; 11. a hydraulic lift truck; 12. a rail wheel; 13. permanent and controllable magnet devices; 14. a support bar; 15. a ball; 16. a support plate; 17. an elliptical hole; 18. a return spring; 19. a limiting rod; 20. a square plate; 21. a square hole; 22. a placement groove; 23. a magnetic bar; 24. an inductor; 25. a shock absorber; 26. a telescopic cylinder; 27. a push rod; 28. and (4) iron blocks.

Detailed Description

The following, with reference to the drawings and the detailed description, further description of the present invention is made:

the first embodiment is as follows:

referring to fig. 1-3, a magnetic stacking system for blanking according to an embodiment of the present invention includes a sheet conveyer belt 1, a fixed frame 2, and a conveying motor 3, wherein the sheet conveyer belt 1 and the conveying motor 3 are mounted on the fixed frame 2, the sheet conveyer belt 1 is connected to an output shaft of the conveying motor 3, a feeding end of the sheet conveyer belt 1 corresponds to a feeding end of a stacking synchronous belt 4, two spline shafts 5 are sleeved on the stacking synchronous belt 4, the stacking synchronous belt 4 is connected to an output shaft of a servo motor 6, the servo motor 6 is fixed to a magnetic stacking gantry 7, two sets of stacking clapper mechanisms 8 are disposed at a bottom of the magnetic stacking gantry 7, each set of the clapper mechanisms 8 includes two magnetic stacking cylinders 9, an output end of each magnetic stacking cylinder 9 is connected to a magnetic stacking clapper 10, a hydraulic lift truck 11 is arranged between the magnetic control stacking clappers 10, the bottom end of the hydraulic lift truck 11 is slidably connected with a track wheel 12, a permanent magnet and controllable magnet device 13 is arranged at the upper part of the magnetic control stacking portal frame 7, the stacking synchronous belt 4 is sleeved outside the permanent magnet and controllable magnet device 13, a support rod 14 is fixedly arranged at the top end of the hydraulic lift truck 11, a round ball 15 is fixedly arranged at the top end of the support rod 14, a support plate 16 is arranged above the round ball 15, an elliptical hole 17 is formed in the bottom end of the support plate 16, the round ball 15 is slidably arranged in the elliptical hole 17, two return springs 18 are fixedly arranged at the top end of the hydraulic lift truck 11, the top ends of the return springs 18 are fixed at the bottom end of the support plate 16, square plates 20 are fixedly arranged at two sides of the bottom end of the support plate 16, square plates 20 are provided with square holes 21, a placing groove 22 is fixedly arranged, the bottom end of the groove wall of the placing groove 22 is fixedly provided with a magnetic rod 23, iron blocks 28 which are mutually attracted are placed in the magnetic rod 23, a telescopic cylinder 26 is fixedly arranged at the top end of the hydraulic lifting vehicle, and the output end of the telescopic cylinder 26 is connected with a push rod 27.

Through the above technical scheme of the utility model, beneficial effect: the plate conveying belt 1 conveys the cut products to a stacking synchronous belt 4 by a laser cutting bed, the stacking synchronous belt 4 and a servo motor 6 which are arranged on a magnetic control stacking portal frame 7 move along the direction of a permanent magnet and controllable magnet device 13 through PLC control, the products of the stacking synchronous belt 4 move to a permanent magnet area to suck the finished products, so that the finished products suspended on the stacking synchronous belt 4 cannot fall midway, when a controllable magnet part area senses a blanking signal, the products can be demagnetized and fall on a supporting plate 16 of a hydraulic lift truck 11, when the finished products fall on the supporting plate 16 of the hydraulic lift truck 11, a magnetic control stacking cylinder 9 operates to enable a magnetic control stacking clapper 10 to run to clapper the products, the products are stacked neatly, the finished product hydraulic lift truck 11 drives a truck track wheel 12 to automatically convey the finished products to a packaging area for packaging, and the finished products are conveyed to the packaging area, the iron blocks 28 in the placing grooves 22 far away from one end of the telescopic cylinder 26 are unbalanced on the supporting plate 16, products on the supporting plate 16 slide down along the inclined plane, blanking is facilitated, when the inclination of the supporting plate 16 is not enough, the sliding speed of the products on the supporting plate 16 is low, the push rod 27 can be driven by the telescopic cylinder 26 to work, the push rod 27 carries out blanking on the products on the supporting plate 16, blanking time is shortened, and working efficiency is improved.

Example two:

referring to fig. 3, for the iron blocks 28, the weights of the iron blocks 28 are the same.

Through the above technical scheme of the utility model, beneficial effect: the iron blocks 28 are of equal weight and maintain the balance of the pallet 16.

Example three:

referring to fig. 1, for the magnetically controlled stacking paddle 10, the magnetically controlled stacking paddle 10 is provided with an inductor 24.

Through the above technical scheme of the utility model, beneficial effect: the sensor 24 arranged on the magnetic control stacking clapper 10 senses the product and sends a signal to enable the magnetic control stacking cylinder 9 to operate, so that the magnetic control stacking clapper 10 operates to clap the plate products to be stacked orderly.

Example four:

referring to fig. 2, for the supporting plate 16, the bottom end of the supporting plate 16 is fixed with a limiting rod 19 at a position corresponding to the top end of the hydraulic lift truck 11, and the limiting rods 19 are respectively sleeved on the corresponding return springs 18.

Through the above technical scheme of the utility model, beneficial effect: the limiting rod 19 is arranged to limit the return spring 18 and prevent the return spring 18 from excessively deforming.

Example five:

referring to fig. 1, for the magnetically controlled stacking portal frame 7, a damper 25 is fixedly disposed at the bottom end of the magnetically controlled stacking portal frame 7.

Through the above technical scheme of the utility model, beneficial effect: the damper 25 plays a role in damping the magnetic control stacking portal frame 7.

To sum up, with the aid of the above technical scheme of the utility model, theory of operation and all beneficial effects: the plate conveyer belt 1 conveys the cut products to a stacking synchronous belt 4 by a laser cutting bed, the stacking synchronous belt 4 and a servo motor 6 which are arranged on a magnetic control stacking portal frame 7 move along the direction of a permanent magnet and controllable magnet device 13 through PLC control, the products of the stacking synchronous belt 4 move to a permanent magnet area to suck the finished products, so that the finished products suspended on the stacking synchronous belt 4 do not fall midway, when the controllable magnet part area senses a blanking signal, the products can be demagnetized and fall on a supporting plate 16 of a hydraulic lifting car 11, when the finished products fall on the supporting plate 16 of the hydraulic lifting car 11, a magnetic control stacking cylinder 9 operates to enable a magnetic control stacking clapper 10 to run to clapper the products, the products are stacked orderly, the finished product hydraulic lifting car 11 drives a car track wheel 12 to automatically convey the finished products to a packaging area for packaging, when the finished products are conveyed to the packaging area, an iron block 28 in a placing groove 22 far away from one end of a telescopic cylinder 26, the supporting plate 16 loses balance, products on the supporting plate 16 slide down along an inclined plane, blanking is convenient, when the inclination of the supporting plate 16 is insufficient, the sliding speed of the products on the supporting plate 16 is low, the push rod 27 can be driven by the telescopic cylinder 26 to work, the push rod 27 carries out blanking on the products on the supporting plate 16, blanking time is accelerated, working efficiency is improved, the weights of the iron blocks 28 are the same, balance of the supporting plate 16 is kept, the sensor 24 mounted on the magnetic control stacking clapper 10 senses the products, signals are sent out to enable the magnetic control stacking cylinder 9 to operate, the magnetic control stacking clapper 10 operates to clapper the plate products, the plate products are stacked tidily, the limiting rod 19 arranged plays a limiting role in limiting the reset spring 18, excessive deformation of the reset spring 18 is prevented, and the shock absorber 25 plays a shock absorption role in the stacking magnetic control portal.

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 invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. A magnetic stacking system for blanking is characterized by comprising a plate conveying belt (1), a fixed rack (2) and a conveying motor (3), wherein the plate conveying belt (1) and the conveying motor (3) are installed on the fixed rack (2), the plate conveying belt (1) is connected with an output shaft of the conveying motor (3), a feeding end of the plate conveying belt (1) corresponds to a feeding end of a stacking synchronous belt (4), two spline shafts (5) are sleeved on the stacking synchronous belt (4), the stacking synchronous belt (4) is connected with an output shaft of a servo motor (6), the servo motor (6) is fixed on a magnetic stacking portal frame (7), two groups of stacking plate beating mechanisms (8) are arranged at the bottom of the magnetic stacking portal frame (7), each group of the stacking plate beating mechanisms (8) comprises two magnetic stacking cylinders (9), the magnetic control stacking device is characterized in that the output end of the magnetic control stacking cylinder (9) is connected with magnetic control stacking clapper plates (10), hydraulic lift trucks (11) are arranged between the magnetic control stacking clapper plates (10), the bottom ends of the hydraulic lift trucks (11) are slidably connected with rail wheels (12), permanent magnet and controllable magnet devices (13) are arranged on the upper portions of the magnetic control stacking portal frames (7), stacking synchronous belts (4) are sleeved outside the permanent magnet and controllable magnet devices (13), supporting rods (14) are fixedly arranged at the top ends of the hydraulic lift trucks (11), round balls (15) are fixedly arranged at the top ends of the supporting rods (14), supporting plates (16) are arranged above the round balls (15), oval holes (17) are formed in the bottom ends of the supporting plates (16), the round balls (15) are slidably arranged in the oval holes (17), and two reset springs (18) are fixedly arranged at the top ends of the hydraulic lift trucks (11), reset spring (18) top is fixed the bottom of layer board (16), layer board (16) bottom both sides are all fixed and are equipped with square plate (20), square hole (21) have been seted up on square plate (20), square hole (21) inner wall bottom mounting is equipped with standing groove (22), standing groove (22) cell wall bottom mounting is equipped with bar magnet (23), iron plate (28) of looks actuation have been placed in bar magnet (23), hydraulic pressure lift roof end mounting is equipped with telescopic cylinder (26), telescopic cylinder's (26) output is connected with push rod (27).

2. Magnetic stacking system for blanking according to claim 1, characterised in that the weights between the iron blocks (28) are equal.

3. Magnetic stacking system for blanking according to claim 1, characterised in that said magnetically controlled stacking clappers (10) are provided with inductors (24).

4. The magnetic stacking system for blanking of claim 1, wherein a position limiting rod (19) is fixedly arranged at a position corresponding to the top end of the hydraulic lift truck (11) at the bottom end of the supporting plate (16), and the position limiting rods (19) are respectively sleeved on the corresponding return springs (18).

5. The magnetic stacking system for blanking of claim 1, wherein a shock absorber (25) is fixed at the bottom end of the magnetic stacking portal frame (7).

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