CN113734754A

CN113734754A - Circulation automatic feeding equipment

Info

Publication number: CN113734754A
Application number: CN202111070307.5A
Authority: CN
Inventors: 刘颂智; 易鹏鹏; 刘芳明; 金小平; 岳崇斌; 周铁夫; 眭宝健
Original assignee: Jl Mag Rare Earth Co ltd
Current assignee: Jl Mag Rare Earth Co ltd
Priority date: 2021-09-13
Filing date: 2021-09-13
Publication date: 2021-12-03
Anticipated expiration: 2041-09-13
Also published as: CN113734754B

Abstract

The invention relates to the technical field of magnetic sheet production, in particular to a circulating automatic feeding device; in the invention, the magnetic sheets are fed from the feeding device, slide into the first conveying device, and are conveyed into the second conveying device by the first conveying device, the magnetic sheets are conveyed to the reversing device by the second conveying device, and are conveyed to the stacking device from the transverse direction to the vertical direction by the reversing device to be stacked; the invention has the advantages of convenient feeding, difficult deviation, no collision and no overlapping between magnetic sheets, and avoids the phenomenon of abrasion or scratching of coatings on the magnetic sheets.

Description

Circulation automatic feeding equipment

Technical Field

The invention relates to the technical field of magnetic sheet production, in particular to a circulating automatic feeding device.

Background

The existing circulating automatic feeding mode completely depends on the rotation of a vibration disc to push, magnetic sheets are easy to collide and overlap, if the magnetic sheets are subjected to surface treatment, a coating is easy to wear or scratch, and even the magnetic sheets are difficult to push.

The existing feeding mode often causes the phenomena that magnetic sheets are rotated on site in the conveying process, the output efficiency is low and the like, and simultaneously reduces the risk of the quality of the magnetic sheets due to the phenomena of collision, overlapping, coating abrasion or scratching and the like; and if a runway type circulating feeding device is adopted, the structure is relatively complex and the price is high.

Disclosure of Invention

In order to overcome the defects, the invention aims to provide the circulating automatic feeding equipment which is convenient to feed, is not easy to deviate, does not collide and overlap magnetic sheets and avoids the phenomenon of abrasion or scratch of a coating on the magnetic sheets.

The technical scheme for solving the technical problem is as follows:

a circulating automatic feeding device comprises a first machine table, a second machine table and a control system; the first machine table is connected with a feeding device for feeding magnetic sheets and a first conveying device for receiving the magnetic sheets transmitted by the feeding device; the second machine table is connected with a second conveying device used for receiving the magnetic sheets conveyed by the first conveying device, a reversing device used for reversing the magnetic sheets conveyed by the second conveying device and a stacking device used for stacking the magnetic sheets conveyed by the reversing device; the control system is used for controlling the movement of the feeding device, the first conveying device, the second conveying device, the reversing device and the stacking device.

As an improvement of the invention, the feeding device comprises a bin for placing the magnetic sheets and a flattening mechanism for flattening the magnetic sheets in the bin into one magnetic sheet.

As a further improvement of the invention, a feeding belt and a feeding mechanism are arranged in the storage bin, the feeding mechanism comprises a first motor and a first conveying assembly, and the first motor drives the feeding belt to move through the first conveying assembly.

As a further improvement of the present invention, the flattening mechanism includes a second motor, a brush drum and a second conveying assembly, the second motor is connected to the storage bin, the second motor drives the brush drum to move through the second conveying assembly, and a gap between the brush drum and the feeding belt is greater than the thickness of one magnetic sheet and smaller than the sum of the thicknesses of two magnetic sheets.

As a further improvement of the invention, the tail end of the storage bin is provided with a blanking plate which is obliquely arranged.

As a further improvement of the present invention, the first conveying device includes a first conveying mechanism for receiving the magnetic sheet sliding off the blanking plate and a second conveying mechanism for transferring the magnetic sheet sliding off the first conveying mechanism to the first conveying mechanism.

As a further improvement of the present invention, the first conveying mechanism includes a first conveyor belt and a first conveying motor, a barrier strip is disposed on the first conveyor belt, a distance between the barrier strip and the blanking plate is greater than a thickness of one magnetic sheet and smaller than a sum of thicknesses of two magnetic sheets, and the first conveying motor drives the first conveyor belt to move, so that the magnetic sheets on the first conveyor belt can be conveyed forward.

As a further improvement of the present invention, the second conveying mechanism includes a guide plate, a second conveyor belt, and a second conveyor motor, the guide plate is attached to the second conveyor belt, a tail end of the guide plate is inclined toward the first conveyor belt, the second conveyor motor drives the second conveyor belt to move, and the magnetic sheet on the second conveyor belt can slide onto the first conveyor belt through the guide plate.

As a further improvement of the invention, the first conveyor belt is provided with a guide block and an adjusting block, the guide block is tightly attached to the barrier strip, the adjusting block is tightly attached to the side edge of the blanking plate, and the interval between the guide block and the adjusting block is larger than the thickness of one magnetic sheet and smaller than the sum of the thicknesses of two magnetic sheets.

As a further improvement of the present invention, the second conveying device includes a slope plate, a third conveyor belt, and a third conveyor motor, the upper end of the slope plate is tightly attached to the first conveyor belt, the lower end of the slope plate is tightly attached to the third conveyor belt, the magnetic sheet on the first conveyor belt slides onto the third conveyor belt through the slope plate, and the third conveyor motor drives the third conveyor belt to move, so as to forward transmit the magnetic sheet on the third conveyor belt.

In the invention, the magnetic sheets are fed from the feeding device, slide into the first conveying device, and are conveyed into the second conveying device by the first conveying device, the magnetic sheets are conveyed to the reversing device by the second conveying device, and are conveyed to the stacking device from the transverse direction to the vertical direction by the reversing device to be stacked; the invention has the advantages of convenient feeding, difficult deviation, no collision and no overlapping between magnetic sheets, and avoids the phenomenon of abrasion or scratching of coatings on the magnetic sheets.

Drawings

For ease of illustration, the present invention is described in detail by the following preferred embodiments and the accompanying drawings.

FIG. 1 is a first schematic structural diagram of the present invention;

FIG. 2 is a second schematic structural view of the present invention;

FIG. 3 is a front view of the present invention;

FIG. 4 is a left side view of the present invention;

FIG. 5 is a right side view of the present invention;

FIG. 6 is a top view of the present invention;

reference numerals: 1-a first machine table, 2-a second machine table, 3-a feeding device, 31-a bin, 32-a feeding belt, 33-a first motor, 34-a first conveying assembly, 35-a blanking plate, 36-a leveling mechanism, 37-a second motor, 38-a second conveying assembly, 39-a brush barrel, 4-a first conveying device, 41-a first conveying mechanism, 42-a first conveying belt, 43-a barrier strip, 44-a guide block, 45-a regulating block, 46-a second conveying mechanism, 47-a guide plate, 48-a second conveying belt, 5-a second conveying device, 51-a slope plate, 52-a third conveying belt, 6-a reversing device, 61-a semicircular sliding table, 62-a reversing mechanism, 63-a reversing seat and 64-a chute, 65-a reversing cylinder, 66-a reversing plate, 7-a stacking device, 71-a stacking table, 72-a receiving mechanism, 73-a pushing mechanism, 74-a receiving cylinder, 75-a receiving plate, 76-a receiving baffle, 77-a pushing cylinder, 78-a pushing plate and 79-a sliding column.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

As shown in fig. 1 to 6, the automatic circular feeding apparatus of the present invention includes a first machine 1, a second machine 2 and a control system; the first machine table 1 is connected with a feeding device 3 for feeding magnetic sheets and a first conveying device 4 for receiving the magnetic sheets transmitted by the feeding device 3.

The second machine table 2 is connected with a second conveying device 5 for receiving the magnetic sheets conveyed by the first conveying device 4, a reversing device 6 for reversing the magnetic sheets conveyed by the second conveying device 5 and a stacking device 7 for stacking the magnetic sheets conveyed by the reversing device 6.

Within the invention, a control system is used to control the movement of the feeding device 3, the first conveying device 4, the second conveying device 5, the reversing device 6 and the stacking device 7.

In the invention, magnetic sheets are fed from a feeding device 3 and then slide into a first conveying device 4, and then are conveyed into a second conveying device 5 by the first conveying device 4, the magnetic sheets are conveyed to a reversing device 6 by the second conveying device 5, and the magnetic sheets are conveyed to a stacking device 7 from a transverse direction to a vertical direction by the reversing device 6 to be stacked.

In the present invention, the feeding device 3 includes a bin 31 for placing magnetic sheets and a flattening mechanism 36 for flattening the magnetic sheets in the bin 31 into one magnetic sheet; specifically, a feeding belt 32 and a feeding mechanism are arranged in the bin 31, the feeding mechanism comprises a first motor 33 and a first conveying assembly 34, and the first motor 33 drives the feeding belt 32 to move through the first conveying assembly 34; the flattening mechanism 36 comprises a second motor 37, a brush barrel 39 and a second conveying assembly 38 which are connected with the stock bin 31, the second motor 37 drives the brush barrel 39 to move through the second conveying assembly 38, the gap between the brush barrel 39 and the feeding belt 32 is larger than the thickness of one magnetic sheet and smaller than the sum of the thicknesses of two magnetic sheets, namely, the magnetic sheets can only pass through the brush barrel 39 one by one; the first conveying assembly and the second conveying assembly are identical in structure and comprise a driving wheel and a driving belt.

In order to slide the magnetic sheets to the first conveying device 4 from the bin 31, the tail end of the bin 31 is provided with the blanking plate 35, the blanking plate 35 is arranged in an inclined mode, specifically, the vertical inclination angle of the blanking plate 35 is 30-80 degrees, the magnetic sheets can conveniently slide from top to bottom, the blanking plate 35 inclines leftwards and rightwards by 10-30 degrees, the blanking plate 35 inclines towards the conveying direction of the first conveying device 4, and the magnetic sheets can better move towards the conveying outlet direction of the first conveying device 4.

In the present invention, the first conveying device 4 includes a first conveying mechanism 41 for receiving the magnetic pieces slid down from the blanking plate 35 and a second conveying mechanism 46 for re-conveying the magnetic pieces slid down on the first conveying mechanism 41 to the first conveying mechanism 41; specifically, the first conveying mechanism 41 includes a first conveying belt 42 and a first conveying motor, a barrier 43 is disposed on the first conveying belt 42, a distance between the barrier 43 and the blanking plate 35 is greater than a thickness of one magnetic sheet and smaller than a sum of thicknesses of the two magnetic sheets, that is, only one magnetic sheet is allowed to pass between the barrier 43 and the blanking plate 35, so that the magnetic sheets are conveyed forward piece by piece, the first conveying motor drives the first conveying belt 42 to move, so that the magnetic sheets on the first conveying belt 42 can be conveyed forward piece by piece, for better, the magnetic sheets are conveyed forward piece by piece, a guide block 44 and an adjusting block 45 are disposed on the first conveying belt 42, the guide block 44 is tightly attached to the barrier 43, the adjusting block 45 is tightly attached to a side edge of the blanking plate 35, and an interval between the guide block 44 and the adjusting block 45 is greater than the thickness of one magnetic sheet and smaller than the sum of the thicknesses of the two magnetic sheets.

In the invention, the second conveying mechanism 46 comprises a guide plate 47, a second conveying belt 48 and a second conveying motor, the guide plate 47 is attached to the second conveying belt 48, the tail end of the guide plate 47 inclines towards the first conveying belt 42, the second conveying motor drives the second conveying belt 48 to move, magnetic sheets on the second conveying belt 48 can slide onto the first conveying belt 42 through the guide plate 47, namely, if the magnetic sheets slide off beyond a barrier strip, the magnetic sheets can fall onto the second conveying belt 48, the second conveying belt 48 can be driven by the second conveying motor to convey the magnetic sheets onto the guide plate 47, and the magnetic sheets can slide onto the first conveying belt 42 through the guide plate 47, specifically, the guide plate 47 is designed to be in a curved surface, the tail end of the guide plate 47 inclines towards the first conveying belt 42, and the curved surface can be 30-60 degrees; further, the first conveyor belt 42 is obliquely arranged, the left-right inclination angle of the first conveyor belt 42 is 3-10 degrees, the first conveyor belt 42 is inclined towards the direction of the first conveyor belt 42, the tail end of the first conveyor belt 42 is lower than the head end of the first conveyor belt, the magnetic sheets are easier to transmit and slide, the front-back inclination angle of the first conveyor belt 42 is 20-38 degrees, and one end, close to the blanking plate 35, of the first conveyor belt 42 is higher than the end, close to the guide plate 47, of the first conveyor belt 42.

In the present invention, the second conveying device 5 includes a slope plate 51, a third conveyor belt 52 and a third conveyor motor, the upper end of the slope plate 51 is tightly attached to the first conveyor belt 42, the lower end of the slope plate 51 is tightly attached to the third conveyor belt 52, the magnetic sheet on the first conveyor belt 42 slides down onto the third conveyor belt 52 through the slope plate 51, and the third conveyor motor drives the third conveyor belt 52 to move, so as to forward transmit the magnetic sheet on the third conveyor belt 52.

In the invention, the reversing device 6 comprises a semicircular sliding table 61 and a reversing mechanism 62, a reversing seat 63 is arranged at the center of the semicircular sliding table 61, sliding grooves 64 are arranged on the circumferential surfaces of two sides of the semicircular sliding table 61, the reversing mechanism 62 comprises a reversing cylinder 65 and a reversing plate 66, the reversing cylinder 65 and the reversing plate 66 are connected to the reversing seat 63, the reversing cylinder 65 drives the reversing plate 66 to move, the reversing plate 66 can be pushed out and pulled back by utilizing the stretching and retracting of the reversing cylinder 65, so that the magnetic sheets can slide down to one side of the semicircular sliding table 61 when the reversing plate 66 is pushed out, the magnetic sheets can slide down to the other side of the semicircular sliding table 61 when the reversing plate 66 is pulled back, and the magnetic sheets are transmitted to the reversing seat 63 piece by piece on the third conveyor belt 52, and the stretching and retracting movement of the reversing cylinder 65 is matched with the conveyor belt of the third conveyor belt 52 correspondingly.

In the invention, the stacking device 7 comprises a stacking table 71, a receiving mechanism 72 and a pushing mechanism 73, wherein the receiving mechanism 72 comprises a receiving cylinder 74, a receiving plate 75 and a receiving baffle 76, the receiving cylinder 74 and the receiving plate 75 are positioned below the semicircular sliding table 61, when a magnetic sheet slides off from the semicircular sliding table 61, the receiving cylinder 74 pushes out the receiving plate 75, and the receiving plate 75 pushes the magnetic sheet to the receiving baffle 76 for stacking; when the magnetic sheets are stacked in a row, the magnetic sheets in the row are pushed to the turnover box by the pushing mechanism 73.

The material pushing mechanism 73 comprises a material pushing cylinder 77, a material pushing plate 78 and a sliding column 79, the middle of the material pushing cylinder 77 and the material pushing plate 78 is fixedly connected, two sides of the material pushing plate 78 are respectively connected with the sliding column 79 in a sliding mode, the material pushing cylinder 77 can push the material pushing plate 78, and the material pushing plate 78 pushes the magnetic sheets stacked in a row into the turnover box.

The invention provides an embodiment, which comprises a first machine table 1, a second machine table 2 and a control system; the first machine table 1 is connected with a feeding device 3 for feeding magnetic sheets and a first conveying device 4 for receiving the magnetic sheets transmitted by the feeding device 3; the second machine table 2 is connected with a second conveying device 5 for receiving the magnetic sheets transmitted by the first conveying device 4, a reversing device 6 for reversing the magnetic sheets transmitted by the second conveying device 5 and a stacking device 7 for stacking the magnetic sheets transmitted by the reversing device 6; the feeding device 3 comprises a bin 31 for placing magnetic sheets and a flattening mechanism 36 for flattening the magnetic sheets in the bin 31 into one magnetic sheet; a feeding belt 32 and a feeding mechanism are arranged in the bin 31, the feeding mechanism comprises a first motor 33 and a first conveying assembly 34, and the first motor 33 drives the feeding belt 32 to move through the first conveying assembly 34; the flattening mechanism 36 comprises a second motor 37, a brush barrel 39 and a second conveying assembly 38 which are connected to the bin 31, the second motor 37 drives the brush barrel 39 to move through the second conveying assembly 38, the gap between the brush barrel 39 and the feeding belt 32 is larger than the thickness of one magnetic sheet and smaller than the sum of the thicknesses of the two magnetic sheets, the tail end of the bin 31 is provided with a blanking plate 35, the blanking plate 35 is obliquely arranged, the vertical inclination angle of the blanking plate 35 is 60 degrees, the left and right inclination angles of the blanking plate 35 are 15 degrees, the first conveying device 4 comprises a first conveying mechanism 41 for receiving the magnetic sheets sliding down from the blanking plate 35 and a second conveying mechanism 46 for conveying the magnetic sheets sliding down from the first conveying mechanism 41 to the first conveying mechanism 41, the first conveying mechanism 41 comprises a first conveying belt 42 and a first conveying motor, the first conveying belt 42 is provided with a baffle strip 43, the distance between the baffle 43 and the blanking plate 35 is larger than the thickness of one magnetic sheet and smaller than the sum of the thicknesses of the two magnetic sheets, the second conveying mechanism 46 comprises a guide plate 47, a second conveying belt 48 and a second conveying motor, the guide plate 47 is attached to the second conveying belt 48, the tail end of the guide plate 47 inclines towards the first conveying belt 42, the second conveying motor drives the second conveying belt 48 to move, magnetic sheets on the second conveying belt 48 can slide onto the first conveying belt 42 through the guide plate 47, the first conveying belt 42 is arranged in an inclined mode, the left-right inclination angle of the first conveying belt 42 is 5 degrees, the front-back inclination angle of the first conveying belt 42 is 28 degrees, the second conveying device 5 comprises a slope plate 51, a third conveying belt 52 and a third conveying motor, the upper end of the slope plate 51 is attached to the first conveying belt 42, the lower end of the slope plate 51 is attached to the third conveying belt 52, the reversing device 6 comprises a semicircular sliding table 61 and a reversing mechanism 62, a reversing seat 63 is arranged at the center of the semicircular sliding table 61, sliding grooves 64 are arranged on the circumferential surfaces of two sides of the sliding table 61, the reversing mechanism 62 comprises a reversing cylinder 65 and a reversing plate 66, the reversing cylinder 65 and the reversing plate 66 are connected to the reversing seat 63, the stacking device 7 comprises a stacking table 71, a material receiving mechanism 72 and a material pushing mechanism 73, the material receiving mechanism 72 comprises a material receiving cylinder 74, a material receiving plate 75 and a material receiving baffle 76, the material receiving cylinder 74 and the material receiving plate 75 are located below the semicircular sliding table 61, the material pushing mechanism 73 comprises a material pushing cylinder 77, a material pushing plate 78 and a sliding column 79, the middle of the material pushing cylinder 77 and the material pushing plate 78 is fixedly connected, and two sides of the material pushing plate 78 are respectively in sliding connection with the sliding column 79.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims

1. A circulating automatic feeding device is characterized by comprising a first machine table, a second machine table and a control system; the first machine table is connected with a feeding device for feeding magnetic sheets and a first conveying device for receiving the magnetic sheets transmitted by the feeding device; the second machine table is connected with a second conveying device used for receiving the magnetic sheets conveyed by the first conveying device, a reversing device used for reversing the magnetic sheets conveyed by the second conveying device and a stacking device used for stacking the magnetic sheets conveyed by the reversing device; the control system is used for controlling the movement of the feeding device, the first conveying device, the second conveying device, the reversing device and the stacking device.

2. The recycling automatic feeding device according to claim 1, wherein said feeding means comprises a bin for placing magnetic sheets and a flattening mechanism for flattening the magnetic sheets in said bin into one magnetic sheet.

3. The automatic circulating feeding device as claimed in claim 2, wherein a feeding belt and a feeding mechanism are disposed in the storage bin, the feeding mechanism includes a first motor and a first conveying assembly, and the first motor drives the feeding belt to move through the first conveying assembly.

4. The automatic circulating feeding device of claim 3, wherein the flattening mechanism comprises a second motor, a brush barrel and a second conveying assembly, the second motor is connected to the storage bin, the second motor drives the brush barrel to move through the second conveying assembly, and a gap between the brush barrel and the feeding belt is larger than the thickness of one magnetic sheet and smaller than the sum of the thicknesses of the two magnetic sheets.

5. The automatic feeding equipment of claim 4, wherein the end of the bin is provided with a blanking plate, and the blanking plate is arranged obliquely.

6. The automatic circular feeding device as claimed in claim 5, wherein the first conveying means comprises a first conveying mechanism for receiving the magnetic sheets slid off the feeding plate and a second conveying mechanism for transferring the magnetic sheets slid off the first conveying mechanism to the first conveying mechanism.

7. The automatic circular feeding device as claimed in claim 6, wherein the first conveying mechanism comprises a first conveyor belt and a first conveying motor, a barrier strip is arranged on the first conveyor belt, the distance between the barrier strip and the blanking plate is larger than the thickness of one magnetic sheet and smaller than the sum of the thicknesses of the two magnetic sheets, and the first conveying motor drives the first conveyor belt to move so as to convey the magnetic sheets on the first conveyor belt forwards.

8. The automatic feeding device according to claim 7, wherein the second conveying mechanism comprises a guide plate, a second conveyor belt and a second conveyor motor, the guide plate is attached to the second conveyor belt, the tail end of the guide plate is inclined towards the first conveyor belt, the second conveyor motor drives the second conveyor belt to move, and the magnetic sheets on the second conveyor belt can slide onto the first conveyor belt through the guide plate.

9. The automatic circular feeding device as claimed in claim 8, wherein the first conveyor belt is provided with a guide block and an adjusting block, the guide block is tightly attached to the barrier strip, the adjusting block is tightly attached to the side edge of the blanking plate, and the distance between the guide block and the adjusting block is larger than the thickness of one magnetic sheet and smaller than the sum of the thicknesses of the two magnetic sheets.

10. The automatic circular feeding device according to claim 9, wherein the second conveying device comprises a slope plate, a third conveyor belt and a third conveyor motor, the upper end of the slope plate is tightly attached to the first conveyor belt, the lower end of the slope plate is tightly attached to the third conveyor belt, the magnetic sheet on the first conveyor belt slides onto the third conveyor belt through the slope plate, and the third conveyor motor drives the third conveyor belt to move so as to convey the magnetic sheet on the third conveyor belt forwards.