CN111633525B

CN111633525B - Automatic production line for magnetic materials

Info

Publication number: CN111633525B
Application number: CN202010375348.4A
Authority: CN
Inventors: 许洪龙
Original assignee: Jiangyin Polytechnic College
Current assignee: Jiangyin Polytechnic College
Priority date: 2020-05-07
Filing date: 2020-05-07
Publication date: 2022-02-01
Anticipated expiration: 2040-05-07
Also published as: CN111633525A

Abstract

The invention relates to an automatic production line for magnetic materials, which comprises a blank making assembly, a transferring manipulator, a to-be-sintered blank conveying line, a sintering plate conveying line, a sintering assembly, a sintering column conveying line, a grinding assembly and a warehousing assembly, wherein the to-be-sintered blank conveying line is arranged on the sintering plate conveying line; the sintering assembly is arranged on the left side of the middle part of the conveying line for the green body to be sintered, the conveying line for the firing column is arranged between the conveying line for the firing plate and the sintering assembly, and the two grinding assemblies are symmetrically arranged on the left side and the right side of the unloading manipulator; the invention reasonably connects four links of blank making, sintering, grinding and warehousing in the production process of the magnetic material, so that feeding and discharging in each link are automatically carried out, and auxiliary parts used in the production process are automatically recycled, thereby greatly reducing the labor cost, reducing the labor intensity and effectively improving the production efficiency.

Description

Automatic production line for magnetic materials

Technical Field

The invention relates to an automatic production line for magnetic materials.

Background

The material capable of reacting in a certain way to the magnetic field is called magnetic material, the production process of the magnetic material can be roughly blank making, sintering, grinding and warehousing, in the existing production line of the magnetic material, feeding and discharging among the four links of blank making, sintering, grinding and warehousing are manually carried out, and recovery of auxiliary parts used in the production process needs to be finished by manpower, so that the labor cost is high, the labor intensity is high, the production efficiency is low, and further improvement is needed.

Disclosure of Invention

In view of the current situation of the prior art, the invention aims to provide an automatic production line for magnetic materials, which greatly reduces the labor cost, reduces the labor intensity and effectively improves the production efficiency.

The technical scheme adopted by the invention for solving the technical problems is as follows: an automatic production line for magnetic materials is characterized by comprising a blank making assembly, a transferring manipulator, a to-be-sintered blank conveying line, a sintering plate conveying line, a sintering assembly, a sintering column conveying line, a grinding assembly and a warehousing assembly; the conveying device comprises a conveying manipulator, a transfer manipulator, a blank-making assembly, a sand supplementing device and a blank-containing plate stirring device, wherein the blank-making assembly comprises four blank-making assemblies which are arranged on the outer side of the transfer manipulator in a pairwise symmetrical manner, the two blank-making assemblies are distributed on the left side and the right side of the conveying manipulator, the blank-making assemblies comprise a blank making machine, a blank arranging machine, a blank laminating machine, a sand supplementing device and a blank-containing plate stirring device, the discharge end of the blank making machine is connected with the feed end of the blank arranging machine, the feed end of the blank-containing plate stirring device is matched with the conveying line of the blank-making plate, the discharge end of the blank-containing plate stirring device is connected with the feed end of the blank laminating machine through the sand supplementing device, and the discharge end of the blank arranging machine is matched with the feed end of the blank laminating machine; the sintering assembly is arranged on the left side of the middle of the to-be-sintered blank conveying line, the to-be-sintered blank pushing device, the to-be-sintered blank pushing cylinder and the to-be-sintered blank pushing cylinder are arranged on the front side of the discharging end of the to-be-sintered blank conveying line, the to-be-sintered blank pushing cylinder, the to-be-sintered column conveying line and the to-be-sintered assembly are arranged between the to-be-sintered plate conveying line and the sintering assembly, the utility model discloses a sintering furnace transition bin, including sintering furnace transition bin, unloading manipulator, grinding subassembly, it includes the sintering furnace transition bin, the sintering furnace transition bin is located to the blank that has burnt material device, the feed end of the transfer chain of unloading links to each other with the discharge end of sintering furnace transition bin and arranges mutually perpendicular, the recovery manipulator locate the discharge end of the transfer chain of unloading and all mutually support with the feed end of holding burning post transfer chain and holding burning board transfer chain, the discharge manipulator locates the discharge end of the transfer chain of unloading and locates the downstream side of recovery manipulator, the grinding subassembly includes two, two the left and right sides of unloading manipulator is located to the grinding subassembly symmetry, the rear side of two grinding subassemblies is located to the warehouse entry subassembly.

Preferably, the grinding assembly comprises a first grinding conveying line, a second grinding conveying line, a third grinding conveying line, a grinding machine group and a transverse moving conveying mechanism, wherein the first grinding conveying line, the second grinding conveying line and the third grinding conveying line of the grinding assembly located on the right side of the unloading manipulator are sequentially arranged on the right side of the unloading manipulator from front to back and are arranged in parallel, the lengths of the first grinding conveying line, the second grinding conveying line and the third grinding conveying line are sequentially increased and are all arranged perpendicular to the unloading conveying line, the grinding machine group comprises three grinding machines, the grinding machine group is parallel to each other and is arranged on the rear side of the third grinding conveying line and is all arranged perpendicular to the third grinding conveying line, and the transverse moving conveying mechanism is arranged between the grinding machine group and the first grinding conveying line, between the grinding machine group and the second grinding conveying line and between the grinding machine group and the third grinding conveying line.

Preferably, the warehousing component comprises a finished product material transfer conveying line and a finished product natural air drying area; the feeding end of the finished product material transfer conveying line is matched with the discharging end of each transverse moving carrying mechanism, and the finished product natural air drying area is arranged at the discharging end of the finished product material transfer conveying line.

Preferably, the device further comprises a temporary warehouse which is arranged at the right side of the conveying line for the blanks to be fired.

Preferably, the blank-making assembly further comprises a brushing device, and the brushing device is arranged at the discharge end of the blank laminating machine.

Compared with the prior art, the invention has the advantages that: the invention reasonably connects four links of blank making, sintering, grinding and warehousing in the production process of the magnetic material, so that feeding and discharging in each link are automatically carried out, and auxiliary parts used in the production process are automatically recycled, thereby greatly reducing the labor cost, reducing the labor intensity and effectively improving the production efficiency.

Drawings

FIG. 1 is a process flow and a structural diagram of the present invention.

Detailed Description

Unless defined otherwise, technical or scientific terms used herein shall have the ordinary meaning as understood by one of ordinary skill in the art to which this invention belongs. The use of "first," "second," and similar terms in the present application do not denote any order, quantity, or importance, but rather the terms are used to distinguish one element from another. The word "comprising" or "comprises", and the like, means that the element or item listed before the word covers the element or item listed after the word and its equivalents, but does not exclude other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect. "upper", "lower", "left", "right", and the like are used merely to indicate relative positional relationships, and when the absolute position of the object being described is changed, the relative positional relationships may also be changed accordingly.

To maintain the following description of the embodiments of the present invention clear and concise, a detailed description of known functions and known components of the invention have been omitted.

As shown in fig. 1, an automatic production line for magnetic materials comprises a blank making assembly, a transfer manipulator 6, a to-be-sintered blank conveying line 7, a sintering plate conveying line 8, a sintering assembly, a sintering column conveying line 27, a grinding assembly and a warehousing assembly; the sintering machine comprises a sintering machine, a conveying manipulator 6, a transfer manipulator 7, a sintering plate conveying line 8, a transfer manipulator 6, a blank making assembly, a sintering plate stacking machine 3, a sand supplementing device 4 and a sintering plate shifting device 5, wherein the sintering plate conveying line 8 is arranged above the blank conveying line 7, the transfer manipulator 6 is arranged above one end of the blank conveying line 7, the blank making assembly comprises four blank making assemblies, the four blank making assemblies are arranged on the outer side of the transfer manipulator 6 in a pairwise symmetry manner, the left side and the right side of the blank conveying line 7 and the left side and the right side of the sintering plate conveying line 8 are respectively provided with two blank making assemblies, each blank making assembly comprises a blank making machine 1, a blank arranging machine 2, a blank stacking machine 3, a sand supplementing device 4 and a sintering plate shifting device 5, the discharge end of the blank arranging machine 1 is connected with the feed end of the blank arranging machine 2, the feed end of the sintering plate shifting device 5 is matched with the sintering plate conveying line 8, the discharge end of the sintering plate shifting device 5 is connected with the feed end of the blank stacking machine 3 through the sand supplementing device 4; the sintering assembly is arranged on the left side of the middle of the to-be-sintered blank conveying line 7, the sintering column conveying line 27 is arranged between the to-be-sintered blank conveying line 8 and the sintering assembly, the sintering assembly comprises a magnetic material pushing cylinder 9, a transition conveying line 10, a sintering furnace incineration bin 11, a feeding conveying line 12, a to-be-sintered blank stirring device 13, a to-be-sintered blank pushing cylinder 14, a sintered blank stirring device 15, a sintering furnace transition bin 16, a discharging conveying line 17, a recycling manipulator 18 and a discharging manipulator 19, the feeding conveying line 12 and the sintering furnace transition bin 16 are arranged on the left side of the to-be-sintered blank conveying line 7, the to-be-sintered blank stirring device 13 is arranged between the feeding conveying line 12 and the to-be-sintered blank conveying line 7, the to-be-sintered blank pushing cylinder 14 is arranged at the feeding end of the feeding conveying line 12, the feeding end of the transition conveying line 10 is connected with the discharging end of the feeding conveying line 12 and is arranged vertically, the magnetic material pushing cylinder 9 is arranged on the front side of the discharging end of the transition conveying line 10, the sintering furnace incineration bin 11 is arranged between the discharge end of the feeding conveying line 12 and the feed end of the sintering furnace transition bin 16, the burnt blank poking device 15 is arranged on the front side of the discharge end of the sintering furnace transition bin 16, the feed end of the discharging conveying line 17 is connected with the discharge end of the sintering furnace transition bin 16 and is vertically arranged, the recovery manipulator 18 is arranged at the discharge end of the discharging conveying line 17 and is matched with the feed ends of the burning bearing column conveying line 27 and the burning bearing plate conveying line 8, the discharging manipulator 19 is arranged at the discharge end of the discharging conveying line 17 and is arranged on the downstream side of the recovery manipulator 18, the grinding assemblies comprise two grinding assemblies, the two grinding assemblies are symmetrically arranged on the left side and the right side of the discharging manipulator 19, the warehousing assemblies are arranged on the rear sides of the two grinding assemblies, each grinding assembly comprises a first grinding conveying line 20, a second grinding conveying line 21, a third grinding conveying line 22, a grinding machine group 23 and a transverse moving and carrying mechanism 24, the first grinding conveying line 20, the second grinding conveying line 21 and the third grinding conveying line 22 of the grinding assembly located on the right side of the unloading manipulator 19 are sequentially arranged on the right side of the unloading manipulator 19 from front to back and are all arranged in parallel, the lengths of the first grinding conveying line 20, the second grinding conveying line 21 and the third grinding conveying line 22 are sequentially increased and are all arranged perpendicular to the unloading conveying line 17, the number of the grinding machine groups 23 is three, the three grinding machine groups 23 are arranged on the rear side of the third grinding conveying line 22 in parallel and are all arranged perpendicular to the third grinding conveying line 22, and a transverse moving conveying mechanism 24 is arranged between the innermost grinding machine group 23 and the first grinding conveying line 20, between the middle grinding machine group 23 and the second grinding conveying line 21 and between the outermost grinding machine group 23 and the third grinding conveying line 22; the warehousing assembly comprises a finished product material transfer conveying line 25 and a finished product natural air drying area 26; the feeding end of the finished product material transfer conveying line 25 is matched with the discharging end of each transverse moving and carrying mechanism 24, and the finished product natural air drying area 26 is arranged at the discharging end of the finished product material transfer conveying line 25.

In a preferred embodiment of the present invention, the automatic production line for magnetic materials further comprises a temporary storage 28, and the temporary storage 28 is arranged at the right side of the transfer line 7 for the blanks to be fired.

In a preferred embodiment of the invention, the blank-making assembly further comprises a brushing device 29, the brushing device 29 being provided at the discharge end of the blank laminator 3.

The working principle is as follows: the powdery magnetic material is made into a required magnetic material shape by a blank making machine 1 through a powder forming process, then blanks are arranged according to a rule by a blank arranging machine 2, the prepared blanks are regularly stacked and piled into a specified layer number by a blank stacking machine 3, and a layer of sand is uniformly supplemented on a burning bearing plate by a sand supplementing device 4 before stacking so as to prevent the bottom connection phenomenon in the sintering process; after stacking, transferring the burning bearing plate to a specified position by a burning bearing plate material shifting device 5, mutually matching the transferring mechanical arm 6 with four blank making machines 1 to transfer the stacked magnetic material to a blank conveying line 7 to be sintered so as to convey the stacked magnetic material to the specified position, then shifting the stacked magnetic material into a feeding conveying line 12 by a blank shifting device 13 to be sintered, conveying the blank to be sintered onto a transition conveying line 10 to be sintered under the work of a blank pushing cylinder 14 to be sintered, and conveying the magnetic material to be sintered into a burning cabin 11 of a sintering furnace under the action of a magnetic material pushing cylinder 9 so as to complete the sintering of the magnetic material; after sintering, the sintered material enters a transition bin 16 of the sintering furnace and is transferred to a discharge conveying line 17 by virtue of a sintered blank material shifting device 15, and the sintering-removed sintering bearing plate and the sintering-removed sintering bearing column are respectively transferred to a sintering bearing plate conveying line 8 and a sintering bearing column conveying line 27 under the operation of a recycling manipulator 18 so as to be conveyed back to the blank making assembly for recycling; the discharging manipulator 19 transfers the sintered magnetic material to a first grinding conveying line 20, a second grinding conveying line 21 and a third grinding conveying line 22 in sequence, and then the sintered magnetic material is sent to a corresponding grinding machine group 23 under the work of a transverse moving and conveying mechanism 24, and the grinding machine group 23 is responsible for grinding the magnetic material to a finished product; after grinding is finished, the finished product materials are moved to a finished product material transfer conveying line 25 under the operation of the transverse moving and conveying mechanism 24, and finally are conveyed to a finished product natural air drying area 26 for natural air drying; if the material transported by the conveyor line 7 for burning blanks is too much to be sintered, the material can be temporarily put into a temporary warehouse 28; some of the blanks to be sintered are also coated with a protective film by means of a coating device 29 before sintering.

The invention reasonably connects four links of blank making, sintering, grinding and warehousing in the production process of the magnetic material, so that feeding and discharging in each link are automatically carried out, and auxiliary parts used in the production process are automatically recycled, thereby greatly reducing the labor cost, reducing the labor intensity and effectively improving the production efficiency.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those skilled in the art that various changes in the embodiments and modifications thereof may be made, and equivalents may be substituted for elements thereof; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims

1. An automatic production line for magnetic materials is characterized by comprising a blank making assembly, a transferring manipulator, a to-be-sintered blank conveying line, a sintering plate conveying line, a sintering assembly, a sintering column conveying line, a grinding assembly and a warehousing assembly; the conveying device comprises a conveying manipulator, a transfer manipulator, a blank-making assembly, a sand supplementing device and a blank-containing plate stirring device, wherein the blank-making assembly comprises four blank-making assemblies which are arranged on the outer side of the transfer manipulator in a pairwise symmetrical manner, the two blank-making assemblies are distributed on the left side and the right side of the conveying manipulator, the blank-making assemblies comprise a blank making machine, a blank arranging machine, a blank laminating machine, a sand supplementing device and a blank-containing plate stirring device, the discharge end of the blank making machine is connected with the feed end of the blank arranging machine, the feed end of the blank-containing plate stirring device is matched with the conveying line of the blank-making plate, the discharge end of the blank-containing plate stirring device is connected with the feed end of the blank laminating machine through the sand supplementing device, and the discharge end of the blank arranging machine is matched with the feed end of the blank laminating machine; the sintering assembly is arranged on the left side of the middle of the to-be-sintered blank conveying line, the to-be-sintered blank pushing device, the to-be-sintered blank pushing cylinder and the to-be-sintered blank pushing cylinder are arranged on the front side of the discharging end of the to-be-sintered blank conveying line, the to-be-sintered blank pushing cylinder, the to-be-sintered column conveying line and the to-be-sintered assembly are arranged between the to-be-sintered plate conveying line and the sintering assembly, the utility model discloses a sintering furnace transition bin, including sintering furnace transition bin, unloading manipulator, grinding subassembly, it includes the sintering furnace transition bin, the sintering furnace transition bin is located to the blank that has burnt material device, the feed end of the transfer chain of unloading links to each other with the discharge end of sintering furnace transition bin and arranges mutually perpendicular, the recovery manipulator locate the discharge end of the transfer chain of unloading and all mutually support with the feed end of holding burning post transfer chain and holding burning board transfer chain, the discharge manipulator locates the discharge end of the transfer chain of unloading and locates the downstream side of recovery manipulator, the grinding subassembly includes two, two the left and right sides of unloading manipulator is located to the grinding subassembly symmetry, the rear side of two grinding subassemblies is located to the warehouse entry subassembly.

2. The automatic production line of magnetic materials as claimed in claim 1, wherein the grinding assembly comprises a first grinding conveyor line, a second grinding conveyor line, a third grinding conveyor line, a grinding machine set and a transverse moving and carrying mechanism, wherein the first grinding conveyor line, the second grinding conveyor line and the third grinding conveyor line of the grinding assembly on the right side of the unloading manipulator are sequentially arranged on the right side of the unloading manipulator from front to back and are all arranged in parallel, the lengths of the first grinding conveyor line, the second grinding conveyor line and the third grinding conveyor line are sequentially increased and are all arranged in a mutually perpendicular mode with the unloading conveyor line, the grinding machine set comprises three grinding machine sets, the three grinding machine sets are arranged in parallel on the rear side of the third grinding conveyor line and are all arranged in a mutually perpendicular mode with the third grinding conveyor line, and one grinding machine set on the innermost side is arranged between the grinding machine set and the first grinding conveyor line, And a transverse moving and carrying mechanism is arranged between the middle grinding machine group and the second grinding conveying line and between the outermost grinding machine group and the third grinding conveying line.

3. The automatic production line of magnetic materials as claimed in claim 1, wherein the warehousing assembly comprises a finished product material transfer conveyor line and a finished product natural air drying area; the feeding end of the finished product material transfer conveying line is matched with the discharging end of each transverse moving carrying mechanism, and the finished product natural air drying area is arranged at the discharging end of the finished product material transfer conveying line.

4. The automatic production line of magnetic materials as claimed in claim 1, further comprising a temporary warehouse provided at the right side of the conveying line for the blanks to be fired.

5. The automatic magnetic material production line of claim 1, wherein the blank assembly further comprises a painting device disposed at a discharge end of the blank laminator.