CN111168479A

CN111168479A - Magnetic force burnishing machine assembly line

Info

Publication number: CN111168479A
Application number: CN202010039756.2A
Authority: CN
Inventors: 彭敏
Original assignee: Suzhou Sunasia Precision Machinery Co ltd
Current assignee: Suzhou Sunasia Precision Machinery Co ltd
Priority date: 2020-01-15
Filing date: 2020-01-15
Publication date: 2020-05-19

Abstract

The invention discloses a magnetic polisher assembly line, which comprises a mounting rack, a mounting beam, a conveying belt, a circulating roller, a feeding structure, a magnetic box and a screening structure, wherein when polishing operation is carried out, a workpiece is placed in a workpiece feeding cylinder, a polishing needle is put into the magnetic box, a vibrating motor operates at the moment, the vibrating motor pulls the magnetic box to realize the vibration of the magnetic box, the magnetic box is mixed and delivered through a discharging cylinder, the conveying belt rotates under the coordination of the circulating roller to move the workpiece to the top side of the magnetic box, the grinding and polishing purposes are achieved through magnetic operation, after polishing, the workpiece and the polishing needle fall onto a screen plate, the screening motor operates to drive a cam to rotate, a reset spring is pushed, the vibration of the screen plate is realized under the coordination of a push rod, the workpiece and the polishing needle are separated, the workpiece slides down along the screen plate, a polishing needle eye bearing plate slides down, therefore, the polishing operation can be rapidly carried out on workpieces in batches, and the polishing efficiency is greatly improved.

Description

Magnetic force burnishing machine assembly line

Technical Field

The invention relates to the field of polishing equipment, in particular to a magnetic polishing machine assembly line.

Background

The magnetic polishing machine breaks through the traditional vibration polishing concept, and adopts magnetic field force to drag the stainless steel needle grinding material to generate rapid rotary motion, thereby achieving the multiple effects of deburring, polishing, cleaning and the like;

when a large batch of workpieces are polished, a common magnetic polishing machine can only polish one part at a time, the polishing operation efficiency is low, the polishing process is complex, the production efficiency is greatly reduced, and a magnetic polishing machine assembly line needs to be designed aiming at the defects.

Disclosure of Invention

The invention aims to provide a magnetic polisher assembly line, which solves the technical problems of low polishing operation efficiency and complex polishing process of single polishing in the existing polishing operation.

The purpose of the invention can be realized by the following technical scheme:

a magnetic polishing machine assembly line comprises a mounting frame, a mounting beam, a conveying belt, circulating rollers, a feeding structure, a magnetic box and a screening structure, wherein the mounting beam is fixed in the middle of the mounting frame through welding, the magnetic box is arranged on the top side of the mounting beam, the circulating rollers are arranged at two ends of the top side of the mounting frame and two ends of the mounting beam respectively through roller frames in a matched mode, the conveying belt is sleeved outside the four circulating rollers in an externally-tangent mode, the feeding structure is arranged at one end of the top side of the magnetic box, and the screening structure is arranged at the bottom of one side of the mounting frame;

the screening structure comprises a screening motor, a cam, a push rod, a support plate, a screening box, a reset spring, a screen plate, a collecting box and a bearing plate, wherein the support plate is fixed at the middle part of the outer wall of the screening box through welding, the screening motor is installed at the top side of the support plate through bolt matching, the output end part of the screening motor is installed by the cam, a plate groove is formed in the inner side of the box wall of the screening box, two ends of the screen plate are respectively inserted into the plate groove in a matching mode, the push rod is fixed to the side face of one end of the screen plate, the reset spring is sleeved and fixed to the outside of the push rod, the reset spring is arranged between the side face of the circumference face of one end of the push rod and the outer side box wall of the screening box, the bearing plate is arranged under the screen plate through welding, and the collecting.

As a further scheme of the invention: one end of the push rod is arranged on one side of the cam, and the end face of one end of the push rod is parallel to the circumferential surface of the cam.

As a further scheme of the invention: the inside bottom that corresponds the sieve of one side tank wall of screening case and the bottom of bearing plate have seted up the bin outlet.

As a further scheme of the invention: the pay-off structure includes shake motor, connecting rod, support frame, work piece feeding section of thick bamboo, magnetism needle case, slider, guide rail and play feed cylinder, the support frame passes through welded fastening in the top side one end of magnetic force case, the guide rail sets up the top side at the support frame, slider cooperation lock joint is in the top side of guide rail, magnetism needle case sets up the top side at the slider, work piece feeding section of thick bamboo erects the indoor portion at magnetism needle case, it puts at the bottom central point of magnetism needle case to go out the feed cylinder, the shake motor passes through the bolt cooperation and installs the top side at the support frame, rotatory rim plate is installed to the output pole tip of shake motor, the eccentric position at rotatory rim plate is installed through the pin pole cooperation to the one end of connecting rod, the other end of connecting rod passes through the pin cooperation and installs.

As a further scheme of the invention: the bottom of play feed cylinder sets up directly over the upper surface of conveyer belt, the upper surface setting of conveyer belt is directly over magnetic box.

The invention has the beneficial effects that: through setting up the pay-off structure, when polishing the operation, place the work piece inside work piece feeding cylinder, throw in the polishing needle to the inside of magnetic needle case, at this moment shake the motor operation, pull the magnetic needle case through the shake motor, realize the shake of magnetic needle case, mix through play feed cylinder and deliver, at this moment the conveyer belt is rotatory under the cooperation of circulating roll, move the work piece to the top side of magnetic force case, through magnetic force operation, reach the purpose of burnishing and polishing, after the polishing, work piece and polishing needle drop on the sieve, at this moment sieve motor operation, it is rotatory to drive the cam, promote reset spring, under the cooperation of catch bar, realize the shake of sieve, realize the separation of work piece and polishing needle, the work piece is along the sieve landing, polishing needle eye bearing plate landing, thus can be fast, carry out the polishing operation to the work piece in batches, great improvement polishing efficiency.

Drawings

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings.

FIG. 1 is an overall elevational view of the present invention;

FIG. 2 is a feed structure view of the present invention;

FIG. 3 is a screening configuration of the present invention;

in the figure: 1. a mounting frame; 2. mounting a beam; 3. a conveyor belt; 4. a circulating roller; 5. a feeding structure; 6. a magnetic box; 7. screening the structure; 51. a dithering motor; 52. a connecting rod; 53. a support frame; 54. a workpiece feed cylinder; 55. a magnetic needle box; 56. a slider; 57. a guide rail; 58. a discharging barrel; 71. a screening motor; 72. a cam; 73. a push rod; 74. a support plate; 75. screening the box; 76. a return spring; 77. a sieve plate; 78. a collection box; 79. a bearing plate.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood 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.

As shown in fig. 1-3, a magnetic polishing machine assembly line comprises a mounting frame 1, a mounting beam 2, a conveyor belt 3, circulating rollers 4, a feeding structure 5, a magnetic box 6 and a screening structure 7, wherein the mounting beam 2 is fixed in the middle of the mounting frame 1 by welding, the magnetic box 6 is arranged on the top side of the mounting beam 2, the circulating rollers 4 are respectively arranged at two ends of the top side of the mounting frame 1 and two ends of the mounting beam 2 in a matched manner through roller frames, the conveyor belt 3 is externally sleeved outside the four circulating rollers 4, the feeding structure 5 is arranged at one end of the top side of the magnetic box 6, and the screening structure 7 is arranged at the bottom of one side of the mounting frame 1;

the screening arrangement 7 comprises a screening motor 71, a cam 72, a push rod 73, a support plate 74, a screening box 75, a return spring 76, a screening plate 77, a collecting box 78 and a bearing plate 79, the support plate 74 is fixed in the middle of the outer wall of the screening box 75 through welding, the screening motor 71 is installed on the top side of the support plate 74 through bolt matching, the cam 72 is installed at the output end part of the screening motor 71, the inner side of the box wall of the screening box 75 is provided with a plate groove, two ends of the screen plate 77 are respectively matched and inserted in the plate groove, the push rod 73 is fixed on the side surface of one end of the screen plate 77, the reset spring 76 is fixedly sleeved outside the push rod 73, the reset spring 76 is arranged between the side surface of the circumferential surface of one end of the push rod 73 and the outer side box wall of the screening box 75, the bearing plate 79 is arranged under the screen plate 77 through welding, and the collecting box 78 is arranged under the bottom end of the;

one end of the push rod 73 is arranged at one side of the cam 72, and one end face of the push rod 73 is parallel to the circumferential surface of the cam 72;

a discharge port is formed in the wall of one side of the screening box 75 corresponding to the bottom end of the screening plate 77 and the bottom end of the bearing plate 79;

the feeding structure 5 comprises a shaking motor 51, a connecting rod 52, a support frame 53, a workpiece feeding barrel 54, a magnetic needle box 55, a sliding block 56, a guide rail 57 and a discharging barrel 58, wherein the support frame 53 is fixed at one end of the top side of the magnetic box 6 through welding, the guide rail 57 is arranged on the top side of the support frame 53, the sliding block 56 is buckled on the top side of the guide rail 57 in a matching manner, the magnetic needle box 55 is arranged on the top side of the sliding block 56, the workpiece feeding barrel 54 is erected inside a chamber of the magnetic needle box 55, the discharging barrel 58 is fixed at the center position of the bottom of the magnetic needle box 55, the shaking motor 51 is arranged on the top side of the support frame 53 through a bolt in a matching manner, a rotating wheel disc is arranged at the end part of an output rod of the shaking motor 51, one end of the connecting rod 52 is;

the bottom end of the discharging barrel 58 is arranged right above the upper surface of the conveying belt 3, and the upper surface of the conveying belt 3 is arranged right above the magnetic box 6, so that better feeding can be realized.

The working principle of the invention is as follows: when polishing, a workpiece is placed in the workpiece feeding cylinder 54, a polishing needle is thrown into the magnetic needle box 55, the vibrating motor 51 operates, the magnetic needle box 55 is pulled through the connecting rod 52, the magnetic needle box 55 realizes the vibration of the magnetic needle box 55 under the sliding fit of the sliding block 56 along the guide rail 57, the magnetic needle box is mixed and delivered through the discharging cylinder 58, the conveying belt 3 rotates under the cooperation of the circulating roller 4 to move the workpiece to the top side of the magnetic box 6, the grinding and polishing purposes are achieved through the magnetic force operation, after polishing, the workpiece and the polishing needle fall onto the sieve plate 77, the sieving motor 71 operates to drive the cam 72 to rotate, the reset spring 76 is pushed, the vibration of the sieve plate 77 is realized under the cooperation of the push rod 73, the workpiece and the polishing needle are separated, the workpiece slides down along the sieve plate 77, the polishing needle eye bearing plate 79 slides down, and thus the workpieces can be polished rapidly in batches, greatly improving the polishing efficiency.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims

1. The magnetic polishing machine assembly line is characterized by comprising a mounting frame (1), a mounting beam (2), a conveying belt (3), circulating rollers (4), a feeding structure (5), a magnetic box (6) and a screening structure (7), wherein the mounting beam (2) is fixed in the middle of the mounting frame (1) through welding, the magnetic box (6) is arranged on the top side of the mounting beam (2), circulating rollers (4) are arranged at two ends of the top side of the mounting frame (1) and two ends of the mounting beam (2) respectively through roller frame matching, the conveying belt (3) is externally sleeved outside the four circulating rollers (4), the feeding structure (5) is arranged at one end of the top side of the magnetic box (6), and the screening structure (7) is arranged at the bottom of one side of the mounting frame (1);

the screening structure (7) comprises a screening motor (71), a cam (72), a push rod (73), a support plate (74), a screening box (75), a reset spring (76), a screening plate (77), a collecting box (78) and a bearing plate (79), wherein the support plate (74) is fixed in the middle of the outer wall of the screening box (75) through welding, the screening motor (71) is installed on the top side of the support plate (74) through bolt matching, the cam (72) is installed at the output end part of the screening motor (71), a plate groove is formed in the inner side of the box wall of the screening box (75), two ends of the screening plate (77) are respectively matched and inserted in the plate groove, the push rod (73) is fixed on the side surface of one end of the screening plate (77), the reset spring (76) is fixedly sleeved outside the push rod (73), the reset spring (76) is arranged between the side surface of the circumference of one end of the push rod (73) and the outer side wall of the screening box, bearing plate (79) set up under sieve (77) through the welding, be provided with collecting box (78) under the bottom of sieve (77) and bearing plate (79).

2. The magnetic polisher assembly line of claim 1, wherein one end of the push rod (73) is disposed at one side of the cam (72), and an end surface of the push rod (73) is parallel to a circumferential surface of the cam (72).

3. The magnetic polisher assembly line of claim 1, wherein a discharge opening is formed in one side wall of the screening box (75) corresponding to the bottom end of the screening plate (77) and the bottom end of the bearing plate (79).

4. The magnetic polisher assembly line of claim 1, wherein the feeding structure (5) comprises a shaking motor (51), a connecting rod (52), a support frame (53), a workpiece feeding cylinder (54), a magnetic needle box (55), a sliding block (56), a guide rail (57) and a discharging cylinder (58), the support frame (53) is fixed at one end of the top side of the magnetic box (6) through welding, the guide rail (57) is arranged at the top side of the support frame (53), the sliding block (56) is buckled at the top side of the guide rail (57) in a matching manner, the magnetic needle box (55) is arranged at the top side of the sliding block (56), the workpiece feeding cylinder (54) is erected inside a chamber of the magnetic needle box (55), the discharging cylinder (58) is fixed at the center position of the bottom of the magnetic needle box (55), the shaking motor (51) is installed at the top side of the support frame (53) through bolt fitting, the end part of an output rod of the shaking motor (51) is provided with a rotary wheel disc, one end of the connecting rod (52) is arranged at the eccentric position of the rotary wheel disc in a matched mode through a pin rod, and the other end of the connecting rod (52) is arranged at the bottom of the outer side of the magnetic needle box (55) in a matched mode through a pin.

5. The magnetic polisher assembly line of claim 1, wherein the bottom end of the discharge drum (58) is disposed directly above the upper surface of the conveyor belt (3), and the upper surface of the conveyor belt (3) is disposed directly above the magnetic box (6).