CN111383817A

CN111383817A - Automatic magnet magnetizing machine

Info

Publication number: CN111383817A
Application number: CN202010347084.1A
Authority: CN
Inventors: 陈嵩; 刘会武; 李伟; 刘向阳; 陈亮
Original assignee: Jin Kun Magnet Co ltd
Current assignee: Jin Kun Magnet Co ltd
Priority date: 2020-04-28
Filing date: 2020-04-28
Publication date: 2020-07-07

Abstract

The invention relates to the technical field of magnetizer magnetization, and particularly discloses an automatic magnet magnetizing machine which comprises a machine table, a feeding mechanism, a transferring mechanism, a guiding mechanism and a magnetizing mechanism, wherein the feeding mechanism, the transferring mechanism, the guiding mechanism and the magnetizing mechanism are arranged on the machine table; the material pushing assembly comprises a first support, a thimble arranged in a sliding manner, a first cam arranged in a rotating manner, a first driving piece for driving the first cam, and a first elastic piece for driving the thimble to abut against the first cam, and the other end of the thimble abuts against a magnetizer lifted by the jacking assembly and enters the guide mechanism; jacking subassembly, the cooperation of pushing away the material subassembly realize the automation of a plurality of magnetizers material loading one by one for the mechanism of magnetizing can once only magnetize to a plurality of magnetizers that pile up the range, promotes the efficiency of magnetizing of magnetizer, and then promotes the manufacturing efficiency of magnet.

Description

Automatic magnet magnetizing machine

Technical Field

The invention relates to the technical field of magnetizer magnetization, and particularly discloses an automatic magnet magnetizing machine.

Background

The magnet is one of the common basic accessories of various electronic devices and mechanical equipment, in the production and manufacturing process of the magnet, a magnetic material needs to be processed into a magnetizer firstly, and the magnetizer is magnetized to enable the magnetizer to become the magnet.

Disclosure of Invention

In order to overcome the defects and shortcomings in the prior art, the invention aims to provide the automatic magnet magnetizing machine, the jacking assembly and the pushing assembly are matched to realize automatic one-by-one feeding of the plurality of magnetizers, so that the magnetizing mechanism can magnetize the plurality of magnetizers which are stacked and arranged at one time, the magnetizing efficiency of the magnetizers is improved, and the manufacturing efficiency of the magnets is further improved.

In order to achieve the above object, the present invention provides an automatic magnet magnetizer, including a machine table, a feeding mechanism, a transferring mechanism, a guiding mechanism and a magnetizing mechanism, the feeding mechanism, the transferring mechanism, the guiding mechanism and the magnetizing mechanism are arranged on the machine table, the feeding mechanism automatically supplies external magnetizers, the transferring mechanism is used for transferring the magnetizers supplied by the feeding mechanism to the guiding mechanism and automatically moving the magnetizers into the magnetizing mechanism under the guidance of the guiding mechanism, and the magnetizing mechanism magnetizes the magnetizers to enable the magnetizers to become magnets; the transfer mechanism comprises a jacking assembly, a pushing assembly and an electronic counter, the jacking assembly is used for lifting the magnetizers supplied by the feeding mechanism to be flush with the guide mechanism, the pushing assembly is used for pushing the magnetizers jacked by the jacking assembly into the guide mechanism, and the electronic counter is used for calculating the number of the magnetizers entering the guide mechanism; the material pushing assembly comprises a first support, a thimble, a first cam, a first driving piece and a first elastic piece, wherein the first support is arranged on the machine table, the thimble is arranged on the first support in a sliding mode, the first cam is arranged on the first support in a rotating mode, the first driving piece is used for driving the first cam to rotate, the first elastic piece is used for driving the thimble to enable one end of the thimble to abut against the outer side face of the first cam, and the other end of the thimble is used for abutting against a magnetizer lifted by the jacking assembly to.

The guide mechanism is provided with a guide groove communicated with the magnetizing mechanism, the guide groove is parallel to the horizontal plane, an ingredient block is slidably arranged in the guide groove, the other end of the ejector pin is used for abutting against a magnetizer lifted by the jacking assembly to enable the magnetizer to enter the guide groove, and the magnetizer in the guide groove is positioned between the ingredient block and the ejector pin.

The first support is provided with a first carrying piece in a sliding mode, the ejector pin is arranged on the first carrying piece, the first carrying piece is provided with a rotating wheel in a rotating mode, the rotating axis of the rotating wheel is parallel to the rotating axis of the first cam, and the first elastic piece drives the first carrying piece to enable the outer side face of the rotating wheel to abut against the outer side face of the first cam.

The jacking assembly is provided with a jacking part and a second driving part, the jacking part is provided with a containing groove and a yielding groove communicated with the containing groove, the containing groove is used for containing a magnetizer supplied by the feeding mechanism, and the ejector pin is abutted against the magnetizer in the containing groove through the yielding groove to drive the magnetizer to enter the guide mechanism from the containing groove.

Wherein, jacking subassembly still including rotate the second cam that sets up, be used for driving the liftout piece so that the lower extreme of liftout piece contradicts the second elastic component at the lateral surface of second cam, the second driving piece is used for driving the second cam and rotates, and the liftout piece slides along vertical direction and sets up in first support, holds silo, guide way and all sets up in the upper end of liftout piece.

The machine table is provided with a second support and a third driving piece, the guide groove is arranged on the second support, and the guide groove is formed by being concavely arranged from the top surface of the second support; the output end of the third driving piece is detachably connected with a cover plate used for covering the opening of the guide groove, and the cover plate covers the opening of the guide groove to prevent the magnetizer from jumping out of the guide groove.

The device also comprises a first baffle arranged on the second support, a second baffle which is arranged on the second support in a sliding mode and is parallel to the first baffle, and a fourth driving piece used for driving the second baffle to be close to or far away from the first baffle, wherein a guide groove is formed in a gap between the first baffle and the second baffle.

The magnetizing mechanism comprises a material containing groove communicated with the guide groove and a magnetizing machine core matched with the material containing groove, the material containing groove and the guide groove are arranged in a collinear mode, and the magnetizing machine core is used for magnetizing a magnetizer in the material containing groove into a magnet.

Wherein, the board is provided with receiving hopper and fifth driving piece, and the output of fifth driving piece is connected with the push pedal, and push pedal, guiding mechanism are located the both sides of magnetizing mechanism respectively, and fifth driving piece drive push pedal makes the magnet of output appearance silo fall into in the receiving hopper.

The feeding mechanism comprises a vibration disc and a linear vibration conveyor, the vibration disc is used for sequentially arranging a plurality of magnetizers into the linear vibration conveyor, the linear vibration conveyor is used for conveying the plurality of magnetizers input by the vibration disc to the jacking assembly, and the jacking assembly is used for jacking the magnetizers output by the linear vibration conveyor one by one.

Has the advantages that: the feeding mechanism realizes automatic supply of magnetizers, the jacking assembly of the transfer mechanism jacks the magnetizers supplied by the feeding mechanism to the guide mechanism, the pushing assembly of the transfer mechanism pushes the magnetizers jacked by the jacking assembly into the guide mechanism one by one, the jacking assembly and the pushing assembly are matched with each other so as to realize automatic one-by-one feeding of a plurality of magnetizers, the electronic calculator automatically calculates and accumulates the number of the magnetizers entering the guide mechanism, the guide mechanism guides a plurality of magnetizers arranged and pasted together to enter the magnetizing mechanism, so that the magnetizing mechanism can magnetize a plurality of magnetizers stacked and arranged at one time, the magnetizing efficiency of the magnetizers is improved, and further the manufacturing efficiency of the magnets is improved.

Drawings

FIG. 1 is a top view of the present invention.

Fig. 2 is a block diagram of the pusher assembly of the present invention.

FIG. 3 is a block diagram of a jacking assembly of the present invention.

The reference numerals include:

1-machine table 2-feeding mechanism 3-transferring mechanism

4-guide mechanism 5-magnetizing mechanism 6-jacking assembly

7-pushing component 8-electronic counter 9-first support

11-thimble 12-first cam 13-first elastic element

14-guide groove 15-dosing block 16-first carrier

17-rotating wheel 18-material ejecting part 19-material containing groove

21-relief groove 22-second cam 23-second elastic element

24-cover plate 25-first baffle 26-second baffle

27-material receiving hopper 28-push plate 29-vibration disk

31-linear vibration conveyor 32-round ball.

Detailed Description

The present invention will be further described with reference to the following examples and the accompanying drawings.

Referring to fig. 1-3, the automatic magnet magnetizer of the present invention includes a machine table 1, a feeding mechanism 2 installed on the machine table 1, a transferring mechanism 3, a guiding mechanism 4 and a magnetizing mechanism 5, wherein the feeding mechanism 2 automatically supplies external magnetizers, the transferring mechanism 3 is used for transferring the magnetizers supplied by the feeding mechanism 2 to the guiding mechanism 4 and automatically moving the magnetizers into the magnetizing mechanism 5 under the guidance of the guiding mechanism 4, and the magnetizing mechanism 5 magnetizes the magnetizers to make the magnetizers become magnets.

The transfer mechanism 3 comprises a jacking assembly 6, a pushing assembly 7 and an electronic counter 8, the jacking assembly 6 is arranged on the machine table 1, the electronic counter is matched with the jacking assembly 6 or/and the pushing assembly 7 for use, the jacking assembly 6 is used for lifting magnetizers supplied by the feeding mechanism 2 to a position flush with the guide mechanism 4, the pushing assembly 7 is used for pushing the magnetizers jacked by the jacking assembly 6 into the guide mechanism 4, and the electronic counter 8 is used for counting the number of the magnetizers entering the guide mechanism 4, so that the number of the magnetizers can be accurately counted.

The material pushing assembly 7 comprises a first support 9 arranged on the machine table 1, an ejector pin 11 arranged on the first support 9 in a sliding mode, a first cam 12 arranged on the first support 9 in a rotating mode, a first driving piece used for driving the first cam 12 to rotate, and a first elastic piece 13 used for driving the ejector pin 11 to enable one end of the ejector pin 11 to abut against the outer side face of the first cam 12, wherein the ejector pin 11 slides left and right relative to the horizontal plane parallel to the first support 9, the rotating axis of the first cam 12 extends in the vertical direction, the first driving piece is a motor used for driving the first cam 12 to rotate, the first elastic piece 13 is a spring, and two ends of the first elastic piece 13 are arranged on the first support 9 and the ejector pin 11 respectively. The first driving element drives the first cam 12 to make the thimble 11 slide relative to the first bracket 9, and the other end of the sliding thimble 11 is used for abutting against the magnetizer lifted by the jacking assembly 6 to make the magnetizer automatically enter the guiding mechanism 4.

The feeding mechanism 2 realizes the automatic supply of magnetizers, the jacking assembly 6 of the transfer mechanism 3 jacks the magnetizers supplied by the feeding mechanism 2 to the guide mechanism 4, the pushing assembly 7 of the transfer mechanism 3 pushes the magnetizers jacked by the jacking assembly 6 to the guide mechanism 4 one by one, the jacking assembly 6 and the pushing assembly 7 are mutually matched so as to realize the automatic one-by-one feeding of a plurality of magnetizers, the electronic calculator automatically calculates and accumulates the number of the magnetizers entering the guide mechanism 4, the guide mechanism 4 guides a plurality of magnetizers arranged and pasted together to enter the magnetizing mechanism 5, so that the magnetizing mechanism 5 can magnetize a plurality of magnetizers arranged in a stacking mode at one time, the magnetizing efficiency of the magnetizers is improved, and the manufacturing efficiency of the magnets is further improved.

The guiding mechanism 4 is provided with a guiding groove 14 communicated with the magnetizing mechanism 5, the guiding groove 14 is parallel to the horizontal plane, an ingredient block 15 is slidably arranged in the guiding groove 14, the other end of the ejector pin 11 is used for abutting against a magnetizer lifted by the jacking assembly 6 to enable the magnetizer to enter the guiding groove 14, and the magnetizer in the guiding groove 14 is positioned between the ingredient block 15 and the ejector pin 11.

As the pushing assembly 7 pushes the magnetizers into the guide slot 14 of the guide mechanism 4 one by one, the magnetizers intermittently move along the length direction of the guide slot 14 until the magnetizers enter the magnetizing mechanism 5. In the process of moving the magnetizer, the inner groove wall of the guide groove 14 is used for stopping and limiting the magnetizer, so that the magnetizer is prevented from being inclined in the moving process. The ingredient block 15 is pressed on the bottom surface of the guide groove 14 under the action of gravity, and the magnetizer which enters the guide groove 14 for the first time is blocked by the ingredient block 15, so that the subsequent poor arrangement of the magnetizer caused by the fact that the magnetizer inclines and falls on the bottom surface of the guide groove 14 is avoided.

The first carrier 16 is arranged on the first support 9 in a sliding mode, the first carrier slides parallel to the horizontal plane, the ejector pins 11 are arranged on the first carrier, the rotating wheels 17 are arranged on the first carrier 16 in a rotating mode, the rotating axes of the rotating wheels 17 extend in the vertical direction, the rotating axes of the rotating wheels 17 and the rotating axes of the first cams 12 are arranged at intervals in parallel, and the first elastic pieces 13 drive the first carrier 16 to enable the outer side faces of the rotating wheels 17 to always abut against the outer side faces of the first cams 12.

The rotating wheel 17 is always abutted against the first cam 12 by the aid of the elastic restoring force of the first elastic piece 13, during actual use, the first driving piece drives the first cam 12 to rotate, the rotating first cam 12 can drive the first carrying piece 16 to slide through the rotating wheel 17, the sliding first carrying piece 16 can drive the ejector pin 11 to move together, the movable ejector pin 11 pushes the magnetizer jacked by the jacking assembly 6 into the guide mechanism 4, and automatic one-by-one feeding of the magnetizer is realized. By means of the runner 17, the frictional noise between the first carrier 16 and the first cam 12 is reduced, and the wear between the two is delayed.

The jacking assembly 6 is provided with a jacking part 18 arranged in a lifting mode and a second driving part used for driving the jacking part 18 to move, the jacking part 18 moves up and down along the vertical direction, the jacking part 18 is provided with a material accommodating groove 19 and a position-giving groove 21 communicated with the material accommodating groove 19, the material accommodating groove 19 is used for accommodating a magnetizer supplied by the feeding mechanism 2, and the magnetizer is stopped and limited by using the inner groove wall of the material accommodating groove 19 so as to prevent the magnetizer from falling off the jacking part 18. Of course, different ejector 18 can be replaced and selected according to the shape and the structure of the magnetizer. In actual use, the thimble 11 abuts against the magnetizer in the driving container 19 through the receding slot 21, so that the magnetizer moves from the container 19 into the guiding mechanism 4. After the magnetizer enters the guiding mechanism 4 from the material accommodating slot 19, the thimble 11 exits from the abdicating slot 21 to prepare for pushing the magnetizer in the material accommodating slot 19 into the guiding mechanism 4 next time.

The jacking assembly 6 further comprises a second cam 22 rotatably arranged, and a second elastic member 23 for driving the jacking member 18 to enable the lower end of the jacking member 18 to abut against the outer side surface of the second cam 22, preferably, the second elastic member 23 is a spring, the second driving member is used for driving the second cam 22 to rotate, the jacking member 18 is slidably arranged on the first bracket 9 along the vertical direction, and the material accommodating groove 19 and the guide groove 14 are both arranged on the upper end of the jacking member 18. During practical use, the magnetizer output by the feeding mechanism 2 automatically enters the containing groove 19, then the second driving piece drives the second cam 22 to rotate, so that the ejecting piece 18 slides upwards, the ejecting piece 18 sliding upwards drives the magnetizer in the containing groove 19 to ascend to the position of the guide groove 14 of the parallel and level guide mechanism 4, and then the first driving piece drives the first cam 12, so that the ejector pin 11 pushes the magnetizer in the containing groove 19 into the guide groove 14 through the abdicating groove 21.

A second bracket and a third driving piece are arranged on the machine table 1, a guide groove 14 is arranged on the second bracket, and the guide groove 14 is formed by recessing the top surface of the second bracket; the output end of the third driving member is detachably connected with a cover plate 24 for covering the opening of the guiding slot 14, and the cover plate 24 covers the opening of the guiding slot 14 to prevent the magnetizer from jumping out of the guiding slot 14.

The cover plate 24 is used for covering the magnetizers in the guide slot 14, so that the magnetizers in the guide slot 14 are prevented from jumping out of the guide slot 14 in the moving process, and when the magnetizing mechanism 5 magnetizes the magnetizers entering the magnetizing mechanism 5, the magnetizers in the guide slot 14 outside the magnetizing mechanism 5 are prevented from jumping out, and the magnetizing yield of the magnetizers is improved.

The device further comprises a first baffle plate 25 arranged on the second support, a second baffle plate 26 arranged on the second support in a sliding mode and parallel to the first baffle plate 25, and a fourth driving piece used for driving the second baffle plate 26 to be close to or far away from the first baffle plate 25, wherein the baffle plates are approximately rectangular flat plates, and a guide groove 14 is formed in a gap between the first baffle plate 25 and the second baffle plate 26. During actual use, according to the actual size of the magnetizer, the fourth driving part drives the second baffle 26 to move, so that the width between the first baffle 25 and the second baffle 26 is changed, the width between the two baffles can be compatible with the magnetizers with various sizes, one magnetizer can magnetize the magnetizers with various sizes, and the manufacturing cost of the magnet is reduced.

The magnetizing mechanism 5 comprises a material containing groove 19 communicated with the guide groove 14 and a magnetizing movement matched with the material containing groove 19, the material containing groove 19 and the guide groove 14 are arranged in a collinear way, and the magnetizing movement is used for magnetizing a magnetizer in the material containing groove 19 into a magnet. The inner groove wall of the material containing groove 19 is used for stopping and limiting the plurality of magnetizers entering the magnetizing mechanism 5, so that the magnetizers are prevented from moving in the magnetizing process to avoid bad magnetizing, and the magnetizing yield of the magnetizers is improved.

Be provided with receiving hopper 27 and fifth driving piece on board 1, the output of fifth driving piece is connected with push pedal 28, and push pedal 28, guiding mechanism 4 are located the left and right sides of magnetizing mechanism 5 respectively, and push pedal 28, receiving hopper 27 are located the same one side of magnetizing mechanism 5, and fifth driving piece drive push pedal 28 makes the magnet of output holding silo 19 fall into receiving hopper 27 to realize the unified collection of magnet. Preferably, the receiving hopper 27 is provided with an inclined plate along which the magnet slides automatically under its own weight to the desired collection place when the push plate 28 pushes the magnet into the receiving hopper 27. Preferably, the inclined plate is provided with a plurality of balls 32 that roll, and the magnets press against the balls 32 and slide quickly and easily to the desired collection location.

Feeding mechanism 2 includes vibration dish 29 and linear vibration conveyer 31, vibration dish 29 and linear vibration conveyer 31 are prior art, no longer describe herein, during the in-service use, put into vibration dish 29 with a plurality of magnetizers, vibration dish 29 is used for arranging a plurality of magnetizers in proper order and gets into linear vibration conveyer 31, linear vibration conveyer 31 is used for carrying a plurality of magnetizers of vibration dish 29 input to jacking subassembly 6, jacking subassembly 6 is used for jacking up the magnetizer of linear vibration conveyer 31 output one by one.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and should not be taken as limiting the invention.

Claims

1. An automatic magnet magnetizer comprises a machine table, a feeding mechanism, a transferring mechanism, a guiding mechanism and a magnetizing mechanism, wherein the feeding mechanism, the transferring mechanism, the guiding mechanism and the magnetizing mechanism are arranged on the machine table; the method is characterized in that: the transfer mechanism comprises a jacking assembly, a pushing assembly and an electronic counter, the jacking assembly is used for lifting the magnetizers supplied by the feeding mechanism to be flush with the guide mechanism, the pushing assembly is used for pushing the magnetizers jacked by the jacking assembly into the guide mechanism, and the electronic counter is used for calculating the number of the magnetizers entering the guide mechanism; the material pushing assembly comprises a first support, a thimble, a first cam, a first driving piece and a first elastic piece, wherein the first support is arranged on the machine table, the thimble is arranged on the first support in a sliding mode, the first cam is arranged on the first support in a rotating mode, the first driving piece is used for driving the first cam to rotate, the first elastic piece is used for driving the thimble to enable one end of the thimble to abut against the outer side face of the first cam, and the other end of the thimble is used for abutting against a magnetizer lifted by the jacking assembly to.

2. The automatic magnet charger according to claim 1, wherein: the guide mechanism is provided with a guide groove communicated with the magnetizing mechanism, the guide groove is parallel to the horizontal plane, an ingredient block is slidably arranged in the guide groove, the other end of the ejector pin is used for abutting against a magnetizer lifted by the jacking assembly to enable the magnetizer to enter the guide groove, and the magnetizer in the guide groove is positioned between the ingredient block and the ejector pin.

3. The automatic magnet charger according to claim 1, wherein: the first support is provided with a first carrying piece in a sliding mode, the ejector pin is arranged on the first carrying piece, the first carrying piece is provided with a rotating wheel in a rotating mode, the rotating axis of the rotating wheel is parallel to the rotating axis of the first cam, and the first elastic piece drives the first carrying piece to enable the outer side face of the rotating wheel to abut against the outer side face of the first cam.

4. The automatic magnet charger according to claim 1, wherein: the jacking assembly is provided with a jacking part and a second driving part, the jacking part is provided with a containing groove and a yielding groove communicated with the containing groove, the containing groove is used for containing a magnetizer supplied by the feeding mechanism, and the ejector pin is abutted against the magnetizer in the containing groove through the yielding groove to drive the magnetizer to move from the containing groove to enter the guide mechanism.

5. The automatic magnet charger according to claim 4, wherein: the jacking assembly further comprises a second cam which is rotatably arranged, a second elastic piece which is used for driving the jacking piece to enable the lower end of the jacking piece to abut against the outer side face of the second cam, a second driving piece is used for driving the second cam to rotate, the jacking piece is arranged on the first support in a sliding mode along the vertical direction, and the material accommodating groove and the guide groove are both formed in the upper end of the jacking piece.

6. The automatic magnet charger according to claim 2, wherein: the machine table is provided with a second bracket and a third driving piece, the guide groove is arranged on the second bracket, and the guide groove is formed by being concavely arranged from the top surface of the second bracket; the output end of the third driving piece is detachably connected with a cover plate used for covering the opening of the guide groove, and the cover plate covers the opening of the guide groove to prevent the magnetizer from jumping out of the guide groove.

7. The automatic magnet charger according to claim 6, wherein: the device also comprises a first baffle arranged on the second support, a second baffle which is arranged on the second support in a sliding mode and is parallel to the first baffle, and a fourth driving piece used for driving the second baffle to be close to or far away from the first baffle, wherein a guide groove is formed in a gap between the first baffle and the second baffle.

8. The automatic magnet charger according to claim 2, wherein: the magnetizing mechanism comprises a material containing groove communicated with the guide groove and a magnetizing machine core matched with the material containing groove, the material containing groove and the guide groove are arranged in a collinear way, and the magnetizing machine core is used for magnetizing a magnetizer in the material containing groove into a magnet.

9. The automatic magnet charger according to claim 8, wherein: the board is provided with receiving hopper and fifth driving piece, and the output of fifth driving piece is connected with the push pedal, and push pedal, guiding mechanism are located the both sides of magnetizing mechanism respectively, and fifth driving piece drive push pedal makes the magnet of output appearance silo fall into in the receiving hopper.

10. The automatic magnet charger according to claim 1, wherein: the feeding mechanism comprises a vibration disc and a linear vibration conveyor, the vibration disc is used for sequentially arranging a plurality of magnetizers into the linear vibration conveyor, the linear vibration conveyor is used for conveying the plurality of magnetizers input by the vibration disc to the jacking assembly, and the jacking assembly is used for jacking the magnetizers output by the linear vibration conveyor one by one.