CN115872167A - High-conductivity ferrite magnetic core queuing and stacking device - Google Patents

Abstract

The invention relates to the field of ferrite core transportation equipment, in particular to a high-conductivity ferrite core queuing and stacking device, wherein a sliding rail support unit, a first conveying unit and a second conveying unit are arranged on a box platform, the front side and the rear side of the second conveying unit are respectively provided with a horizontal pushing unit and a third conveying unit, and a stacking and stacking unit is connected to the sliding rail support unit in a sliding manner, so that the transportation process of ferrite cores entering a stacking and placing process from a sintering process is optimized, the first conveying belt and the second conveying belt are not interfered with each other, and the second conveying unit can queue and collect materials conveniently; the materials which are queued to form a line can be orderly pushed away from the second transportation unit under the action of the horizontal pushing unit, so that the materials are temporarily transferred to a platform of the third transportation unit, and stacked to a plurality of rows of magnetic cores on the platform of the third transportation unit for transfer stacking, the queuing stacking sequence and the conveying path are optimized, and errors in the stacking process are relieved.

Description

High ferrite core pile up neatly device of lining up

Technical Field

The invention relates to the field of ferrite core transportation equipment, in particular to a high-conductivity ferrite core queuing and stacking device.

Background

The high-conductivity ferrite magnetic core is a high-frequency magnetic conductive material, mainly used as high-frequency transformer (like switch power supply and line output transformer), high-frequency magnetic ring (for resisting interference) and others, can raise magnetic conductivity and raise inductance quality factor, and is a common equipment for transformer, and is mainly made up by using sintering process.

Because the ferrite core is led to the height can form the finished product through the sintering, because the ferrite core product part is led to the height little, the temperature after the sintering is high, pile up neatly discharges factor influences such as difficulty, and the artifical inefficiency of putting the pile up neatly, unsatisfied production demand, current pile up neatly equipment supply line design is more unreasonable, especially pushes away from the in-process of putting from the assembly line, causes the destruction of the magnetic core formation of waiting to put very easily to influence the pile up neatly process of lining up in later stage.

Disclosure of Invention

The technical problem that the later stacking procedure is influenced due to the fact that the ferrite core equipment is prone to being placed in a fault in the queuing and stacking process is solved; the invention provides a high-conductivity ferrite magnetic core queuing and stacking device.

The technical problem of the invention is realized by the following technical scheme: the utility model provides a high ferrite core pile up neatly device of lining up, includes box platform and the control unit, be provided with slide rail bracket unit on the box platform, the upper portion of box platform has set gradually first conveying unit and second conveying unit along material direction of delivery, the front side of second conveying unit is provided with horizontal propelling movement unit, the rear side of second conveying unit is provided with third conveying unit, first conveying unit and second conveying unit's direction of delivery is unanimous, third conveying unit sets up perpendicularly relatively with second conveying unit's material direction of delivery, sliding connection has the pile up the unit on the slide rail bracket unit, the pile up the unit and be located the upper portion of third conveying unit, first conveying unit, second conveying unit, horizontal propelling movement unit, third conveying unit and pile up the unit respectively with the control unit communication connection.

By using the technical scheme, the transportation process of the ferrite magnetic core from the sintering process to the stacking process is optimized, and the first conveying unit and the second conveying unit are arranged, so that the magnetic core materials can be transported in stages on a production line, the first conveying belt and the second conveying belt are not interfered with each other, and the second conveying unit can queue and collect the materials conveniently; the second transportation unit and the third transportation unit are relatively vertical in transportation direction, materials which are lined up to form a line and completed can be orderly pushed away from the second transportation unit under the action of the horizontal pushing unit, so that the materials are temporarily transferred to a platform of the third transportation unit, and the materials are stacked to a plurality of rows of magnetic cores to be transferred and stacked on the platform of the third transportation unit, so that the sequence and the transmission path of the lined stacking are optimized, and errors in the stacking process are relieved.

Preferably, the horizontal pushing unit comprises a pushing mounting support, a rodless pushing cylinder and a horizontal front pushing plate, the rodless pushing cylinder is symmetrically arranged on the front side of the pushing mounting support, one end of the rodless pushing cylinder is fixedly connected with the horizontal front pushing plate, and the horizontal front pushing plate is located above the second conveying unit.

Preferably, the horizontal pushing unit further comprises a step guide rail, a synchronous pushing connecting rod, a synchronous pushing support and a lifting rear baffle; the step guide rail sets up in both sides between the no pole propelling movement cylinder, both sides another tip fixed connection of no pole propelling movement cylinder is synchronous to push the connecting rod, the one end of synchronous propelling movement support with synchronous propelling movement connecting rod rotates to be connected, the other end and lifting backplate fixed connection, the lifting backplate is located the top of second conveying unit, the lower part of synchronous propelling movement support with step guide rail sliding connection.

Through using above technical scheme, horizontal propelling movement unit adopts the dual structure design of horizontal propelling movement board and lifting backplate, the conveyer belt between horizontal propelling movement board and the lifting backplate is used for arranging the magnetic core on the conveyer belt and arranges with the slivering, simultaneously at the in-process that shifts from second conveying unit, horizontal propelling movement board and lifting backplate treat the magnetic core strip group that shifts and play good limiting displacement, guarantee magnetic core strip group from second conveying unit to third conveying unit's good transition, can not cause in disorder, influence the pile up neatly of arranging in the later stage, lifting backplate is raised to the automation that the structural design of step guide rail can be timely simultaneously, from not influencing normal arranging in proper order and putting the process.

Preferably, the stacking and stacking unit comprises a stacking and mounting frame, a stacking and driving mechanism, an outer lifting module and an inner adsorption module, the stacking and mounting frame is connected with the slide rail support unit in a sliding manner, and the stacking and driving mechanism drives the stacking and mounting frame to be capable of sliding on the slide rail support unit; the stacking driving mechanism is in communication connection with the control unit; pile up and be provided with outside lift module on the mounting bracket, be provided with inboard absorption module on the outside lift module.

Preferably, the outer side lifting module comprises a first lifting cylinder and an outer side adsorption template; first lift cylinder is installed pile up on the mounting bracket, the flexible end fixed connection outside adsorption formwork of first lift cylinder.

Preferably, the inner side adsorption module comprises a second lifting cylinder and an inner side magnetic adsorption plate; the second lifting cylinder is arranged on the upper portion of the outer side adsorption template, the extending end of the second lifting cylinder is fixedly connected with the inner side magnetic attraction plate, and the inner side magnetic attraction plate is located inside the outer side adsorption template.

Through using above technical scheme, the inboard absorption module passes through the second lift cylinder and adsorbs the elevating sliding motion in the template in the outside to realized the square magnetic core group after will arranging accurate transfer pile up neatly process, guaranteed that the magnetic core buttress layer after the pile up neatly can not misplace and collapse.

Preferably, a brush mechanism is further arranged on the first conveying unit and comprises a brush support, a brush motor and a brush, the brush support is connected to the side portion of the first conveying unit through bolts, the brush motor is fixedly mounted on the upper portion of the brush support, the output end of the brush motor is fixedly connected with the brush, the brush is located above the first conveying unit, and the brush motor is in communication connection with the first conveying unit.

Through using above technical scheme, brush mechanism is used for cleaning burr residue etc. after the sintering of the upper surface to the magnetic core, promotes product quality, and the bolt-up spout that sets up on the brush support simultaneously can adjust the brush for the height of conveyer belt to the surface cleaning work of the product of adaptation co-altitude, model.

Preferably, the first conveying unit comprises a first mounting frame group, a first conveying belt group and a first driving motor; the first mounting frame group is fixedly arranged on the box body platform; the first mounting frame set is provided with a first conveyor belt set, the end part of the first conveyor belt set is connected with a first driving motor, and the first driving motor is in communication connection with the control unit.

Preferably, the device further comprises a counting detection unit, the counting detection unit is arranged on the second conveying unit close to the horizontal pushing unit, and the counting detection unit is in communication connection with the control unit.

By using the technical scheme, the counting detection unit feeds back counting signals of the materials before entering the horizontal pushing unit, so that the start and stop of the conveying line of the second conveying unit are controlled, and the queuing and pushing process of the magnetic cores is facilitated.

Preferably, the upper portion of the first conveying unit is further provided with a material limiting strip group, the material limiting strip group comprises door frame supports, limiting connecting pieces and limiting strip rails, the door frame supports are connected to the two sides of the first mounting frame group through bolts, the upper portions of the door frame supports are connected with the limiting strip rails through the limiting connecting pieces, and the limiting strip rails are located on the upper portion of the first conveying belt group.

Through using above technical scheme, the material transportation passageway that the spacing strip of material formed carries out spacing queuing to the magnetic core piece on the first conveying unit, guarantees that the magnetic core piece gets into the process of lining up in order, can not cause the magnetic core piece skew because of the influence of brush mechanism simultaneously, influences normal line transportation process.

In conclusion, the invention has the following beneficial effects:

according to the high-conductivity ferrite core queuing device, the transportation process of ferrite cores from a sintering process to a stacking process is optimized, and the first conveying unit and the second conveying unit are arranged, so that magnetic core materials can be carried out stage by stage in the conveying process on a production line, the first conveying belt and the second conveying belt are not interfered with each other, and the second conveying unit can queue and collect the materials conveniently; the second transportation unit and the third transportation unit are relatively vertical in transportation direction, materials which are lined up to form a line and completed can be orderly pushed away from the second transportation unit under the action of the horizontal pushing unit, so that the materials are temporarily transferred to a platform of the third transportation unit, and the materials are stacked to a plurality of rows of magnetic cores to be transferred and stacked on the platform of the third transportation unit, so that the sequence and the transmission path of the lined stacking are optimized, and errors in the stacking process are relieved.

2. The horizontal pushing unit adopts a dual structure design of the horizontal pushing plate and the lifting back baffle, the conveying belt between the horizontal pushing plate and the lifting back baffle is used for arranging magnetic cores on the conveying belt in a strip shape, meanwhile, in the process of transferring from the second conveying unit, the horizontal pushing plate and the lifting back baffle have a good limiting effect on a magnetic core strip group to be transferred, good transition of the magnetic core strip group from the second conveying unit to the third conveying unit is guaranteed, disorder cannot be caused, the later-stage arrangement and stacking are influenced, and meanwhile, the lifting back baffle can be timely and automatically lifted through the structural design of the step guide rail, so that the normal sequential arrangement and placement process is not influenced.

3. According to the inner side adsorption module, the square magnetic core groups after arrangement are accurately transferred and stacked through the lifting sliding motion of the second lifting cylinder in the outer side adsorption template, and the stacked magnetic core stacks are prevented from being misplaced and collapsed; the brush mechanism is used for cleaning burr residue and the like after sintering of the upper surface of the magnetic core, product quality is improved, and meanwhile the height of the brush relative to the conveying belt can be adjusted through the bolt fastening sliding groove formed in the brush support, so that the brush mechanism is suitable for surface cleaning of products with different heights and models.

4. According to the invention, the counting detection unit feeds back a counting signal to the material before entering the horizontal pushing unit, so that the start and stop of the conveying line of the second conveying unit are controlled, and the queuing and pushing process of the magnetic core is carried out; the material transportation channel formed by the material limiting strip group is used for limiting and queuing the magnetic core blocks on the first conveying unit, so that the magnetic core blocks can enter a queuing procedure in order, and meanwhile, the magnetic core blocks cannot be deviated due to the influence of the brush mechanism, and the normal line conveying process is not influenced.

Drawings

FIG. 1 is a schematic diagram of a forward perspective structure of the present invention;

FIG. 2 is a schematic rear perspective view of the present invention;

FIG. 3 is an enlarged view of the structure at A;

FIG. 4 is an enlarged view of the structure at B;

FIG. 5 is a schematic diagram of a horizontal pushing unit and a connection structure thereof;

fig. 6 is a schematic view of the palletizing and stacking unit and the connection structure thereof.

Description of reference numerals:

1. a box platform; 2. a slide rail bracket unit; 3. a first conveying unit; 31. a first mounting bracket set; 32. a first conveyor belt set; 33. a first drive motor; 4. a second conveying unit; 5. a horizontal pushing unit; 51. pushing the mounting bracket; 52. a rodless push cylinder; 53. a horizontal front push plate; 54. a step guide rail; 55. synchronously pushing the connecting rod; 56. synchronously pushing the bracket; 57. lifting the rear baffle; 6. a third conveying unit; 7. a stacking and stacking unit; 71. stacking the mounting frames; 72. a stacking drive mechanism; 73. an outer lifting module; 731. a first lifting cylinder; 732. the outer side adsorbs the template; 74. an inner side adsorption module; 741. a second lifting cylinder; 742. an inner magnetic attraction plate; 8. a control unit; 9. a brush mechanism; 91. a brush holder; 92. a brush motor; 93. a brush; 10. a count detection unit; 11. a material limiting strip group; 111. a doorframe bracket; 112. a limiting connecting piece; 113. and limiting the strip rail.

Detailed Description

In order that the above objects, features and advantages of the present invention can be more clearly understood, the present invention will be further described with reference to the accompanying drawings and examples.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those specifically described herein, and thus the present invention is not limited to the specific embodiments of the present disclosure.

The invention discloses a high-conductivity ferrite magnetic core queuing and stacking device, which comprises a box body platform 1 and a control unit 8, wherein a slide rail support unit 2 is arranged at the upper part of the box body platform 1, an electric control main body circuit element is distributed in the box body platform 1, the slide rail support unit 2 is arranged on the box body platform 1 in a crossing manner along the axis direction, the slide rail support unit 2 is of a frame structure, a guide rail part is arranged at the rear side of a support in the horizontal direction of the slide rail support unit 2, the control unit 8 can be arranged at the front side of the slide rail support unit 2 so as to facilitate operation and control, and the control unit 8 is respectively in communication connection with parts needing electric control in a first conveying unit 3, a second conveying unit 4, a horizontal pushing unit 5, a third conveying unit 6 and a stacking unit 7, so as to control the working and operation of the whole device.

A first conveying unit 3 and a second conveying unit 4 are sequentially arranged on the upper part of the box body platform 1 along the material conveying direction, conveying lines of the first conveying unit 3 and the second conveying unit 4 are on the same axis, and specifically, the first conveying unit 3 comprises a first mounting frame group 31, a first conveying belt group 32 and a first driving motor 33; the first mounting frame group 31 is fixedly arranged on the box platform 1 in the axial direction; the first conveyor belt group 32 is installed on the first installation frame group 31, the first conveyor belt group 32 is clamped between the first installation frame group 31, meanwhile, a first driving motor 33 is connected to the end portion of the first conveyor belt group 32, a stepping motor is preferably adopted for first driving through the motor 33, the first driving motor 33 is used for driving the first conveyor belt group 32 to move, the first driving motor 33 is in communication connection with the control unit 8 to control the conveying start and stop of the first conveying unit 3, and the first conveying unit 3, the second conveying unit 4 and the third conveying unit 6 are all of similar conveyor belt structures.

The improvement is that: as shown in fig. 3, still be provided with brush mechanism 9 above first conveying unit 3, brush mechanism 9 includes brush support 91, brush motor 92 and brush 93, brush support 91 adopts type "7" type structure, the notch has all been seted up on the vertical connecting plate of brush support 91 and the transverse connection board, brush support 91 passes through notch bolted connection at the lateral part of first conveying unit 3, thereby can be according to the size of a dimension of product and the position of position real-time adjustment brush 93 on the conveyer belt, brush mechanism 9 also can direct fixed connection on box platform 1, fixed mounting has brush motor 92 on the transverse connection board on the upper portion of brush support 91, brush motor 92's output fixedly connected with brush 93, brush 93 is located the top of first conveying unit 3, the lowest end of brush 93 can just contact with the ferrite core on the conveyer belt, thereby clean the burr of the upper surface of ferrite core, brush motor 92 and first conveying unit 3 communication connection.

It is further improved in that: a material limit strip group 11 is further arranged on the upper portion of the first conveying unit 3, the material limit strip group 11 comprises a doorframe bracket 111, a limit connecting piece 112 and a limit strip rail 113, the doorframe bracket 111 comprises two vertically arranged connecting plates and a horizontally arranged connecting plate, bolt grooves are formed in the three connecting plates, the two vertical connecting plates of the doorframe bracket 111 are fixed to two sides of the first mounting frame group 31 through bolts respectively, the horizontal connecting plate on the upper portion of the doorframe bracket 111 is connected with the limit strip rail 113 through the limit connecting piece 112, the limit connecting piece 112 can be adjusted in position on the doorframe bracket 111 at proper time, so that the two limit strip rails 113 form a channel suitable for magnetic core blocks to pass through, the limit strip rail 113 is located on the upper portion of the first conveying belt group 32, the limit strip rail 113 is not in contact with the first conveying belt group 32, and the movement of the first conveying belt group 32 is not affected. The material limiting and adjusting group 11 can limit the materials transported on the first conveying unit 3, so that ordered arrangement and operation are guaranteed, and meanwhile, the phenomenon that the brush mechanism 9 displaces when working on the surface of the magnetic core block to influence the subsequent queuing process can be avoided.

The feeding end of the first conveying unit 3 is used for bearing the ferrite magnetic core block prepared in the sintering process, the discharging end of the first conveying unit 3 is used for bearing the feeding end of the second conveying unit 4, and the feeding end and the discharging end of the first conveying unit 3 work independently and do not interfere with each other; the horizontal pushing unit 5 is arranged on the front side of the second conveying unit 4, the horizontal pushing unit 5 comprises a pushing mounting support 51, rodless pushing cylinders 52 and a horizontal front push plate 53, the pushing mounting support 51 is fixedly connected to a frame body on the front side of the second conveying unit 4, two groups of rodless pushing cylinders 52 are symmetrically arranged on two side portions of a front side plate of the pushing mounting support 51, each rodless pushing cylinder 52 comprises a cylinder body portion and a telescopic portion, the cylinder body portion of each rodless pushing cylinder is fixedly mounted on the pushing mounting support 51, the telescopic portions are front telescopic ends and rear telescopic ends, the rear telescopic ends of the two groups of rodless pushing cylinders 52 are fixedly connected with the horizontal front push plate 53 together, the horizontal front push plate 53 is axially arranged along the conveying direction of the magnetic core blocks, the horizontal front push plate 53 is located on the front side portion of a conveying belt of the second conveying unit 4, and is located above the second conveying unit 4.

As shown in fig. 5, the horizontal pushing unit 5 is further improved in that: the device also comprises a step guide rail 54, a synchronous pushing connecting rod 55, a synchronous pushing support 56 and a lifting back baffle 57; the automatic lifting device is characterized in that a step guide rail 54 is arranged between rodless pushing cylinders 52 on two sides, the end part of the high-order part of the step guide rail 54 is fixedly connected to a pushing mounting bracket 51, a synchronous pushing connecting rod 55 is fixedly connected between the rear telescopic ends of the rodless pushing cylinders 52 on the two sides, one end part of two groups of synchronous pushing brackets 56 is rotatably connected to the synchronous pushing connecting rod 55, the other end part of the two groups of synchronous pushing brackets 56 is fixedly connected with a lifting rear baffle 57, the lifting rear baffle 57 is positioned above the second conveying unit 4, an interval channel formed by a horizontal front push plate 53 and the lifting rear baffle 57 above a conveying belt of the second conveying unit 4 is a queuing channel of the magnetic core blocks, and supporting legs are arranged on the lower part of the synchronous pushing brackets 56 and are in sliding connection with sliding grooves on the step guide rail 54, so that the lifting rear baffle 57 is driven to be automatically lifted.

As shown in fig. 4, a further improvement on the second conveyor unit 4 is that: a counting detection unit 10 is arranged on the second conveying unit 4 close to the horizontal pushing unit 5, an infrared sensor is preferably adopted as the counting detection unit 10, the counting detection unit 10 is in communication connection with the control unit 8 and used for counting the magnetic core blocks entering the second conveying unit 4 so as to control the start and stop of the second conveying unit 4 in time, and meanwhile, a queuing limit stop is arranged on the second conveying unit 4 close to the discharging direction of the horizontal pushing unit 5 so as to queue the magnetic core blocks in order in an interval channel formed by the horizontal front pushing plate 53 and the lifting back baffle 57; the horizontal pushing unit 5 is used for pushing away the magnetic core blocks which are arranged on the second conveying unit 4 to enter the third conveying unit 6 for waiting for stacking;

as shown in fig. 6, a third conveying unit 6 is disposed at the rear side of the second conveying unit 4, the third conveying unit 6 is disposed perpendicular to the material conveying direction of the second conveying unit 4, the third conveying unit 6 is configured to receive the magnetic core block separated from the axial conveying line, the stacking unit 7 is slidably connected to the slide rail member at the rear side of the slide rail support unit 2, so that the stacking unit 7 can perform a reciprocating sliding motion along the axial direction of the slide rail support unit 2, and the stacking unit 7 is disposed on the slide rail support unit 2 above the third conveying unit 6, specifically: the stacking and stacking unit 7 comprises a stacking and mounting frame 71, a stacking and driving mechanism 72, an outer side lifting module 73 and an inner side adsorption module 74, wherein the stacking and mounting frame 71 is of an L-shaped structure, a vertical plate of the stacking and driving mechanism is connected with a guide rail, the stacking and driving mechanism 72 is arranged on the stacking and mounting frame 71, and the stacking and mounting frame 71 is driven to make reciprocating sliding motion on the slide rail support unit 2 by adopting a connection mode that the guide rail is matched with a rack; the stack driving mechanism 72 is in communication connection with the control unit 8; an outer lifting module 73 is arranged on the stacking mounting frame 71, and the outer lifting module 73 comprises a first lifting cylinder 731 and an outer adsorption template 732; first lift cylinder 731 installs on the horizontal board of piling up mounting bracket 71, and the flexible end fixed connection outside of first lift cylinder 731 adsorbs template 732 in order to drive outside and adsorbs template 732 can elevating movement, and outside adsorbs template 732 is hollow cavity structure, has seted up the absorption hole on the bottom face, and the hole area that adsorbs the hole is less than the size of the magnetic core piece that will adsorb the transfer. An inner adsorption module 74 is disposed on the outer lifting module 72, and the inner adsorption module 74 includes a second lifting cylinder 741 and an inner magnetic attraction plate 742; the second lifting cylinders 741 are uniformly arranged on the upper portion of the outer adsorption template 732, the extending ends of the second lifting cylinders 741 are fixedly connected with the inner magnetic adsorption plate 742, the inner magnetic adsorption plate 742 is located inside the outer adsorption template 732, and the second lifting cylinders 741 drive the inner magnetic adsorption plate 742 to move up and down in the inner cavity of the outer adsorption template 732, so that adsorption and desorption of magnetic core blocks are achieved.

The working principle of the invention is as follows: under the control of a control system 8, the feeding end of the first conveying unit 3 bears magnetic core blocks sintered in the previous process, the magnetic core blocks move on the first conveying belt group 32 between the limiting strip rails 113, surface burr cleaning is carried out on the magnetic core blocks when the magnetic core blocks pass through the brush mechanism 9, when the magnetic core blocks enter the second conveying unit 4 from the first conveying unit 3, the magnetic core blocks pass through the counting detection unit 10 for counting, then the conveying belts on the second conveying unit 4 sequentially queue up in the limiting interval channel between the horizontal front push plate 53 and the lifting rear baffle 57, when the counting detection unit 10 detects that the counting reaches a preset value, the second conveying unit 4 stops working, the horizontal pushing unit 5 works, the rodless pushing cylinder 52 pushes out the rodless pushing cylinder 52 to drive the horizontal front push plate 53 to push out, the synchronous pushing connecting rod 56 and the synchronous pushing support 57 to drive the lifting rear baffle 57 to synchronously move, meanwhile, due to the existence of the step guide rail 54, the lifting rear baffle 57 automatically rises, a plurality of magnetic core blocks enter a group of the designated positions of the third conveying unit 6, the rodless pushing cylinder 52 contracts, the lifting rear baffle 57 to drive the magnetic core block pushing cylinder to move, and the magnetic core blocks to move in the first conveying unit, and the third conveying unit 6, the magnetic core block group of the magnetic core block pushing unit is a linear conveying unit, and the magnetic core block group. When a plurality of groups of magnetic core blocks are sequentially placed on the third conveying unit 6, the stacking unit 7 works, the first lifting cylinder 731 extends out to drive the outer adsorption template 732 to descend until the lower surface is attached to the magnetic core block group after stacking, the second lifting cylinder 741 extends out to drive the inner magnetic adsorption plate 742 to descend so as to adsorb and attach the magnetic core blocks to the outer adsorption template 732 through the magnetic attraction of the inner magnetic adsorption plate 742, the second lifting cylinder 731 contracts to drive the outer adsorption template 742 to ascend, the stacking driving mechanism 72 drives the whole stacking alignment unit 7 to displace to a specified stacking position, the outer adsorption template 732 descends, the inner magnetic adsorption plate 742 ascends to place the magnetic core group with the bottom adsorption fixed, and the working process of transporting and queuing the magnetic core blocks to the stacking position is completed.

While the invention has been described with reference to the preferred embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention.

Claims (10)

1. The utility model provides a pile up neatly device is queued to high ferrite core that leads which characterized in that: including box platform (1) and control unit (8), be provided with slide rail support unit (2) on box platform (1), the upper portion of box platform (1) has set gradually first conveying unit (3) and second conveying unit (4) along material direction of delivery, the front side of second conveying unit (4) is provided with horizontal propelling movement unit (5), the rear side of second conveying unit (4) is provided with third conveying unit (6), the direction of delivery of first conveying unit (3) and second conveying unit (4) is unanimous, third conveying unit (6) sets up perpendicularly relatively with the material direction of delivery of second conveying unit (4), sliding connection has the pile up the unit (7) on slide rail support unit (2), the pile up unit (7) and be located the upper portion of third conveying unit (6), first conveying unit (3), second conveying unit (4), horizontal propelling movement unit (5), third conveying unit (6) and pile up the unit (7) and be connected with control unit (8) communication respectively.

2. The high-conductivity ferrite core queuing and stacking device according to claim 1, wherein: horizontal propelling movement unit (5) are including push mounting support (51), rodless propelling movement cylinder (52), preceding push pedal of level (53), the front side symmetry of push mounting support (51) is provided with rodless propelling movement cylinder (52), push pedal (53) before the one end fixed connection level of rodless propelling movement cylinder (52), push pedal (53) are located before the level the top of second conveying unit (4).

3. The high-conductivity ferrite core queuing and stacking device as claimed in claim 2, wherein: the horizontal pushing unit (5) further comprises a step guide rail (54), a synchronous pushing connecting rod (55), a synchronous pushing support (56) and a lifting rear baffle (57); step guide rail (54) set up in both sides between no pole propelling movement cylinder (52), both sides another tip fixed connection synchronization propelling movement connecting rod (55) of no pole propelling movement cylinder (52), the one end of synchronous propelling movement support (56) with synchronous propelling movement connecting rod (55) rotate to be connected, the other end and lifting backplate (57) fixed connection, lifting backplate (57) are located the top of second conveying unit (4), the lower part of synchronous propelling movement support (56) with step guide rail (54) sliding connection.

4. The high-conductivity ferrite core queuing and stacking device according to claim 1, wherein: the stacking and stacking unit (7) comprises a stacking mounting frame (71), a stacking driving mechanism (72), an outer side lifting module (73) and an inner side adsorption module (74), the stacking mounting frame (71) is connected with the slide rail support unit (2) in a sliding mode, and the stacking driving mechanism (72) drives the stacking mounting frame (71) to move on the slide rail support unit (2) in a sliding mode; the stacking driving mechanism (72) is in communication connection with a control unit (8); an outer side lifting module (73) is arranged on the stacking mounting frame (71), and an inner side adsorption module (74) is arranged on the outer side lifting module (72).

5. The high-conductivity ferrite core queuing and stacking device according to claim 4, wherein: the outer lifting module (73) comprises a first lifting cylinder (731) and an outer adsorption template (732); the first lifting cylinder (731) is installed on the stacking installation frame (71), and the telescopic end of the first lifting cylinder (731) is fixedly connected with the outer adsorption template (732).

6. The high-conductivity ferrite core queuing and stacking device according to claim 5, wherein: the inner adsorption module (74) comprises a second lifting cylinder (741) and an inner magnetic adsorption plate (742); the second lifting cylinder (741) is arranged at the upper part of the outer adsorption template (732), the extending end of the second lifting cylinder (741) is fixedly connected with an inner magnetic adsorption plate (742), and the inner magnetic adsorption plate (742) is positioned inside the outer adsorption template (732).

7. The high-conductivity ferrite core queuing and stacking device as claimed in claim 1, wherein: still be provided with brush mechanism (9) on first conveying unit (3), brush mechanism (9) are including brush support (91), brush motor (92) and brush (93), brush support (91) are in through bolted connection the lateral part of first conveying unit (3), the upper portion fixed mounting of brush support (91) has brush motor (92), the output fixedly connected with brush (93) of brush motor (92), brush (93) are located the top of first conveying unit (3), brush motor (92) with first conveying unit (3) communication connection.

8. The high-conductivity ferrite core queuing and stacking device according to claim 1, wherein: the first conveying unit (3) comprises a first mounting frame group (31), a first conveying belt group (32) and a first driving motor (33); the first mounting frame group (31) is fixedly arranged on the box body platform (1); install first conveyer belt group (32) on first mount frame group (31), the end connection of first conveyer belt group (32) has first driving motor (33), first driving motor (33) with control unit (8) communication connection.

9. The high-conductivity ferrite core queuing and stacking device as claimed in claim 1, wherein: the automatic conveying device is characterized by further comprising a counting detection unit (10), wherein the counting detection unit (10) is arranged on the second conveying unit (4) close to the horizontal pushing unit (5), and the counting detection unit (10) is in communication connection with the control unit (8).

10. The high conductivity ferrite core queuing and stacking device according to claim 8, wherein: the upper portion of first conveying unit (3) still is provided with spacing strip group of material (11), spacing strip group of material (11) is including door frame support (111), spacing connecting piece (112) and spacing strip rail (113), door frame support (111) bolted connection be in the both sides of first mount frame group (31), spacing strip rail (113) are connected through spacing connecting piece (112) in the upper portion of door frame support (111), spacing strip rail (113) are located the upper portion of first conveyer belt group (32).

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