CN112317246B - Shielding inductance glue filling device for processing electronic components - Google Patents

Abstract

The invention relates to a cleaning device, in particular to a shielding inductor glue filling device for processing electronic components. The invention provides a glue pouring device for a shielding inductor for processing an electronic component, which adopts automatic operation, can uniformly coat glue on the surface of the shielding inductor and can scrape redundant glue on the surface of the shielding inductor. The utility model provides such electronic components processing is with shielding inductance encapsulating device includes: the top of the base is provided with three supporting plates; the workbench is arranged among the tops of the three supporting plates; the collecting box is arranged on one side of the top of the base; the top of the workbench is provided with a feeding mechanism; the glue pouring mechanism is arranged at the top of the workbench and matched with the feeding mechanism. The pinch roller rolls on the surface of the shielding inductor to uniformly paint colloid on the surface of the shielding inductor, and the wiping block moves on the surface of the shielding inductor to scrape off redundant colloid on the surface of the shielding inductor.

Description

Shielding inductance glue filling device for processing electronic components

Technical Field

The invention relates to a cleaning device, in particular to a shielding inductor glue filling device for processing electronic components.

Background

Inductors, also known as chokes, reactors, and dynamic reactors, are components that can convert electrical energy into magnetic energy for storage. The inductor is similar in structure to a transformer, but has only one winding. The inductor has an inductance that resists the change in current. If the inductor is in a state where no current is passing, it will try to block the current passing when the circuit is on; if the inductor is in a current passing state, the inductor will try to keep the current unchanged when the circuit is opened.

The shielding patch inductor has different functions with the common patch inductor, the common patch inductor is not provided with shielding in a circuit, the shielding patch inductor can shield instability of current in some circuits, the shielding patch inductor plays a good role in blocking, in order to reduce electromagnetic interference of the inductor to the outside, a lead, a loop and a coil are protected from being influenced by an external magnetic field, the interference effect of an electromagnetic field generated by the circuit on other elements is weakened, a layer of colloid is required to be coated to protect the elements when the shielding patch inductor is produced, at present, manual operation is mostly adopted, and the use safety of the shielding patch inductor is difficult to ensure due to the fact that the coating is not uniform.

Therefore, there is a need to develop a glue filling device for electronic component processing, which can automatically apply glue on the surface of a shielding inductor and can scrape off the excess glue on the surface of the shielding inductor.

Disclosure of Invention

In order to overcome the interference effect that the electromagnetic field that the circuit produced other components, need scribble a layer colloid protection components and parts when producing shielding paster inductance, at present mostly adopt manual work, because scribble the shortcoming that uneven is difficult to guarantee shielding paster inductance safety in utilization, the technical problem is: the shielding inductance glue filling device for processing the electronic component is automatically operated, can uniformly paint the surface of the shielding inductance by using the glue and can scrape the redundant glue on the surface of the shielding inductance.

The technical scheme is as follows: the utility model provides an electronic components processing is with shielding inductance encapsulating device, includes: the top of the base is provided with three supporting plates; the workbench is arranged among the tops of the three supporting plates; the collecting box is arranged on one side of the top of the base; the top of the workbench is provided with a feeding mechanism; the glue pouring mechanism is arranged at the top of the workbench and matched with the feeding mechanism; the resetting mechanism is arranged on one side of the top of the workbench; and the return mechanism is arranged on one side, close to the return mechanism, of the top of the workbench.

Further, feeding mechanism includes: the top of the workbench is symmetrically provided with two fixed blocks; the guide rail is arranged between the two fixed blocks on the same side; the sliding block is arranged on one side of the top of the workbench in a sliding manner; the sliding block is provided with a pressing column in a sliding manner; the pressing block is arranged between the two pressing columns; the shifting blocks are uniformly arranged on the pressing block at intervals; the first elastic piece is sleeved on the compression column; the first rotating shaft is rotatably arranged between the two sliding blocks at the top of the workbench; the upper end of the first rotating shaft is provided with a cam; the cam is eccentrically and rotatably provided with a shifting column; the middle part of the top of the pressing block is provided with a shifting lever, and the shifting lever is matched with the shifting column; the second rotating shaft is rotatably arranged on one side of the top of the workbench; the first belt transmission component is arranged between the second rotating shaft and the first rotating shaft; the top of the second rotating shaft is provided with a first one-way bearing; the first circular gear is arranged on the outer ring of the first one-way bearing; the third rotating shaft is rotatably arranged at the position, close to the second rotating shaft, of the top of the workbench; the lower side of the third rotating shaft is provided with a first gear lack which is meshed with the first circular gear; the third rotating shaft is provided with a second circular gear above the first gear-lacking gear; the bearing block is arranged at the position, close to the second rotating shaft, of the top of the workbench; the bearing block is provided with a fourth rotating shaft; the lower end of the fourth rotating shaft is provided with a second gear which is meshed with the second circular gear; the bearing block is provided with a fifth rotating shaft; first bevel gears are arranged between the fifth rotating shaft and the fourth rotating shaft, and the two first bevel gears are meshed with each other; the servo motor is arranged at the position, close to the bearing block, of the top of the workbench, and an output shaft of the servo motor is connected with the fifth rotating shaft through a coupler; and a second elastic piece is arranged between the sliding block and the inner wall close to the workbench.

Further, glue-pouring mechanism includes: the first sliding rail is arranged on one side, away from the servo motor, of the top of the workbench; the sliding plate is arranged on the first sliding rail in a sliding manner; the connecting plate is arranged on the lower side of the sliding plate; the cover block is arranged on one side, close to the servo motor, of the connecting plate; the fixing plate is arranged on one side, close to the servo motor, of the covering block; the sliding plate is symmetrically provided with bearing seats at one side close to the connecting plate; the first guide pillar is arranged between the bearing seat close to the collecting box and the fixing plate; the first screw rod is arranged between the fixing plate and the bearing block far away from the collecting box; four first ejector blocks are arranged on one side, close to the first slide rail, of the fixing plate; the top of the workbench is provided with an L-shaped plate above the collection box; the L-shaped plate is provided with a rack on one side close to the covering block; the guide sleeve is arranged on the first guide pillar in a sliding manner; the first screw rod is connected with the nut sleeve in a threaded manner; the box is arranged between the nut sleeve and the guide sleeve; the box is internally provided with a first nut block in a sliding manner; the first nut block is in threaded connection with a first screw rod; the upper end of the second screw rod is provided with a second one-way bearing; the box is provided with a connecting block at one side close to the fixed plate; the bottom of the connecting block is provided with a square box; the first sliding block is arranged in the square box in a sliding manner; the third elastic piece is symmetrically arranged between the top of the first sliding block and the inner wall of the square box; the bottom of the first sliding block is provided with a wiping block; the second sliding block is symmetrically arranged in the first sliding block in a sliding manner; the two second sliding blocks are respectively and rotatably provided with a second rotating shaft at the back side; the rubber sliding sleeves are symmetrically arranged on the sixth rotating shaft and matched with the linear grooves in the side walls of the square boxes; the blades are arranged on the sides, back to the two sixth rotating shafts, of the two sixth rotating shafts and matched with the first ejector block; the end part of the sixth rotating shaft is provided with a circular ring; the side of the box, which is far away from the connecting block, is provided with a T-shaped block; the second guide posts are symmetrically and slidably arranged on the T-shaped block; the pressing wheel is rotatably arranged between the lower ends of the two second guide columns; the second guide pillar is sleeved with a second elastic part; the fixing plate is provided with a first nut block on one side close to the servo motor; the upper end of the third rotating shaft is provided with a third screw rod, and the third screw rod is in threaded connection with the second nut block; the bearing rod is arranged at the position, close to the servo motor, of the top of the workbench; the first sliding seat is arranged on one side, close to the servo motor, of the top of the workbench; the first sliding seat is provided with a first guide pillar in a sliding manner; the third guide pillar is provided with an N-shaped block at one end close to the bearing rod; a fifth elastic piece is arranged between the N-shaped block and the first sliding seat; the bearing rod is provided with a seventh rotating shaft; a second belt transmission assembly is arranged among the seventh rotating shaft, the first screw rod and the N-shaped block; the eighth rotating shaft is rotatably arranged at the top of the workbench between the bearing rod and the bearing block; a fourth circular gear is arranged on the eighth rotating shaft and meshed with the second missing gear; a second bevel gear is arranged between the eighth rotating shaft and the seventh rotating shaft, and the two second bevel gears are meshed with each other; a third circular gear is arranged on the outer ring of the second one-way bearing and meshed with the rack; the opposite sides of the two sixth rotating shafts are sleeved with the sixth elastic pieces; and a seventh elastic part is arranged between the inner walls of the two opposite sides of the two second sliding blocks, which are close to the first sliding blocks.

Further, the reset mechanism includes: the sliding plate is symmetrically provided with a second sliding rail at one side close to the servo motor; the second sliding rail is provided with an N-shaped ejector rod in a sliding mode, and the N-shaped ejector rod is matched with the blade; the second sliding seat is symmetrically and slidably arranged on one side of the top of the sliding plate, which is far away from the servo motor; the fourth guide pillar is arranged on the second sliding seat and is in sliding fit with the similar N-shaped ejector rod; the eighth elastic piece is sleeved on the fourth guide pillar; the second ejector block is slidably provided with two second ejector blocks, and the second ejector blocks are matched with the similar N-shaped ejector rods; two ninth elastic pieces are arranged between the second top block and the inner wall of the second sliding rail close to the second top block; the handle is arranged above the fourth guide pillar on one side of the N-shaped ejector rod close to the second sliding seat; the third sliding blocks are arranged on the opposite sides of the two second sliding rails in a sliding manner; the third sliding block is provided with a guide rod which is matched with the circular ring; and a tenth elastic piece is arranged between the third sliding block and the inner wall close to the second sliding rail.

Further, the return mechanism includes: the fixing sleeve is arranged above the T-shaped block of the box; the sliding rod is arranged on the fixed sleeve in a sliding manner; the lower end of the sliding rod is provided with a first convex column; the slide bar is sleeved with the eleventh elastic piece; the top of the connecting plate is symmetrically provided with side plates; the middle part of the side plate is slidably provided with a special-shaped loop bar which is slidably matched with the similar N-shaped ejector rod; the hinge assembly is arranged between the tops of the two special-shaped loop bars; the hinge assembly is provided with an elastic inserted bar which is matched with the sliding bar; the elastic inserted rod is provided with a second convex column; the wheels are arranged on the upper sides of the side plates and matched with the second convex columns; the side plate is provided with a guide block below the wheel, and the guide block is matched with the first convex column; and a twelfth elastic piece is arranged between the hinge assembly and the elastic inserted rod.

Further, still include: the rubber block is arranged on the poking block.

Further, still include: the brush board is arranged at the top of the connecting plate and matched with the pressing wheel.

Further, still include: and the middle part of the box is provided with a sealing strip.

The beneficial effects are that: 1. the staff will need the even interval of the clear shielding inductance of encapsulating to put between two guide rails, start servo motor, drive then and cover the piece and move down and shield the inductance cooperation below, but second belt drive assembly keep device steady operation under the effect of fifth elastic component.

2. When the nut sleeve, the guide sleeve and the mounting part thereof move between the first screw rod and the first guide pillar towards the direction of the servo motor, the third circular gear and the rack are meshed to drive the second screw rod to rotate under the action of the second one-way bearing, and then the first nut block is driven to move downwards to extrude the colloid in the box to flow out of the discharge port to the surface of the shielding inductor.

3. The pinch roller rolls on the surface of the shielding inductor to uniformly paint colloid on the surface of the shielding inductor, and the wiping block moves on the surface of the shielding inductor to scrape off redundant colloid on the surface of the shielding inductor.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic view of a first partial body structure of the feeding mechanism of the present invention.

Fig. 3 is a schematic structural view of a second partial body of the feeding mechanism of the present invention.

Fig. 4 is a schematic perspective view of the glue filling mechanism of the present invention.

Fig. 5 is a schematic view of a first partial body structure of the glue filling mechanism of the present invention.

Fig. 6 is an exploded perspective view of the glue pouring mechanism of the present invention.

Fig. 7 is a schematic cross-sectional view of a three-dimensional structure of the glue filling mechanism of the present invention.

Fig. 8 is a schematic view of a second partial structure of the glue filling mechanism of the present invention.

Fig. 9 is a schematic view of a first partial body structure of the reset mechanism of the present invention.

Fig. 10 is a schematic view of a second partial body structure of the reset mechanism of the present invention.

Fig. 11 is a schematic perspective view of the return mechanism of the present invention.

Part names and serial numbers in the figure: 1 base, 2 supporting plate, 3 working table, 31 collecting box, 4 feeding mechanism, 41 fixing block, 42 guide rail, 43 sliding block, 44 pressing column, 45 pressing block, 46 shifting block, 47 first elastic piece, 48 first rotating shaft, 49 cam, 410 shifting column, 411 shifting rod, 412 second rotating shaft, 413 first belt transmission component, 414 first one-way bearing, 415 first circular gear, 416 third rotating shaft, 417 first gear lacking, 418 second circular gear, 419 bearing block, 420 fourth rotating shaft, 421 second gear lacking, 422 fifth rotating shaft, 423 first bevel gear, 424 servo motor, 425 second elastic piece, 5 glue pouring mechanism, 51 first sliding rail, 52 sliding plate, 53 connecting plate, 54 covering block, 55 fixing plate, 56 bearing seat, 57 first guide column, 58 first lead screw, 59 a first top block, 510L-shaped plate, 511 rack, 512 guide sleeve, 513 nut sleeve, 514 box, 515 a first nut block, 516 a second lead screw, 517 a second one-way bearing, 518 connecting block, 519 square box, 520 a first slider, 521 a third elastic element, 522 wiping block, 523 a second slider, 524 a sixth rotating shaft, 525 rubber sliding sleeve, 526 blade, 527 ring, 528T-shaped block, 529 a second guide pillar, 530 pinch roller, 531 a fourth elastic element, 532 a second nut block, 533 a third lead screw, 534 bearing rod, 535 a first sliding seat, 536 a third guide pillar, 537N-shaped block, 538 a fifth elastic element, 539 a seventh rotating shaft, 540 a second belt transmission component, 541 an eighth rotating shaft, 542 a fourth circular gear, 543 gear, 544 a third circular gear, 545 a sixth elastic element, 546 a seventh elastic element, the mechanical hand comprises a 6 reset mechanism, a 61 second sliding rail, a 62N-shaped ejector rod, a 63 second sliding seat, a 64 fourth guide post, a 65 eighth elastic part, a 66 second ejector block, a 67 ninth elastic part, a 68 handle, a 69 third sliding block, a 610 guide rod, a 611 tenth elastic part, a 7 reset mechanism, a 71 fixed sleeve, a 72 sliding rod, a 73 first convex column, a 74 eleventh elastic part, a 75 side plate, a 76 special-shaped sleeve rod, a 77 hinged component, a 78 elastic inserted rod, a 79 second convex column, a 710 wheel, a 711 guide block, a 712 twelfth elastic part, an 8 rubber block, a 9 brush plate and a 10 sealing strip.

Detailed Description

The preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Example 1

As shown in fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10 and fig. 11, a shielding inductance glue-pouring device for processing electronic components comprises a base 1, a supporting plate 2, a workbench 3, a collecting box 31, a feeding mechanism 4, a glue-pouring mechanism 5, a resetting mechanism 6 and a resetting mechanism 7, wherein the supporting plate 2 is arranged at the top of the base 1 in a three-dimensional manner, the workbench 3 is arranged between the tops of the three supporting plates 2, the collecting box 31 is arranged on the rear side of the top of the base 1, the feeding mechanism 4 is arranged at the top of the workbench 3, the glue-pouring mechanism 5 is matched with the feeding mechanism 4, the resetting mechanism 6 is arranged on the right side of the top of the workbench 3, and the resetting mechanism 7 is arranged on the right side of the top of the workbench 3.

The feeding mechanism 4 comprises fixed blocks 41, guide rails 42, sliding blocks 43, press columns 44, press blocks 45, a toggle block 46, a first elastic part 47, a first rotating shaft 48, a cam 49, a toggle column 410, a toggle rod 411, a second rotating shaft 412, a first belt transmission component 413, a first one-way bearing 414, a first circular gear 415, a third rotating shaft 416, a first missing gear 417, a second circular gear 418, a bearing block 419, a fourth rotating shaft 420, a second missing gear 421, a fifth rotating shaft 422, a first bevel gear 423, a servo motor 424 and a second elastic part 425, wherein the left side and the right side of the top of the workbench 3 are symmetrically provided with the two fixed blocks 41, the guide rails 42 are symmetrically arranged between the two fixed blocks 41 on the same side, the left side of the top of the workbench 3 is slidably provided with the two sliding blocks 43, the press columns 44 are slidably provided with the slide blocks 44, the press blocks 45 are provided with the press blocks 46 at even intervals, a first elastic element 47 is sleeved on the compression leg 44, a first rotating shaft 48 is rotatably arranged on the top of the workbench 3 between the two sliding blocks 43, a cam 49 is arranged at the upper end of the first rotating shaft 48, a shifting column 410 is eccentrically and rotatably arranged on the cam 49, a shifting lever 411 is arranged in the middle of the top of the compression block 45, the shifting lever 411 is matched with the shifting column 410, a second rotating shaft 412 is rotatably arranged on the left side of the top of the workbench 3, a first belt transmission assembly 413 is arranged between the second rotating shaft 412 and the first rotating shaft 48, a first one-way bearing 414 is arranged on the top of the second rotating shaft 412, a first circular gear 415 is arranged on the outer ring of the first one-way bearing 414, a third rotating shaft 416 is rotatably arranged on the top of the workbench 3 close to the second rotating shaft 412, a first gear segment 417 is arranged on the lower side of the third rotating shaft 416, the first gear segment 417 is engaged with the first circular gear 415, and the second circular gear 418 is arranged on the third rotating shaft 416 above the first gear segment 417, the top of the workbench 3 is provided with a bearing block 419 near the second rotating shaft 412, the bearing block 419 is provided with a fourth rotating shaft 420, the lower end of the fourth rotating shaft 420 is provided with a second lacking gear 421, the second lacking gear 421 is engaged with a second circular gear 418, the bearing block 419 is provided with a fifth rotating shaft 422, a first bevel gear 423 is arranged between the fifth rotating shaft 422 and the fourth rotating shaft 420, the two first bevel gears 423 are engaged with each other, the top of the workbench 3 is provided with a servo motor 424 near the bearing block 419, an output shaft of the servo motor 424 is connected with the fifth rotating shaft 422 through a coupling, and a second elastic member 425 is arranged between the sliding block 43 and the inner wall of the workbench 3 near the same.

The glue filling mechanism 5 comprises a first slide rail 51, a slide plate 52, a connecting plate 53, a covering block 54, a fixing plate 55, a bearing seat 56, a first guide post 57, a first lead screw 58, a first top block 59, an L-shaped plate 510, a rack 511, a guide sleeve 512, a nut sleeve 513, a box 514, a first nut block 515, a second lead screw 516, a second one-way bearing 517, a connecting block 518, a square box 519, a first slider 520, a third elastic element 521, a wiping block 522, a second slider 523, a sixth rotating shaft 524, a rubber sliding sleeve 525, a blade 526, a ring 527, a T-shaped block 528, a second guide post 529, a pressing wheel 530, a fourth elastic element 531, a second nut block 532, a third lead screw 533, a bearing rod 534, a first sliding seat 535, a third guide post 536, an N-shaped block 537, a fifth elastic element 538, a seventh rotating shaft 539, a second belt transmission assembly 540, an eighth rotating shaft 541, a fourth circular gear 542, a third circular gear 543, a third circular gear 544, A sixth elastic element 545 and a seventh elastic element 546, a first sliding rail 51 is arranged on the right side of the top of the workbench 3, a sliding plate 52 is slidably arranged on the first sliding rail 51, a connecting plate 53 is arranged on the lower side of the sliding plate 52, a cover block 54 is arranged on the left side of the connecting plate 53, a fixing plate 55 is arranged on the left side of the cover block 54, bearing seats 56 are symmetrically arranged on the front and back of the left side of the sliding plate 52, a first guide post 57 is arranged between the rear bearing seat 56 and the fixing plate 55, a first lead screw 58 is arranged between the front bearing seat 56 and the fixing plate 55, four first top blocks 59 are arranged on the right side of the fixing plate 55, an L-shaped plate 510 is arranged on the top of the workbench 3 above the collecting box 31, a rack 511 is arranged on the front side of the L-shaped plate 510, a guide sleeve 512 is slidably arranged on the first guide post 57, a nut sleeve 513 is threadedly connected on the first lead screw 58, a box 514 is arranged between the nut sleeve 513 and the guide sleeve 512, a first nut 515 is slidably arranged in the box 514, a second screw 516 is connected with the first nut block 515 through a thread, a second one-way bearing 517 is arranged at the upper end of the second screw 516, a connecting block 518 is arranged at the left side of the box 514, a square box 519 is arranged at the bottom of the connecting block 518, a first slide block 520 is arranged in the square box 519 in a sliding manner, third elastic parts 521 are symmetrically arranged between the top of the first slide block 520 and the inner wall of the square box 519 in a front-back manner, wiping blocks 522 are arranged at the bottom of the first slide block 520, second slide blocks 523 are symmetrically arranged in the first slide block 520 in a front-back manner, sixth rotating shafts 524 are rotatably arranged on opposite sides of the two second slide blocks 523, rubber sliding sleeves 525 are symmetrically arranged on the sixth rotating shafts 524, the rubber sliding sleeves 525 are matched with a straight groove on the side wall of the square box 519, blades 526 are arranged on opposite sides of the two sixth rotating shafts 524, the blades 526 are matched with the first top block 59, a circular ring 527 is arranged at the end part of the sixth rotating shafts 524, a T-shaped block 528 is arranged on the right side of the box 514, the T-shaped block 528 is provided with second guide posts 529 which are symmetrically and slidably arranged back and forth, a press wheel 530 is rotatably arranged between the lower ends of the two second guide posts 529, a fourth elastic member 531 is sleeved on the second guide posts 529, the left side of the fixing plate 55 is provided with a second nut block 532, the upper end of the third rotating shaft 416 is provided with a third lead screw 533, the third lead screw 533 is in threaded connection with the second nut block 532, the top of the workbench 3 is provided with a bearing rod 534 close to the servo motor 424, the left side of the top of the workbench 3 is provided with a first sliding seat 535, the first sliding seat 535 is slidably provided with a third guide post 536, the rear end of the third guide post 536 is provided with an N-shaped block 537, a fifth elastic member 538 is arranged between the N-shaped block 537 and the first sliding seat 535, the bearing rod 534 is provided with a seventh rotating shaft 539, a second belt transmission assembly 540 is arranged between the seventh rotating shaft 539 and the first lead screw 58 and the N-shaped block 537, the top of the workbench 3 is rotatably provided with an eighth rotating shaft 541 between the bearing rod 534 and the bearing block 419, a fourth circular gear 542 is arranged on the eighth rotating shaft 541, the fourth circular gear 542 is meshed with the second missing gear 421, a second circular gear 543 is arranged between the eighth rotating shaft 541 and the seventh rotating shaft 539, the two second circular gears 543 are meshed with each other, a third circular gear 544 is arranged on the outer ring of the second one-way bearing 517, the third circular gear 544 is meshed with the rack 511, a sixth elastic member 545 is sleeved on one opposite side of each of the two sixth rotating shafts 524, the sixth elastic member 545 is connected with the second slider 523, and a seventh elastic member 546 is arranged between one opposite side of each of the two second sliders 523 and the inner wall of the first slider 520.

The resetting mechanism 6 comprises a second slide rail 61, an N-shaped ejector rod 62, a second slide seat 63, a fourth guide post 64, an eighth elastic part 65, a second ejector block 66, a ninth elastic part 67, a handle 68, a third slide block 69, a guide rod 610 and a tenth elastic part 611, the second slide rail 61 is symmetrically arranged at the front and back of the left side of the slide plate 52, the N-shaped ejector rod 62 is slidably arranged on the second slide rail 61, the N-shaped ejector rod 62 is matched with the blade 526, the second slide seat 63 is symmetrically slidably arranged at the front and back of the right side of the top of the slide plate 52, the fourth guide post 64 is arranged on the second slide seat 63, the fourth guide post 64 is slidably matched with the adjacent N-shaped ejector rod 62, the eighth elastic part 65 is sleeved on the fourth guide post 64, the two second ejector blocks 66 are slidably arranged on the second slide rail 61, the second ejector block 66 is matched with the adjacent N-shaped ejector rod 62, two ninth elastic parts 67 are arranged between the second ejector block 66 and the second slide rail 61, a handle 68 is arranged on the right side of the N-shaped top rod 62 above the fourth guide post 64, a third sliding block 69 is arranged on one side of each of the two second sliding rails 61 facing away from the other side, a guide rod 610 is arranged on the third sliding block 69, the guide rod 610 is matched with a circular ring 527, and a tenth elastic element 611 is arranged between the third sliding block 69 and the inner wall of the second sliding rail 61 close to the inner wall.

The return mechanism 7 comprises a fixed sleeve 71, a sliding rod 72, a first convex column 73, an eleventh elastic part 74, a side plate 75, a special-shaped loop bar 76, a hinge assembly 77, an elastic inserted bar 78, a second convex column 79, wheels 710, a guide block 711 and a twelfth elastic part 712, the box 514 is provided with the fixed sleeve 71 above a T-shaped block 528, the fixed sleeve 71 is provided with the sliding rod 72 in a sliding manner, the lower end of the sliding rod 72 is provided with the first convex column 73, the sliding rod 72 is sleeved with the eleventh elastic part 74, the top of the connecting plate 53 is symmetrically provided with the side plate 75 in a front-back manner, the middle part of the side plate 75 is provided with the special-shaped loop bar 76 in a sliding manner, the special-shaped loop bar 76 is matched with a similar N-shaped top bar 62 in a sliding manner, the hinge assembly 77 is arranged between the tops of the two special-shaped loop bars 76, the hinge assembly 77 is provided with the elastic inserted bar 78, the elastic inserted bar 78 is matched with the sliding rod 72, the second convex column 79 is arranged on the elastic inserted bar 78, the upper side of the side plate 75 is provided with the wheels 710, the wheel 710 is matched with the second convex column 79, the side plate 75 is provided with a guide block 711 below the wheel 710, the guide block 711 is matched with the first convex column 73, and a twelfth elastic piece 712 is arranged between the hinge assembly 77 and the elastic inserted rod 78.

When a worker needs to perform glue filling and cleaning on the shielded inductors, the worker places the shielded inductors needing to be filled and cleaned between the two guide rails 42 at uniform intervals, wherein one row of the shielded inductors are positioned below the covering block 54, the worker starts the servo motor 424, the output shaft of the servo motor 424 rotates to drive the fifth rotating shaft 422 to rotate, the fifth rotating shaft 422 rotates to drive the second rotating shaft 412 to rotate through the first bevel gear 423, the second rotating shaft 412 rotates to drive the second missing gear 421 to rotate, the second missing gear 421 rotates to drive the second circular gear 418 to rotate when being meshed with the second circular gear 418, the second circular gear 418 rotates to drive the third screw rod 533 to rotate, the third screw rod 533 rotates to drive the second screw block 532 to move below the third screw rod 533, and then drives the mounting component between the second screw block 532 and the sliding plate 52 to move downwards between the third screw rod 533 and the first sliding rail 51, and then drives the covering block 54 to move downwards to be matched with the lower shielded inductors, the second belt transmission assembly 540 can keep the stable operation of the device under the action of the fifth elastic element 538, the second missing gear 421 rotates and is meshed with the fourth circular gear 542 to drive the eighth rotating shaft 541 to rotate, the eighth rotating shaft 541 rotates and drives the seventh rotating shaft 539 to rotate through the second bevel gear 543, the seventh rotating shaft 539 rotates and drives the first lead screw 58 to rotate through the second belt transmission assembly 540, the first lead screw 58 rotates and drives the nut sleeve 513 and the installation part thereof to move on the first lead screw 58, the guide sleeve 512 and the first guide post 57 are in sliding fit to enhance the stability of the device, when the nut sleeve 513, the guide sleeve 512 and the installation part thereof move between the first lead screw 58 and the first guide post 57 towards the direction of the servo motor 424, the third circular gear is meshed with the rack 511 to drive the second lead screw 516 to rotate under the action of the second one-way bearing 517, the second lead screw 516 rotates and drives the first nut block 515 to move downwards, the first nut block 515 moves downwards to squeeze the colloid 544 in the box 514 to flow out from the discharge hole to the surface of the shielding inductor, the pressing wheel 530 rolls on the surface of the shielded inductor to uniformly coat colloid on the surface of the shielded inductor, when the nut sleeve 513 moves to a side close to the servo motor 424, the blade 526 is in contact with the first top block 59 and is pressed to drive the sixth rotating shaft 524 to rotate, the sixth rotating shaft 524 rotates to drive the rubber sliding sleeve 525 to rotate around the sixth rotating shaft 524, the sixth elastic member 545 deforms, the seventh elastic member 546 is initially in a stretching state, the third elastic member 521 is initially in a compressing state, when the blade 526 rotates to a vertical direction around the sixth rotating shaft 524, the seventh elastic member 546 resets to drive the two second sliding blocks 523 to move towards the inside of the first sliding block 520, the third elastic member 521 resets to drive the wiping block 522 to move downwards to be attached to the surface of the shielded inductor, and a worker controls the servo motor 424 to rotate reversely, so as to drive the nut sleeve 513, the guide sleeve 512 and the installation components thereof to move towards the first sliding rail 51 between the first lead screw 58 and the first guide post 57, the blade 526 is separated from the first top block 59, the sixth elastic element 545 resets to drive the rubber sliding sleeve 525 to reset and clamp into the linear groove on the side wall of the square box 519, the third circular gear 544 does not rotate under the action of the second one-way bearing 517, the wiping block 522 moves on the surface of the shielded inductor to scrape off the redundant colloid on the surface of the shielded inductor, the third elastic element 521 and the fourth elastic element 531 can enhance the stability of the device, when the nut sleeve 513 moves to be close to one side of the first sliding rail 51, the blade 526 is in contact with the N-shaped top rod 62 and is pressed to drive the sixth rotating shaft 524 to rotate, the sixth rotating shaft 524 rotates to drive the rubber sliding sleeve 525 and the circular ring 527 to rotate around the sixth rotating shaft 524, the sixth elastic element 545 deforms, the circular ring 527 rotates to cooperate with the guide rod 610 and moves along the guide rod 610 to drive the rubber sliding sleeve 525 to move to separate from the linear groove on the side wall of the square box 519, and the third sliding block 69 cooperates with the second sliding rail 61 in a sliding manner under the action of the tenth elastic element 611 to reduce the interference on the circular ring 527 moving along the guide rod 610, the blade 526 and the N-shaped top rod 62 drive the N-shaped top rod 62 to move on the fourth guide post 64 in a contact extrusion state, the eighth elastic element 65 is compressed, the ninth elastic element 67 is initially in a compressed state, when the concave side of the N-shaped top rod 62 is matched with the second slide rail 61, the ninth elastic element 67 resets to drive the second top block 66 to move in the second slide rail 61, the second top block 66 moves in the second slide rail 61 to contact and extrude the second top block 66 to drive the N-shaped top rod 62 to move in the second slide rail 61 and separate from the blade 526, the sixth elastic element 545 resets to drive the moving blade 526 to rotate and reset around the sixth rotating shaft 524, meanwhile, the square box 519 moves to drive the fixed sleeve 71 and the installation part thereof to move, the first convex column 73 is contacted and extruded with the guide block 711 to drive the first convex column 73 to move along the lower surface of the guide block 711, the first convex column 73 moves along the lower surface of the guide block 711 to drive the sliding rod 72 to move downwards in the fixed sleeve 71, the eleventh elastic element 74 stretches, the first convex column 73 continues to move and is separated from the guide block 711, meanwhile, the second third screw rod 533 rotates and drives the first third screw rod 417 to rotate, the first third screw rod 417 rotates and is meshed with the first circular gear 415, the first one-way bearing 414 drives the second rotating shaft 412 to rotate, the second rotating shaft 412 rotates and drives the first rotating shaft 48 to rotate through the first belt transmission component 413, the first rotating shaft 48 rotates and drives the cam 49 to rotate, the cam 49 rotates and contacts the extrusion pressing block 45 to drive the shifting block 46 to move and match with the square hole of the shielding inductor, the first elastic element 47 stretches, meanwhile, the cam 49 rotates and drives the shifting column 410 to rotate around the first rotating shaft 48 to contact the extrusion driving rod 411 to drive the pressing block 45 to move, the pressing block 45 moves and drives the shifting block 46 to move, the shifting block 46 moves and contacts and extrudes the inner wall of the square hole of the shielding inductor to drive the shielding inductor to move by one unit, the shielding inductor in a row moves into the covering block 54, the pressing block 45 moves to contact and extrude the sliding block 43 through the pressing column 44 to drive the sliding block 43 to move, the second elastic piece 425 compresses, the cam 49 rotates to be separated from the pressing block 45, the shifting column 410 is driven to rotate around the first rotating shaft 48 to be separated from the shifting rod 411, the first elastic piece 47 resets to drive the shifting block 46 to move to be separated from the shielding inductor square hole, and the second elastic piece 425 resets to drive the sliding block 43 and the mounting component thereof to reset. The worker controls the servo motor 424 to rotate positively, then the second gear 421 rotates to be meshed with the second circular gear 418 to realize downward movement of the covering block 54 to be matched with the lower shielding inductor, then the second gear 421 rotates to be meshed with the fourth circular gear 542 to realize movement of the first convex column 73 along the upper surface of the guide block 711, the first convex column 73 moves along the upper surface of the guide block 711 to drive the sliding rod 72 to move upward in the fixed sleeve 71, the eleventh elastic part 74 is compressed, the sliding rod 72 contacts and extrudes the elastic inserted rod 78 to drive the elastic inserted rod 78 to move, the elastic inserted rod 78 moves to drive the two special-shaped sleeved rods 76 to move oppositely through the hinge assembly 77, the twelfth elastic part 712 deforms, the special-shaped sleeved rod 76 moves to contact and extrude the N-shaped top rod 62 to drive the N-shaped top rod 62 to move and reset in the second sliding rail 61, the eighth elastic part 65 resets to drive the N-shaped top rod 62 to move and reset on the fourth guide column 64, the ninth elastic member 67 is compressed, the elastic insertion rod 78 continues to move to contact with the wheel 710 and is extruded to drive the elastic insertion rod 78 to move upwards along the surface of the wheel 710 to be separated from the sliding rod 72, the twelfth elastic member 712 resets to drive the special-shaped loop bar 76 to move on the side plate 75 to reset, the processed shielding inductor falls into the collection box 31, and the shielding inductor glue pouring cleaning can be realized by repeating the operations.

Example 2

As shown in fig. 3, 4 and 6, in embodiment 1, the shielded inductor glue filling device for processing an electronic component further includes a rubber block 8, and the rubber block 8 is disposed on the toggle block 46.

When the poking block 46 moves to contact and extrude the inner wall of the square hole of the shielding inductor, the rubber block 8 can buffer the impact between the device and the component.

The cleaning device also comprises a brush plate 9, the top of the sliding plate 52 is provided with the brush plate 9, and the brush plate 9 is matched with the pressing wheel 530.

The wiping block 522 moves on the surface of the shielding inductor to scrape the redundant colloid on the surface of the shielding inductor onto the brush plate 9, and then the colloid is recycled.

The sealing strip 10 is further included, and the sealing strip 10 is arranged in the middle of the box 514.

The sealing tape 10 can improve the sealing performance of the box 514.

The technical principle of the embodiment of the present invention is described above in conjunction with the specific embodiments. The description is only intended to explain the principles of embodiments of the invention and should not be taken in any way as limiting the scope of the embodiments of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without inventive step, and these embodiments will fall within the scope of the present invention.

Claims (7)

1. The utility model provides an electronic components processing is with shielding inductance encapsulating device which characterized in that includes:

three supporting plates (2) are arranged at the top of the base (1);

the workbench (3) is arranged among the tops of the three supporting plates (2);

the collecting box (31) is arranged on one side of the top of the base (1);

the feeding mechanism (4) is arranged at the top of the workbench (3);

the glue pouring mechanism (5), the top of the workbench (3) is provided with the glue pouring mechanism (5), and the glue pouring mechanism (5) is matched with the feeding mechanism (4);

a reset mechanism (6), wherein the reset mechanism (6) is arranged on one side of the top of the workbench (3);

the return mechanism (7) is arranged on one side, close to the return mechanism (6), of the top of the workbench (3);

the feeding mechanism (4) comprises:

the top of the workbench (3) is symmetrically provided with two fixed blocks (41);

the guide rail (42) is arranged between the two fixing blocks (41) on the same side;

the sliding block (43), one side of the top of the workbench (3) is provided with two sliding blocks (43) in a sliding way;

a compression column (44), wherein the compression column (44) is arranged on the sliding block (43) in a sliding way;

a pressing block (45), wherein the pressing block (45) is arranged between the two pressing columns (44);

the shifting blocks (46) are uniformly arranged on the pressing block (45) at intervals;

the first elastic piece (47) is sleeved on the compression column (44);

the first rotating shaft (48) is rotatably arranged between the two sliding blocks (43) at the top of the workbench (3);

the cam (49) is arranged at the upper end of the first rotating shaft (48);

the shifting column (410) is eccentrically and rotatably arranged on the cam (49);

the middle of the top of the pressing block (45) is provided with a shifting rod (411), and the shifting rod (411) is matched with the shifting column (410);

a second rotating shaft (412), wherein the second rotating shaft (412) is rotatably arranged on one side of the top of the workbench (3);

a first belt transmission component (413), wherein the first belt transmission component (413) is arranged between the second rotating shaft (412) and the first rotating shaft (48);

the top of the second rotating shaft (412) is provided with a first one-way bearing (414);

the first circular gear (415) is arranged on the outer ring of the first one-way bearing (414);

the third rotating shaft (416) is rotatably arranged at the position, close to the second rotating shaft (412), of the top of the workbench (3);

the first gear (417) is arranged on the lower side of the third rotating shaft (416), and the first gear (417) is meshed with the first circular gear (415);

the second circular gear (418) is arranged above the first missing gear (417) on the third rotating shaft (416);

a bearing block (419), wherein the bearing block (419) is arranged at the position, close to the second rotating shaft (412), of the top of the workbench (3);

the bearing block (419) is provided with a fourth rotating shaft (420);

the lower end of the fourth rotating shaft (420) is provided with a second gear (421), and the second gear (421) is meshed with the second circular gear (418);

a fifth rotating shaft (422), wherein the bearing block (419) is provided with the fifth rotating shaft (422);

the first bevel gears (423) are arranged between the fifth rotating shaft (422) and the fourth rotating shaft (420), and the two first bevel gears (423) are meshed with each other;

the servo motor (424) is arranged at the position, close to the bearing block (419), of the top of the workbench (3), and the output shaft of the servo motor (424) is connected with the fifth rotating shaft (422) through a coupler;

and a second elastic piece (425) is arranged between the sliding block (43) and the inner wall close to the workbench (3).

2. The shielding inductor glue filling device for processing the electronic component as claimed in claim 1, wherein the glue filling mechanism (5) comprises:

the first sliding rail (51) is arranged on one side, away from the servo motor (424), of the top of the workbench (3);

a sliding plate (52), wherein the sliding plate (52) is arranged on the first sliding rail (51) in a sliding manner;

the connecting plate (53) is arranged on the lower side of the sliding plate (52);

the cover block (54) is arranged on one side, close to the servo motor (424), of the connecting plate (53);

the fixing plate (55) is arranged on one side, close to the servo motor (424), of the covering block (54);

the sliding plate (52) is symmetrically provided with the bearing seats (56) close to one side of the connecting plate (53);

the first guide post (57) is arranged between the fixing plate (55) and a bearing seat (56) close to the collecting box (31);

a first screw rod (58), wherein the first screw rod (58) is arranged between the fixing plate (55) and the bearing seat (56) far away from the collecting box (31);

the fixing plate (55) is provided with four first ejector blocks (59) close to one side of the first sliding rail (51);

the top of the workbench (3) is provided with the L-shaped plate (510) above the collection box (31);

the rack (511) is arranged on one side, close to the covering block (54), of the L-shaped plate (510);

the guide sleeve (512), the guide sleeve (512) is arranged on the first guide pillar (57) in a sliding way;

the first screw rod (58) is in threaded connection with the nut sleeve (513);

the box (514), the box (514) is arranged between the nut sleeve (513) and the guide sleeve (512);

the box comprises a first nut block (515), wherein the first nut block (515) is arranged in the box (514) in a sliding manner;

the first nut block (515) is in threaded connection with a second screw rod (516);

the upper end of the second screw rod (516) is provided with a second one-way bearing (517);

the connecting block (518), one side of the box (514) close to the fixing plate (55) is provided with the connecting block (518);

the bottom of the connecting block (518) is provided with the square box (519);

the first sliding block (520) is arranged in the square box (519) in a sliding mode;

third elastic pieces (521) are symmetrically arranged between the top of the first sliding block (520) and the inner wall of the square box (519);

the bottom of the first sliding block (520) is provided with a wiping block (522);

the second sliding block (523), the first sliding block (520) is internally and symmetrically provided with the second sliding block (523) in a sliding way;

the two second sliding blocks (523) are respectively and rotatably provided with a sixth rotating shaft (524) at the back side;

the rubber sliding sleeves (525) are symmetrically arranged on the sixth rotating shaft (524), and the rubber sliding sleeves (525) are matched with the linear grooves in the side walls of the square boxes (519);

the blades (526) are arranged on the opposite sides of the two sixth rotating shafts (524), and the blades (526) are matched with the first jacking block (59);

a circular ring (527), wherein the circular ring (527) is arranged at the end part of the sixth rotating shaft (524);

the T-shaped block (528) is arranged on one side, away from the connecting block (518), of the box (514);

the second guide post (529) is symmetrically and slidably arranged on the T-shaped block (528);

the pressing wheel (530) is rotatably arranged between the lower ends of the two second guide columns (529);

the fourth elastic piece (531), the second guide pillar (529) is sleeved with the fourth elastic piece (531);

the second nut block (532) is arranged on one side, close to the servo motor (424), of the fixing plate (55);

the upper end of the third rotating shaft (416) is provided with a third screw rod (533), and the third screw rod (533) is in threaded connection with the second nut block (532);

the bearing rod (534) is arranged at the position, close to the servo motor (424), of the top of the workbench (3);

the first sliding seat (535), one side of the top of the workbench (3) close to the servo motor (424) is provided with the first sliding seat (535);

a third guide post (536), wherein the first sliding seat (535) is provided with the third guide post (536) in a sliding way;

the N-shaped block (537) is arranged at one end, close to the bearing rod (534), of the third guide pillar (536);

a fifth elastic piece (538), wherein the fifth elastic piece (538) is arranged between the N-shaped block (537) and the first sliding seat (535);

a seventh rotating shaft (539), wherein the bearing rod (534) is provided with the seventh rotating shaft (539);

a second belt transmission assembly (540) is arranged among the seventh rotating shaft (539), the first screw rod (58) and the N-shaped block (537);

an eighth rotating shaft (541), wherein the eighth rotating shaft (541) is rotatably arranged at the top of the workbench (3) between the bearing rod (534) and the bearing block (419);

the eighth rotating shaft (541) is provided with a fourth circular gear (542), and the fourth circular gear (542) is meshed with the second missing gear (421);

a second bevel gear (543), a second bevel gear (543) is arranged between the eighth rotating shaft (541) and the seventh rotating shaft (539), and the two second bevel gears (543) are meshed with each other;

a third circular gear (544) is arranged on the outer ring of the second one-way bearing (517), and the third circular gear (544) is meshed with the rack (511);

the opposite sides of the two sixth rotating shafts (524) are sleeved with the sixth elastic pieces (545);

and seventh elastic pieces (546) are arranged between the opposite sides of the two second sliding blocks (523) and the inner wall of the first sliding block (520) in a close way.

3. The shielding inductor glue-pouring device for processing the electronic component as claimed in claim 2, wherein the resetting mechanism (6) comprises:

the sliding plate (52) is symmetrically provided with a second sliding rail (61) close to one side of the servo motor (424);

the N-shaped ejector rod (62) is arranged on the second sliding rail (61) in a sliding mode, and the N-shaped ejector rod (62) is matched with the blade (526);

the top of the sliding plate (52) is symmetrically and slidably provided with a second sliding seat (63) at one side far away from the servo motor (424);

the fourth guide post (64) is arranged on the second sliding seat (63), and the fourth guide post (64) is in sliding fit with the similar N-shaped ejector rod (62);

the eighth elastic piece (65) is sleeved on the fourth guide pillar (64);

the second ejector block (66) is arranged on the second sliding rail (61) in a sliding mode, and the second ejector block (66) is matched with the similar N-shaped ejector rod (62);

a ninth elastic piece (67), two ninth elastic pieces (67) are arranged between the second top block (66) and the inner wall of the second slide rail (61) close to each other;

the handle (68) is arranged above the fourth guide post (64) on one side of the N-shaped ejector rod (62) close to the second sliding seat (63);

the third sliding blocks (69) are arranged on the two second sliding rails (61) in a sliding mode on the back side;

the third sliding block (69) is provided with a guide rod (610), and the guide rod (610) is matched with the circular ring (527);

and a tenth elastic piece (611) is arranged between the third sliding block (69) and the inner wall close to the second sliding rail (61).

4. The device for encapsulating the shielding inductor in the electronic component processing as claimed in claim 3, wherein the return mechanism (7) comprises:

a fixed sleeve (71), wherein the fixed sleeve (71) is arranged above the T-shaped block (528) of the box (514);

the sliding rod (72) is arranged on the fixed sleeve (71) in a sliding manner;

the lower end of the sliding rod (72) is provided with a first convex column (73);

the eleventh elastic piece (74) is sleeved on the sliding rod (72);

the top of the connecting plate (53) is symmetrically provided with the side plates (75);

the middle part of the side plate (75) is provided with a special-shaped loop bar (76) in a sliding way, and the special-shaped loop bar (76) is matched with the similar N-shaped ejector rod (62) in a sliding way;

the hinge assembly (77) is arranged between the tops of the two special-shaped loop bars (76);

the hinge assembly (77) is provided with an elastic inserted rod (78), and the elastic inserted rod (78) is matched with the sliding rod (72);

the elastic inserted rod (78) is provided with a second convex column (79);

the wheel (710) is arranged on the upper side of the side plate (75), and the wheel (710) is matched with the second convex column (79);

the side plate (75) is provided with a guide block (711) below the wheel (710), and the guide block (711) is matched with the first convex column (73);

a twelfth elastic piece (712), wherein the twelfth elastic piece (712) is arranged between the hinge assembly (77) and the elastic plug rod (78).

5. The shielded inductor glue-pouring device for processing electronic components as claimed in claim 4, further comprising:

the rubber block (8) is arranged on the rubber block (8) and the poking block (46).

6. The device as claimed in claim 5, further comprising:

the top of the sliding plate (52) is provided with a brush plate (9), and the brush plate (9) is matched with the pressing wheel (530).

7. The shielded inductor glue filling device for processing electronic components as claimed in claim 6, further comprising:

the sealing strip (10) is arranged in the middle of the box (514).

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