CN222051555U - Coil cutting test tinning device - Google Patents

Abstract

The utility model discloses a coil pin cutting test tin dipping device which comprises a frame, a plurality of jigs, a fork pushing mechanism, a shearing mechanism, a tin dipping mechanism, a testing mechanism and a material receiving mechanism, wherein the fork pushing mechanism is arranged on the frame and used for pushing the jigs along the X direction, and the shearing mechanism, the tin dipping mechanism, the testing mechanism and the material receiving mechanism are sequentially arranged below the fork pushing mechanism along the X direction. The machine frame is also provided with a reflux mechanism positioned above the push fork mechanism, the reflux mechanism comprises two belt lines which are arranged at intervals and extend along the X direction, a motor which is arranged on the machine frame and used for driving one of the belt lines to rotate, one end, close to the shearing mechanism, of the upper end of the belt line is provided with a stop block, and one end of the belt line, close to the shearing mechanism, of the material receiving mechanism forms a channel with the machine frame, and the channel can be used for a jig to ascend to the corresponding position of the upper end of the belt line. The advantages are that: can effectively realize the quick reflux of the jig and improve the production efficiency.

Description

Coil pin cutting test tin immersion device

Technical Field

The utility model relates to the field of coil processing equipment, in particular to a coil pin cutting test tin dipping device.

Background

The coil is according to the application needs in manufacturing process, need cut out unnecessary pin and carry out the tin pick-up to the pin, and current device adopts the mode of sliding guide rail more, places the coil in the guide rail, through linkage pushing mechanism, moves unit distance with a plurality of coils along the guide rail simultaneously for the guide rail carries out processes such as cutting foot, wicking in proper order. Although this approach can reduce the complexity of the apparatus and also can process multiple rails simultaneously, the efficiency remains to be improved. And the coil is placed by arranging the jigs, and then a plurality of jigs are moved along the guide rail for unit distance by the pushing mechanism, so that the guide rail is sequentially subjected to processes such as pin cutting, tin dipping and the like. However, the equipment is manual in recycling of the jig, so that the jig is inconvenient to reflow, and the working efficiency is reduced.

In view of this, it is necessary to provide a coil dicing test wicking apparatus.

Disclosure of Invention

The utility model provides a coil pin cutting test tin-dipping device, which effectively solves the problem that the working efficiency of the existing coil pin cutting test tin-dipping device is low when a coil is processed.

The technical proposal adopted by the utility model is that

The coil pin cutting test tin dipping device comprises a frame, a plurality of jigs, a fork pushing mechanism, a shearing mechanism, a tin dipping mechanism, a testing mechanism and a material receiving mechanism, wherein the fork pushing mechanism is arranged on the frame and used for pushing the jigs along the X direction, and the shearing mechanism, the tin dipping mechanism, the testing mechanism and the material receiving mechanism are sequentially arranged below the fork pushing mechanism along the X direction. The machine frame is also provided with a reflux mechanism positioned above the push fork mechanism, the reflux mechanism comprises two belt lines which are arranged at intervals and extend along the X direction, a motor which is arranged on the machine frame and used for driving one of the belt lines to rotate, one end, close to the shearing mechanism, of the upper end of the belt line is provided with a stop block, and one end of the belt line, close to the shearing mechanism, of the material receiving mechanism forms a channel with the machine frame, and the channel can be used for a jig to ascend to the corresponding position of the upper end of the belt line.

Further is: the utility model provides a cutting mechanism, including setting up preceding cutter unit spare in the frame, with preceding cutter unit spare corresponds back cutter unit spare and set up the clamp line subassembly between preceding cutter unit spare and back cutter unit spare, clamp line subassembly includes two splint, along a plurality of No. one cylinders of vertical setting in the frame, set up a clamping jaw in No. one cylinder output, a clamping jaw includes a cylinder body and sets up two claw toecaps on a cylinder body, two splint set up respectively on two claw toecaps relatively, preceding cutter unit spare includes along the vertical setting in the frame and the ascending No. two cylinders of output, set up a board of No. two cylinder outputs, slide along X direction setting on a board be used for driving a sliding No. three cylinders of slide, fixed cutter, the output of fixed cutter of cutter unit one end along the flexible No. four cylinders output of Y direction that is close to in a board and set up in No. four cylinder output, the cutter cuts the pin of coil with fixed cutter cooperation realization.

Further is: the tin immersion mechanism comprises a tin furnace and a plurality of No. five cylinders which are vertically arranged on the frame and used for driving the tin furnace to lift.

Further is: the pushing fork mechanism comprises two pushing assemblies and two fixed cross bars which are respectively arranged below two belt lines, two ends of the jig slide on the two fixed cross bars respectively, the two pushing assemblies are respectively used for pushing two ends of the jig, each pushing assembly comprises a support fixedly arranged on a frame, a No. six cylinder arranged on the support along the Y direction, a No. two plate fixedly arranged at the output end of the No. six plate, a No. seven cylinder of which the output end stretches out and draws back along the X direction, and a push plate fixedly arranged at the output end of the No. seven cylinder, a plurality of clamping grooves used for clamping the end parts of the jig are formed in the push plate at equal intervals, and the distance between two adjacent clamping grooves is equal to the stroke of the output end of the No. seven cylinder.

Further is: the material receiving mechanism comprises a material box arranged on the frame, a material guide plate arranged on the frame, a jacking component arranged on the frame and used for jacking the jig from the fixed cross rod, and a pushing component used for pushing the coil out of the jig.

The utility model has the beneficial effects that: can effectively realize the quick reflux of the jig and improve the production efficiency.

Drawings

Fig. 1 is an overall schematic diagram of a coil pin cutting test wicking device according to an embodiment of the application.

Fig. 2 is a schematic diagram of a reflow mechanism and a fixture of a coil dicing test wicking device according to an embodiment of the application.

Fig. 3 is a schematic diagram of a shearing mechanism of a coil pin cutting test wicking device according to an embodiment of the application.

Fig. 4 is a schematic diagram of a tin dipping mechanism of a coil pin cutting test tin dipping device according to an embodiment of the application.

Fig. 5 is a schematic diagram of a fork pushing mechanism and a jig of a coil pin cutting test wicking device according to an embodiment of the application.

Fig. 6 is a schematic diagram of one view of a fixture of a coil dicing test wicking device according to an embodiment of the application.

Fig. 7 is a schematic diagram of another view of a fixture of a coil dicing test wicking device according to an embodiment of the application.

Marked in the figure as: 1. a frame; 2. a jig; 3. a fork pushing mechanism; 4. a shearing mechanism; 5. a tin immersion mechanism; 6. a testing mechanism; 7. a material receiving mechanism; 8. a reflow mechanism; 81. a belt line; 82. a motor I; 83. a stop block; 100. a channel; 41. a front cutter assembly; 42. a rear cutter assembly; 43. a wire clamping assembly; 431. a clamping plate; 432. a first air cylinder; 433. a first clamping jaw; 411. a second cylinder; 412. a first plate; 413. a first slide plate; 414. a third cylinder; 415. fixing the cutter; 416. sliding the cutter; 417. a fourth air cylinder; 51. a tin furnace; 52. a fifth cylinder; 31. a pushing assembly; 32. fixing the cross bar; 311. a support; 312. a sixth air cylinder; 313. a second plate; 314. a seventh air cylinder; 315. a push plate; 21. a magnetic strip; 22. an elastic ejection member; 201. a placement groove; 71. a magazine; 72. a material guide plate; 73. a jacking assembly; 74. a pushing component;

Detailed Description

In order that the above objects, features and advantages of the utility model will be readily understood, a more particular description of the utility model will be rendered by reference to the appended drawings.

As shown in fig. 1 and 2, the coil pin cutting test tin dipping device provided by the embodiment of the application comprises a frame 1, a plurality of jigs 2, a fork pushing mechanism 3 arranged on the frame 1 and pushing the jigs 2 along the X direction, a shearing mechanism 4, a tin dipping mechanism 5, a testing mechanism 6 and a material receiving mechanism 7 which are sequentially arranged below the fork pushing mechanism 3 along the X direction. The machine frame 1 is further provided with a reflux mechanism 8 positioned above the push fork mechanism 3, the reflux mechanism 8 comprises two belt lines 81 which are arranged at intervals and extend along the X direction, a first motor 82 which is arranged on the machine frame 1 and used for driving one of the belt lines 81 to rotate, a stop block 83 is arranged at one end, close to the shearing mechanism 4, of the upper end of the belt line 81 positioned on the machine frame 1, and a channel 100 which is positioned at the corresponding position of the upper end of the belt line 81 and used for allowing the jig 2 to ascend is formed between one end of the material receiving mechanism 7 and the machine frame 1.

When it is noted that, as shown in fig. 6 and 7, the jig 2 includes a magnetic strip 21 and an elastic ejector 22 disposed in the magnetic strip 21, the shrinkage direction of the elastic ejector 22 is along the X direction, and a plurality of placement slots 201 arranged along the Y direction and lead notches connected to the lower ends of the placement slots 201 are disposed on the side of the magnetic strip 21. Each elastic ejection piece 22 corresponds to one placing groove 201, and when the jig 2 is pushed to the upper part of the material receiving mechanism 7 by the push fork mechanism 3 after detection, the elastic ejection pieces 22 are abutted against the frame 1, so that the elastic ejection pieces 22 eject products from the jig 2.

When in actual use, the coil is placed in the jig 2, after the jig 2 is pushed to the corresponding position of the shearing mechanism 4 by the push fork mechanism 3, the shearing mechanism 4 shears redundant parts of pins of the coil, then the push fork mechanism 3 pushes the jig 2 to the tin dipping mechanism 5, the tin dipping mechanism 5 is utilized to dip tin on the pins, then the push fork mechanism 3 pushes the jig 2 to the testing mechanism 6, the testing mechanism 6 is utilized to test the pins of the coil, then the blanking mechanism is utilized to carry out blanking, the jig 2 is pushed upwards along the channel 100 and pushed onto the belt line 81, then the belt line 81 drives the jig 2 to move towards the other end, and finally the stop block 83 is utilized to stop the jig 2 on the belt line 81.

In the above-mentioned design, can effectually realize the quick backward flow to tool 2, improve production efficiency.

Specifically: as shown in fig. 1 and 3, the shearing mechanism 4 includes a front cutter assembly 41 disposed on the frame 1, a rear cutter assembly 42 corresponding to the front cutter assembly 41, and a wire clamping assembly 43 disposed between the front cutter assembly 41 and the rear cutter assembly 42, the wire clamping assembly 43 includes two clamping plates 431, a plurality of first cylinders 432 disposed on the frame 1 vertically, a first clamping jaw 433 disposed at an output end of the first cylinders 432, the first clamping jaw 433 includes a first cylinder and two claw toes disposed on the first cylinder, the two clamping plates 431 are disposed on the two claw toes respectively, the front cutter assembly 41 includes a second cylinder 411 disposed vertically on the frame 1 and having an output end facing upwards, a first plate 412 disposed on the output end of the second cylinder 411, a first sliding plate 413 disposed on the first plate 412 and sliding along an X direction, a third cylinder 414 disposed on the first plate 412 and used for driving the first sliding plate 413 to slide, a fixed cutter 415 fixedly disposed on one end of the first sliding plate 413 and a fourth cylinder 415 disposed on the output end of the second cylinder 413 and a fourth cylinder 416 disposed on the output end of the fourth cylinder 417 and a fourth cylinder 416 are disposed on the output end of the fourth cylinder 416 to realize telescopic fit.

In actual use, the front cutter assembly 41 and the rear cutter assembly 42 cut off the two pins of the coil respectively. The front cutter assembly 41 and the rear cutter assembly 42 have the same working principle that the lower ends of the pins are clamped by the wire clamping assembly 43, and then the front cutter assembly 41 and the rear cutter assembly 42 shear. The wire clamping assembly 43 acts as follows: the first cylinder 432 drives the first clamping jaw 433 to ascend so that the lower end of the pin is positioned between the two clamping plates 431, and then the first clamping jaw 433 drives the two clamping plates 431 to close so as to fix the pin. The action of the front cutter assembly 41 is: the first plate 412 is driven to ascend through the second air cylinder 411, the first sliding plate 413 is driven to slide to one side of the pin through the third air cylinder 414, the pin is located in an opening formed by dislocation of the sliding cutter 416 and the fixed cutter, and then the sliding cutter 416 is driven to slide through the fourth air cylinder 417, so that the pin is cut.

In the above design, the structural design and the specific embodiment of the shearing mechanism 4 can effectively realize rapid cutting of the pins.

Specifically: as shown in fig. 4, the tin immersion mechanism 5 includes a tin furnace 51, and a plurality of fifth cylinders 52 vertically disposed on the frame 1 for driving the tin furnace 51 to lift.

In actual use, when the jig 2 is pushed to the upper part of the tin furnace 51 by the fork pushing mechanism 3, the tin furnace 51 is driven to ascend by the No. five air cylinder 52 to realize tin dipping of pins.

In the above design, the structural design and the specific embodiment of the tin dipping mechanism 5 can effectively realize tin dipping of the pins.

Specifically: as shown in fig. 1 and 5, the fork pushing mechanism 3 includes two pushing assemblies 31 and two fixing cross bars 32 respectively disposed below the two belt lines 81, two ends of the jig 2 slide on the two fixing cross bars 32 respectively, two pushing assemblies 31 are respectively used for pushing two ends of the jig 2, the pushing assemblies 31 include a support 311 fixedly disposed on the frame 1, a No. six cylinder 312 disposed on the support 311 along the Y direction, a No. two plate 313 fixedly disposed on the output end of the No. six plate, a No. seven cylinder 314 with the output end extending along the X direction, and a push plate 315 fixedly disposed on the output end of the No. seven cylinder 314, a plurality of clamping grooves for clamping the end of the jig 2 are equidistantly disposed on the push plate 315, and the distance between two adjacent clamping grooves is equal to the stroke of the output end of the No. seven cylinder 314.

In actual use, when the jig 2 is placed on the fixed cross bar 32, the pushing assembly 31 acts, the second plate 313 is driven to move towards the end of the jig 2 by the sixth air cylinder 312, the end of the jig 2 stretches into the clamping groove, the seventh air cylinder 314 drives the push plate 315 to move towards one side of the material receiving mechanism 7 by a stroke unit, the sixth air cylinder 312 drives the second plate 313 to reset, and the air cylinder drives the push plate 315 to reset.

In the above design, the structural design of the fork pushing mechanism 3 can enable a plurality of jigs 2 to be moved simultaneously, so that the efficiency is improved and the cost is saved.

Specifically: as shown in fig. 1, the material receiving mechanism 7 includes a material box 71 disposed on the frame 1, a material guiding plate 72 disposed on the frame 1, a lifting assembly 73 disposed on the frame 1 for lifting the jig 2 from the fixing cross bar 32, and a material pushing assembly 74 for pushing the coil out of the jig 2.

In actual use, when the pushing fork mechanism 3 pushes the jig 2 up from the fixed cross bar 32 through the jacking component 73, then the pushing component 74 is utilized to push the jig 2 onto the belt line 81. So that the empty jig 2 flows back along the belt.

In the above design, the structural design and the specific embodiment of the material receiving mechanism 7 can effectively realize the rapid reflux of the jig 2.

It should be understood that the foregoing description is only illustrative of the present utility model and is not intended to limit the utility model to the particular forms disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the utility model.

Claims (5)

1. Coil pin cutting test wicking device, including frame (1), a plurality of tool (2), set up in frame (1) along X direction push away fork mechanism (3) that go on pushing away to tool (2), set gradually in X direction and push away shearing mechanism (4), wicking mechanism (5), testing mechanism (6) and receiving mechanism (7) of fork mechanism (3) below, its characterized in that: the machine frame is characterized in that a backflow mechanism (8) located above the push fork mechanism (3) is further arranged on the machine frame (1), the backflow mechanism (8) comprises two belt lines (81) which are arranged at intervals and extend along the X direction, a first motor (82) which is arranged on the machine frame (1) and used for driving one of the belt lines (81) to rotate, a stop block (83) is arranged at one end, close to the shearing mechanism (4), of the upper end of the belt line (81) on the machine frame (1), and the belt line (81) is located at one end of the material collecting mechanism (7) and forms a channel (100) which can be used for the jig (2) to ascend to the corresponding position of the upper end of the belt line (81).

2. The coil pin cutting test wicking device of claim 1, wherein: the shearing mechanism (4) comprises a front cutter assembly (41) arranged on the frame (1), a rear cutter assembly (42) corresponding to the front cutter assembly (41) and a wire clamping assembly (43) arranged between the front cutter assembly (41) and the rear cutter assembly (42), wherein the wire clamping assembly (43) comprises two clamping plates (431), a plurality of first air cylinders (432) vertically arranged on the frame (1), a first clamping jaw (433) arranged at the output end of the first air cylinders (432), the first clamping jaw (433) comprises a first cylinder body and two claw toes arranged on the first cylinder body, the two clamping plates (431) are respectively and oppositely arranged on the two claw toes, the front cutter assembly (41) comprises a second air cylinder (411) vertically arranged on the frame (1) and with the output end upwards, a first sliding plate (412) arranged at the output end of the second air cylinder (411), a first sliding plate (413) vertically arranged on the first air cylinder (412) in the X direction in a sliding mode, a first sliding plate (413) arranged on the first air cylinder (412) in the X direction in a sliding mode, a first sliding plate (414) is used for driving the first sliding plate (414) and a second sliding plate (417) is arranged at the output end of the first sliding plate (416) in a sliding mode, the cutter assembly is arranged at one end of the second sliding plate (417) in the direction is arranged on the sliding plate (416) in a mode, and is arranged on the end of the sliding plate (416) is arranged on the sliding plate (Z direction) and is fixed, the sliding cutter (416) is matched with the fixed cutter (415) to cut the pins of the coil.

3. The coil pin cutting test wicking device of claim 1, wherein: the tin immersion mechanism (5) comprises a tin furnace (51) and a plurality of five-number air cylinders (52) which are vertically arranged on the frame (1) and used for driving the tin furnace (51) to lift.

4. The coil pin cutting test wicking device of claim 1, wherein: push away fork mechanism (3) including two pushing away subassembly (31) and two fixed horizontal pole (32) that set up respectively in two belt line (81) below, the both ends of tool (2) slide on two fixed horizontal poles (32) respectively, two pushing away subassembly (31) are used for pushing away tool (2) both ends respectively, pushing away subassembly (31) including fixed support (311) that set up on frame (1), setting up No. six cylinder (312) on support (311) along the Y direction, fixed No. two boards (313) that set up in No. six board output, the output is along the flexible No. seven cylinder (314) of X direction and fixed push pedal (315) that set up in No. seven cylinder (314) output, equidistance is provided with a plurality of draw-in grooves that are used for carrying out the joint to tool (2) tip on push pedal (315), and the distance of two adjacent draw-in grooves equals the stroke of No. seven cylinder (314) output.

5. The coil pin cutting test wicking device of claim 1, wherein: the material receiving mechanism (7) comprises a material box (71) arranged on the frame (1), a material guide plate (72) arranged on the frame (1), a jacking component (73) arranged on the frame (1) and used for jacking the jig (2) from the fixed cross rod (32), and a material pushing component (74) used for pushing out the coil from the jig (2).