阅读说明：本技术 一种电子元器件生产流水线 (Electronic components production water line ) 是由 林瑞 于 2020-07-27 设计创作，主要内容包括：本发明涉及一种电子元器件生产流水线,包括底板、支架板、凹模传送装置和捋平装置,所述的底板安装在已有的工作地面上,底板的右端安装有支架板,支架板的左端面安装有凹模传送装置,凹模传送装置的左侧设置有捋平装置,本发明采用捋平装置是在电子元器件生产流水线中加上此步骤,对生产出的电子元器件插腿进行捋平,捋平工作时既要达到捋平效果又要保护电子元器件插腿不受到伤害,从而也提高了电子元器件的使用便捷度。(The invention relates to an electronic component production line which comprises a bottom plate, a support plate, a female die conveying device and a smoothing device, wherein the bottom plate is arranged on the existing working ground, the support plate is arranged at the right end of the bottom plate, the female die conveying device is arranged on the left end face of the support plate, and the smoothing device is arranged on the left side of the female die conveying device.)

1. The utility model provides an electronic components production water line, includes bottom plate (1), mounting panel (2), die conveyer (3) and smooths down device (4), its characterized in that: the bottom plate (1) is arranged on the existing working ground, the right end of the bottom plate (1) is provided with the support plate (2), the left end face of the support plate (2) is provided with the female die conveying device (3), and the left side of the female die conveying device (3) is provided with the smoothing device (4);

the die conveying device (3) comprises a first rotating shaft (30), a first vertical plate (31), a die conveying belt (32), a second rotating shaft (33), a round head plate (34), a conveying mechanism (35) and a second vertical plate (36), one end of the first rotating shaft (30) is installed on the support plate (2) through a first bearing, the other end of the first rotating shaft (30) is installed on the right end face of the first vertical plate (31) through a second bearing, the die conveying belt (32) is installed on the first rotating shaft (30), the rear end of the die conveying belt (32) is installed on the second rotating shaft (33), a die plate (34) is installed between the first rotating shaft (30) and the second rotating shaft (33), the die plate (34) is installed on the two sides of the die conveying belt (32) in a left-to-left symmetrical mode, a rectangular vertical through groove is formed in the left side of the die conveying belt (34), and the conveying mechanism (35) is arranged on, the conveying mechanism (35) is positioned at the rear side of the first vertical plate (31), the left end of the second rotating shaft (33) is installed on the second vertical plate (36), and the right end face of the second rotating shaft (33) is installed on the left end face of the support plate (2);

the smoothing device (4) comprises an ear seat (40), a swing rod (41), a convex column (42), a rotating rod (43), a rotating shaft (44), a support seat (45), a first motor (46), a guide plate (47), a clamping mechanism (48), a supporting frame plate (49) and a die plate (4a), wherein the ear seat (40) is installed on the upper end face of the bottom plate (1), the ear seat (40) is positioned at the rear side of the conveying mechanism (35), the swing rod (41) is connected with the ear seat (40) through a pin shaft, a round-head through groove is formed in the swing rod (41), the convex column (42) is arranged in the round-head through groove, the convex column (42) is connected with the round-head through groove in a sliding fit mode, the rear end face of the convex column (42) is connected with one end of the rotating rod (43), the rotating shaft (44) is installed at the other end face of the rotating rod (43), and the rotating shaft (44) is installed on, a rotating shaft (44) penetrates through a support (45) and is connected with the output end of a first motor (46), the upper end of a swing rod (41) is connected with a guide plate (47) through a cylinder, a clamping mechanism (48) is installed on the right end face of the guide plate (47), the lower end of the clamping mechanism (48) is connected with the upper end face of a bottom plate (1) through a support frame plate (49), mold plates (4a) are symmetrically arranged in the clamping mechanism (48) up and down, the right end of each mold plate (4a) is connected with a rectangular through groove in a sliding fit mode, and the rectangular through groove is formed in the left end face of a circular head plate (34).

2. An electronic component production line as claimed in claim 1, wherein: the conveying mechanism (35) comprises a second motor (350), a first transmission shaft (351), a support plate (352), a conveying belt (353), a second transmission shaft (354), a first gear (355), a second gear (356), a third transmission shaft (357), a circular plate (358), a transmission column (359) and a groove-shaped plate (35a), the second motor (350) is installed on the upper end face of the bottom plate (1) through a support, the first transmission shaft (351) is installed at the output end of the second motor (350), the support plate (352) is symmetrically installed in the front of and behind the first transmission shaft (351), the lower end face of the support plate (352) is installed on the upper end face of the bottom plate (1), the conveying belt (353) is installed on the first transmission shaft (351), the right end of the conveying belt (353) is connected with the second transmission shaft (354), the second transmission shaft (354) is installed on the support plate (352), the first gear (355) is installed at the front end of the second transmission shaft (354) penetrating through, no. two gears (356) are arranged on the right end face of a first gear (355), the first gear (355) is connected with the second gear (356) in a meshing mode, an included angle between the first gear (355) and the second gear (356) is 90 degrees, a third transmission shaft (357) is arranged on the right end face of the second gear (356), a circular plate (358) is arranged on the third transmission shaft (357) in a penetrating mode on a support plate (2), the circular plate (358) is located on the right side of the support plate (2), a transmission column (359) is arranged on the left end face of the circular plate (358), a groove plate (35a) is arranged at the left end of the transmission column (359), the transmission column (359) is connected with the groove plate (35a) in a sliding fit mode, and the right end face of a rotating shaft (30) is arranged on the groove plate (35 a).

3. An electronic component production line as claimed in claim 1, wherein: the clamping mechanism (48) comprises a U-shaped clamp (480), a clamping plate (481), a bidirectional cylinder (482), a telescopic rod (483), a rectangular transmission plate (484), a rectangular division plate (485), a guide pillar (486), a circular shaft (487), a transfer rod (488), a push block (489) and a push plate (48a), wherein the U-shaped clamp (480) is installed on the right end face of the guide plate (47), the clamping plate (481) is symmetrically arranged in the U-shaped clamp (480) from top to bottom, the clamping plate (481) is connected with a rectangular groove in a sliding fit mode, the rectangular groove is formed in the right end of the inner wall of the U-shaped clamp (480), a mold plate (4a) is installed at the inner side end of the clamping plate (481), the lower end faces of the clamping plate (481) are connected through the bidirectional cylinder (482), the telescopic rod (483) is installed on the left end face of the inner wall of the clamping plate (481), and the telescopic rod (483, the sleeve plate is sleeved on a cylinder body of a bidirectional cylinder (482), a telescopic rod (483) is connected with a rectangular groove in a sliding fit mode, the rectangular groove is formed in the left end face of a mold plate (4a), a rectangular transmission plate (484) is installed in the rectangular groove in a sliding fit mode, the rectangular transmission plate (484) is located on a U-shaped mold groove, the U-shaped mold groove is formed in the lower end face of the mold plate (4a), the U-shaped mold grooves are uniformly distributed from front to back, a rectangular sub-plate (485) is installed at the right end of the rectangular transmission plate (484), guide columns (486) are installed on the right end face of the rectangular sub-plate (485), the guide columns (486) are equidistantly distributed from front to back, a circular shaft (487) is installed at the right end of the guide columns (486), transfer rods (488) are symmetrically installed on the circular shaft (487) from front to back, the transfer rods (488) are connected with one end of a push block (489) through circular pins, the pushing plate (48a) is connected with the U-shaped die groove in a sliding fit mode.

4. An electronic component production line as claimed in claim 1, wherein: the brush flat column (320) is arranged above the female die conveyor belt (32), the brush flat column (320) is located at the right end of the rectangular vertical through groove, a brush (321) is installed on the lower end face of the brush flat column (320), the upper end face of the brush flat column (320) is connected with the output end of a third motor (322), the third motor (322) is installed on the left end face of the support plate (2) through a support plate, a rectangular baffle plate (323) is arranged on the rear side of the brush (321), and the inner side end face of the circular head plate (34) is installed at the left end face and the right end face of the rectangular baffle plate (323).

5. An electronic component production line as claimed in claim 1, wherein: the left end face of the support plate (2) is provided with a rectangular groove, an electric push rod (20) is arranged in the rectangular groove, a pressing plate (21) is installed at the upper end of the electric push rod (20), a pressing block (22) is installed at the left end of the pressing plate (21), and the pressing block (22) is located on the right side of the rectangular through groove of the left circular head plate (34).

6. An electronic component production line as claimed in claim 3, wherein: the outer end of the transmission rod (488) is connected with one end of a buffer plate (48b) in a sliding fit mode, and the other end of the buffer plate (48b) is provided with a compression spring (48 c).

Technical Field

The invention relates to the technical field of electronic component production, in particular to an electronic component production line.

Background

The electronic component is a component of an electronic element and a small machine or instrument, is composed of a plurality of parts, can be commonly used in the similar products, is a general name of electronic devices such as a capacitor, a transistor, a hairspring, a clockwork spring and the like, is a general name of the electronic devices such as the capacitor, the transistor, the hairspring, the clockwork spring and the like, is a common diode, the triode and the like, is a semiconductor triode which is a semiconductor triode, is also called a bipolar transistor and a crystal triode, is a semiconductor device for controlling current, has the function of amplifying a weak signal into an electric signal with a large amplitude value, and is also used as a contactless switch, but the following problems can occur in the process of the electronic components of:

1. generally, for electronic components with pins, such as triodes, in an industrial production line, the steps of smoothing the pins of the electronic components are fewer in the production process, so that the pins of the produced electronic components need to be smoothed when in use, and the use convenience of the electronic components is reduced.

2. When the electronic component inserting legs are smoothed out, parts of electronic components are easy to omit, so that the produced electronic component inserting legs need to be smoothed out again in the using process, and the using flow is increased.

Disclosure of Invention

Technical scheme (I)

In order to achieve the purpose, the invention adopts the following technical scheme that the electronic component production line comprises a bottom plate, a support plate, a female die conveying device and a smoothing device, wherein the bottom plate is installed on the existing working ground, the right end of the bottom plate is provided with the support plate, the left end surface of the support plate is provided with the female die conveying device, and the left side of the female die conveying device is provided with the smoothing device;

the die conveying device comprises a first rotating shaft, a first vertical plate, a die conveying belt, a second rotating shaft, a round head plate, a conveying mechanism and a second vertical plate, wherein one end of the first rotating shaft is arranged on the support plate through a first bearing, the other end of the first rotating shaft is arranged on the right end face of the first vertical plate through a second bearing, the die conveying belt is arranged on the first rotating shaft, the rear end of the die conveying belt is arranged on the second rotating shaft, a round head plate is arranged between the first rotating shaft and the second rotating shaft, the round head plates are symmetrically arranged on the left side and the right side of the die conveying belt, a rectangular vertical through groove is formed in the left side of the round head plate, the conveying mechanism is arranged on the left side of the rectangular vertical through groove and is positioned on the rear side of the first vertical plate, the left end of the second rotating shaft is arranged on the second vertical plate, the right end face of the second rotating shaft, the die conveyer belt drives the second rotating shaft to rotate, the components entering the die are conveyed, and the round head plate prevents the components from sliding down in the conveying process.

The smoothing device comprises an ear seat, a swing rod, a convex column, a rotating rod, a rotating shaft, a support, a motor, a guide plate, a clamping mechanism, a support frame plate and a mold plate, wherein the ear seat is arranged on the upper end surface of the bottom plate, the ear seat is positioned at the rear side of the conveying mechanism, the swing rod is connected with the ear seat through a pin shaft, a round-head through groove is formed in the swing rod, the convex column is arranged in the round-head through groove, the convex column is connected with the round-head through groove in a sliding fit mode, the rear end surface of the convex column is connected with one end of the rotating rod, the rotating shaft is arranged at the other end of the rotating rod through the support, the rotating shaft penetrates through the support and is connected with the output end of the motor, the upper end of the swing rod is connected with the guide plate through a cylinder, the clamping mechanism is arranged on the, the interior longitudinal symmetry of clamping mechanism is provided with the mould board, the right-hand member of mould board is connected with the logical groove of rectangle through sliding fit, the logical groove of rectangle is seted up at the left end face of head board, it rotates to drive the dwang through a motor, the dwang passes through projection synchronous drive pendulum rod left and right sides reciprocating motion, pendulum rod synchronous drive baffle left and right sides reciprocating motion, the baffle drives clamping mechanism reciprocating motion about the up end of support frame plate in step, and simultaneously, clamping mechanism drives the mould board and presss from both sides tightly the components and parts spud leg, the mould board is smoothed out the components and parts spud leg, make the components and parts outward appearance of carrying out once more level.

As a preferred technical scheme of the invention, the conveying mechanism comprises a second motor, a first transmission shaft, a support plate, a conveying belt, a second transmission shaft, a first gear, a second gear, a third transmission shaft, a circular plate, a transmission column and a groove plate, wherein the second motor is arranged on the upper end surface of the bottom plate through a bracket, the output end of the second motor is provided with the first transmission shaft, the support plate is symmetrically arranged in front and at the back of the first transmission shaft, the lower end surface of the support plate is arranged on the upper end surface of the bottom plate, the first transmission shaft is provided with the conveying belt, the right end of the conveying belt is connected with the second transmission shaft, the second transmission shaft is arranged on the support plate, the front end of the second transmission shaft penetrates through the support plate and is provided with the first gear, the right end surface of the first gear is provided with the second gear, the first gear is connected with the second gear in a meshing manner, and, no. three transmission shafts are installed to the right-hand member face of No. two gears, No. three transmission shafts penetrate the mounting panel and install the plectane, the plectane is located the right side of mounting panel, the transmission post is installed to the left end face of plectane, the left end of transmission post is provided with the channel plate, be connected through sliding fit mode between transmission post and the channel plate, the right-hand member face in pivot is installed to the channel plate, drive a transmission shaft synchronous revolution through No. two motors, a transmission shaft synchronous drive conveyer belt synchronous motion, No. two transmission shaft synchronous motion of conveyer belt synchronous drive, the conveyer belt carries components and parts, No. two transmission shaft synchronous drive a gear synchronous motion, No. two gears drive No. two gear motion through the meshing synchronization, No. two gear synchronous drive plectanes synchronous revolution, the plectane drives channel plate motion through the transmission post synchronous drive channel plate, the.

As a preferred technical scheme of the invention, the clamping mechanism comprises a U-shaped clamp, a clamping plate, a bidirectional cylinder, a telescopic rod, a rectangular transmission plate, a rectangular dividing plate, a guide pillar, a round shaft, a transmission rod, a push block and a push plate, wherein the U-shaped clamp is arranged on the right end face of a guide plate, the clamping plate is symmetrically arranged in the U-shaped clamp from top to bottom, the clamping plate is connected with a rectangular groove in a sliding fit manner, the rectangular groove is formed in the right end of the inner wall of the U-shaped clamp, a mold plate is arranged at the inner side end of the clamping plate, the lower end faces of the clamping plates are connected through the bidirectional cylinder, the telescopic rod is arranged on the clamping plate through a sleeve plate arranged on the left end face of the inner wall of the clamping plate, the sleeve plate is sleeved on a cylinder body of the bidirectional cylinder, the telescopic rod is connected with a rectangular groove in a sliding fit manner, the rectangular, the rectangular driving plate is positioned on the U-shaped die groove, the U-shaped die groove is formed in the lower end face of the die plate, the U-shaped die grooves are uniformly distributed from front to back, the right end of the rectangular driving plate is provided with a rectangular sub-plate, the right end face of the rectangular sub-plate is provided with guide columns, the guide columns are equidistantly distributed from front to back, the right end of each guide column is provided with a circular shaft, the circular shaft is symmetrically provided with a transmission rod from front to back, the transmission rod is connected with one end of a push block through a circular pin, the other end of the push block is provided with a push plate, the push plate is connected with the U-shaped die groove through a sliding fit mode, the clamping plate is synchronously driven to move through a bidirectional air cylinder, the clamping plate synchronously drives the die plate to clamp, when the telescopic rod is clamped into the rectangular groove, the telescopic rod extends out to push the rectangular driving plate to move rightwards, the transfer rod synchronously pushes the push block to move towards two sides, and the push block synchronously pushes the push plate to clamp the inserting legs of the components left and right, so that the inserting legs of the components are flat when the components are used.

According to a preferred technical scheme, a brushing flat column is arranged above a female die conveyor belt and is positioned at the right end of a rectangular vertical through groove, a hairbrush is arranged on the lower end face of the brushing flat column, the upper end face of the brushing flat column is connected with the output end of a third motor, the third motor is arranged on the left end face of a support plate through a support plate, a rectangular baffle is arranged on the rear side of the hairbrush, the left end and the right end of the rectangular baffle are arranged on the inner side end face of a circular head plate, the brushing flat column is synchronously driven to move through the third motor, the hairbrush is synchronously driven to move by the brushing flat column, components on the female die conveyor belt are brushed into the female die groove by the hairbrush to be conveyed, and the components are prevented from being.

According to a preferred technical scheme, a rectangular groove is formed in the left end face of the support plate, an electric push rod is arranged in the rectangular groove, a pressing plate is mounted at the upper end of the electric push rod, a pressing block is mounted at the left end of the pressing plate and located on the right side of the rectangular through groove of the left round head plate, one end of the pressing plate is driven to move upwards through the electric push rod, the other end of the pressing plate moves downwards, and the pressing plate synchronously drives the pressing block to press components in the groove of the concave die, so that the components are prevented from tilting in the leveling process.

As a preferred technical scheme of the invention, the outer side end of the transfer rod is connected with one end of the buffer plate in a sliding fit mode, the other end of the buffer plate is provided with the compression spring, and the buffer plate plays a role in buffering the transfer rod and prevents the transfer rod from damaging the plug legs of the components due to overlarge thrust.

(II) advantageous effects

1. According to the electronic component production line, the step is added in the electronic component production line by adopting the smoothing device, so that the produced electronic component inserting legs are smoothed, the smoothing effect is achieved during smoothing, the electronic component inserting legs are protected from being damaged, and the use convenience of the electronic components is improved.

2. The flat brushing column drives the hairbrush to brush the produced electronic components into the die conveyor belt, and the hairbrush is matched with the rectangular baffle plate to prevent the electronic components from being directly conveyed out of the die conveyor belt;

3. the buffer board plays the biography effect of dashing to the biography pole, prevents that biography pole thrust from causing the injury to electronic components inserted leg.

Drawings

The invention is further illustrated with reference to the following figures and examples.

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

FIG. 2 is a cross-sectional view taken along line A of FIG. 1 in accordance with the present invention;

FIG. 3 is a cross-sectional view taken along line B of FIG. 1 in accordance with the present invention;

FIG. 4 is a perspective view of a component of the present invention;

FIG. 5 is an enlarged view of the invention taken along line C of FIG. 1;

FIG. 6 is an enlarged view of the invention taken from the D-side of FIG. 2;

FIG. 7 is an enlarged view of the invention taken from the E-direction of FIG. 3;

fig. 8 is an enlarged view of the invention in section F of fig. 6.

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways, which are defined and covered by the claims.

As shown in fig. 1 to 8, an electronic component production line comprises a bottom plate 1, a support plate 2, a die conveying device 3 and a smoothing device 4, wherein the bottom plate 1 is installed on the existing working floor, the support plate 2 is installed at the right end of the bottom plate 1, the die conveying device 3 is installed at the left end face of the support plate 2, and the smoothing device 4 is arranged at the left side of the die conveying device 3.

The left end face of mounting panel 2 seted up the rectangle recess, be provided with electric putter 20 in the rectangle recess, clamp plate 21 is installed to electric putter 20's upper end, briquetting 22 is installed to the left end of clamp plate 21, briquetting 22 is located the right side that the groove was led to left side round head board 34 rectangle, drives the one end upward movement of clamp plate 21 through electric putter 20, the other end of clamp plate 21 is then downstream, clamp plate 21 drives briquetting 22 in step and compresses tightly the components and parts of die inslot to avoid straightening the in-process components and parts perk.

The die conveying device 3 comprises a first rotating shaft 30, a first vertical plate 31, a die conveying belt 32, a second rotating shaft 33, a round head plate 34, a conveying mechanism 35 and a second vertical plate 36, one end of the first rotating shaft 30 is mounted on the support plate 2 through a first bearing, the other end of the first rotating shaft 30 is mounted on the right end face of the first vertical plate 31 through a second bearing, the die conveying belt 32 is mounted on the first rotating shaft 30, the rear end of the die conveying belt 32 is mounted on the second rotating shaft 33, the round head plate 34 is mounted between the first rotating shaft 30 and the second rotating shaft 33, the round head plates 34 are symmetrically mounted on two sides of the die conveying belt 32 in a left-right mode, a rectangular vertical through groove is formed in the left side of the round head plate 34, the conveying mechanism 35 is arranged on the left side of the rectangular vertical through groove, the conveying mechanism 35 is located on the rear side of the first vertical plate 31, the left end of the second rotating shaft 33 is mounted on the second vertical plate, the first rotating shaft 30 drives the female die conveyor belt 32 to transmit, the female die conveyor belt 32 drives the second rotating shaft 33 to rotate, the components entering the female die are conveyed, and the round head plate 34 prevents the components from sliding down in the conveying process.

The brush flat column 320 is arranged above the female die conveyor belt 32, the brush flat column 320 is located at the right end of the rectangular vertical through groove, a brush 321 is arranged on the lower end face of the brush flat column 320, the upper end face of the brush flat column 320 is connected with the output end of a third motor 322, the third motor 322 is arranged on the left end face of the support plate 2 through a support plate, a rectangular baffle 323 is arranged on the rear side of the brush 321, the left end and the right end of the rectangular baffle 323 are arranged on the inner side end face of the circular head plate 34, the brush flat column 320 is synchronously driven to move through the third motor 322, the brush flat column 320 synchronously drives the brush 321 to move, the brush 321 brushes components on the female die conveyor belt 32 into the female die groove for conveying, and the rectangular baffle 323 prevents the components from.

The conveying mechanism 35 comprises a second motor 350, a first transmission shaft 351, a support plate 352, a conveying belt 353, a second transmission shaft 354, a first gear 355, a second gear 356, a third transmission shaft 357, a circular plate 358, a transmission column 359 and a groove plate 35a, the second motor 350 is arranged on the upper end surface of the bottom plate 1 through a support, the first transmission shaft 351 is arranged at the output end of the second motor 350, the support plate 352 is symmetrically arranged in front and at the back of the first transmission shaft 351, the lower end surface of the support plate 352 is arranged on the upper end surface of the bottom plate 1, the conveying belt 353 is arranged on the first transmission shaft 351, the right end of the conveying belt 353 is connected with the second transmission shaft 354, the second transmission shaft 354 is arranged on the support plate 352, the first gear 355 is arranged at the front end of the second transmission shaft 354 in a penetrating mode through the support plate 352, the second gear 356 is arranged at the right end surface of the first gear 355, the first, an included angle between the first gear 355 and the second gear 356 is 90 degrees, a third transmission shaft 357 is installed on the right end face of the second gear 356, the third transmission shaft 357 penetrates through the support plate 2 and is provided with a circular plate 358, the circular plate 358 is located on the right side of the support plate 2, a transmission column 359 is installed on the left end face of the circular plate 358, a groove plate 35a is arranged at the left end of the transmission column 359, the transmission column 359 is connected with the groove plate 35a in a sliding fit manner, the groove plate 35a is installed on the right end face of the first rotating shaft 30, the first transmission shaft 351 is driven to synchronously rotate by the second motor 350, the first transmission shaft synchronously drives the conveyer belt 353 to synchronously move, the conveyer belt 353 synchronously drives the second transmission shaft 354 to synchronously move, the conveyer belt 353 carries out conveying on components, the second transmission shaft 354 synchronously drives the first gear 355 to synchronously move, the first gear 355 synchronously drives the second gear 356 to move by meshing, the second gear 356 synchronously, the circular plate 358 synchronously drives the slotted plate 35a to move through the transmission column 359, and the slotted plate 35a synchronously drives the first rotating shaft 30 to synchronously move.

The smoothing device 4 comprises an ear seat 40, a swing rod 41, a convex column 42, a rotating rod 43, a rotating shaft 44, a support 45, a first motor 46, a guide plate 47, a clamping mechanism 48, a support frame plate 49 and a die plate 4a, wherein the ear seat 40 is arranged on the upper end surface of the base plate 1, the ear seat 40 is positioned on the rear side of the conveying mechanism 35, the swing rod 41 is connected with the ear seat 40 through a pin shaft, a round-head through groove is formed in the swing rod 41, the convex column 42 is arranged in the round-head through groove, the convex column 42 is connected with the round-head through groove in a sliding fit mode, the rear end surface of the convex column 42 is connected with one end of the rotating rod 43, the rotating shaft 44 is arranged at the other end of the rotating rod 43, the rotating shaft 44 is arranged on the upper end surface of the base plate 1 through the support 45, the rotating shaft 44 penetrates through the support 45 and is connected with the output end of, the lower end of the clamping mechanism 48 is connected with the upper end face of the bottom plate 1 through a support frame plate 49, the mold plates 4a are symmetrically arranged in the clamping mechanism 48 from top to bottom, the right end of each mold plate 4a is connected with a rectangular through groove in a sliding fit mode, the rectangular through groove is formed in the left end face of the circular head plate 34, a motor 46 drives a rotating rod 43 to rotate, the rotating rod 43 synchronously drives a swing rod 41 to reciprocate from left to right through a convex column 42, the swing rod 41 synchronously drives a guide plate 47 to reciprocate from left to right, the guide plate 47 synchronously drives the clamping mechanism 48 to reciprocate from left to right on the upper end face of the support frame plate 49, meanwhile, the clamping mechanism 48 drives the mold plates 4a to clamp the component pins, and the mold plates 4a smooth the component pins so that the appearance of the component conveyed.

The clamping mechanism 48 comprises a U-shaped clamp 480, a clamping plate 481, a bidirectional air cylinder 482, an expansion link 483, a rectangular transmission plate 484, a rectangular sub-plate 485, a guide post 486, a round shaft 487, a transmission rod 488, a push block 489 and a push plate 48a, the U-shaped clamp 480 is installed on the right end face of a guide plate 47, the clamping plate 481 is symmetrically arranged on the upper and lower sides in the U-shaped clamp 480, the clamping plate 481 is connected with a rectangular groove in a sliding fit mode, the rectangular groove is formed in the right end of the inner wall of the U-shaped clamp 480, a mold plate 4a is installed on the inner side end of the clamping plate 481, the lower end faces of the clamping plate 481 are connected through the bidirectional air cylinder 482, an expansion link 483 is installed on the left end face of the inner wall of the clamping plate 481 through a sleeve plate, the expansion link 483 is installed on the clamping plate 481 through a sleeve plate, the sleeve plate is sleeved on the bidirectional air, the rectangular groove is internally provided with a rectangular transmission plate 484 in a sliding fit mode, the rectangular transmission plate 484 is positioned on a U-shaped die groove, the U-shaped die groove is arranged on the lower end face of a die plate 4a, the U-shaped die groove is uniformly distributed from front to back, the right end of the rectangular transmission plate 484 is provided with a rectangular sub-plate 485, the right end face of the rectangular sub-plate 485 is provided with guide posts 486, the guide posts 486 are equidistantly distributed from front to back, the right end of the guide posts 486 is provided with a circular shaft 487, the circular shaft 487 is symmetrically provided with transmission rods 488 from front to back, the transmission rods 488 are connected with one end of a push block 489 through circular pins, the other end of the push block 489 is provided with a push plate 48a, the push plate 48a is connected with the U-shaped die groove through a sliding fit mode, the clamping plate 481 is synchronously driven to move through a bidirectional air cylinder 482, the clamping plate synchronously drives the die plate 4a to clamp, when a, the rectangular transmission plate 484 synchronously pushes the rectangular sub-plate 485 to move rightwards, the rectangular sub-plate 485 synchronously pushes the guide post 486 to move rightwards, the guide post 486 synchronously pushes the transmission rod 488 to move rightwards through the round shaft 487, the transmission rod 488 synchronously pushes the push block 489 to move towards two sides, and the push block 489 synchronously pushes the push plate 48a to clamp the left and right of the component plug leg, so that the plug leg of the component is flat when the component is used.

The outside end of dowel 488 be connected with the one end of buffer plate 48b through sliding fit, compression spring 48c is installed to the other end of buffer plate 48b, buffer plate 48b plays the cushioning effect to dowel 488, prevents that the too big injury of component plug-in legs is received to dowel 488 thrust.

When the device is in operation, the second motor 350 drives the conveyer belt 353 to convey the devices, the second transmission shaft 354 synchronously drives the first gear 355 to synchronously move, the first gear 355 synchronously drives the second gear 356 to move through meshing, the second gear 356 synchronously drives the circular plate 358 to synchronously rotate, the circular plate 358 synchronously drives the groove plate 35a to move through the transmission column 359, the groove plate 35a synchronously drives the first rotating shaft 30 to synchronously move, the first rotating shaft 30 drives the die conveyer belt 32 to transmit, the die conveyer belt 32 drives the second rotating shaft 33 to rotate, the devices entering the die are conveyed and conveyed, meanwhile, the third motor 322 synchronously drives the brush flat column 320 to move, the brush flat column 320 synchronously drives the brush 321 to move, the brush 321 brushes the devices on the die conveyer belt 32 into the die grooves to convey, and the rectangular baffle 323 prevents the devices from being conveyed out without entering the die grooves, the circular head plate 34 prevents components from sliding off during transmission, then, the electric push rod 20 drives one end of the press plate 21 to move upwards, the other end of the press plate 21 moves downwards, the press plate 21 synchronously drives the press block 22 to press the components in the concave groove so as to prevent the components from tilting during smoothing, when the components are pressed, the guide plate 47 is driven by the motor 46 to reciprocate left and right, the guide plate 47 synchronously drives the clamping mechanism 48 to reciprocate left and right on the upper end face of the support frame plate 49, at the moment, the bidirectional cylinder 482 works to drive the clamping plate 481 to move, the clamping plate 481 synchronously drives the mold plate 4a to clamp, when the telescopic rod 483 is clamped in the rectangular groove, the telescopic rod 483 stretches out to push the rectangular transmission plate 484 to move rightwards, the rectangular transmission plate 484 synchronously pushes the transmission rod 488 to move rightwards, the transmission rod 488 synchronously pushes the push block 489 to move towards both sides, the push block 489 synchronously pushes the plate 48a to clamp the, the plug legs of the components are flat when the components are used, the buffer plate 48b has a buffer effect on the transfer bar 488, and the excessive thrust of the transfer bar 488 is prevented from damaging the plug legs of the components.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.