CN115351198A

CN115351198A - Prevent panel diode pin cutting equipment

Info

Publication number: CN115351198A
Application number: CN202211189878.5A
Authority: CN
Inventors: 付光远
Original assignee: Mutual Creation Dongguan Electronic Technology Co ltd
Current assignee: Mutual Creation Dongguan Electronic Technology Co ltd
Priority date: 2022-09-28
Filing date: 2022-09-28
Publication date: 2022-11-18

Abstract

The invention provides an anti-embedding diode pin cutting device which comprises a cutter assembly, an auxiliary pressing assembly and a waste collecting tank, wherein the auxiliary pressing assembly is arranged on the cutter assembly; the auxiliary pressing component is arranged on the two sides of the conveying component, and the auxiliary pressing component is arranged on the two sides of the conveying component; a plurality of lower diode embedding grooves are uniformly and linearly distributed on the upper surface of the positioning seat along the length direction of the positioning seat; the conveying assembly comprises a bearing plate, a lifting shaft, a lifting driving motor, a sliding block and a linear sliding table; auxiliary material ejecting structures are arranged on the bearing plates at the two sides; the auxiliary material ejecting structure comprises a push-pull driving motor, an L-shaped push-pull arm, a push-pull plate and a plurality of drop-shaped shifting blocks; the cutter assembly comprises a cutter, a driving shaft, a mounting plate and a stamping driving motor, and the auxiliary pressing assembly comprises an upper pressing plate mounting seat, an upper pressing block driving motor and a buffering upper pressing plate. Take supplementary liftout structure to the realization prevents the inlay material function, improves the efficiency of unloading.

Description

Prevent that inlay material diode pin cuts equipment

Technical Field

The invention relates to the technical field of diode processing, in particular to an anti-embedding diode pin cutting device.

Background

Chinese patent publication No. CN 114367603A, publication No. 2022, 04/19/2022, entitled a highly efficient and adjustable diode pin cutting device, which discloses the following technical contents: the automatic cutting device comprises an upper pressing assembly, a first lower pressing assembly, a second lower pressing assembly, a cutting assembly, a first conveying belt structure, a second conveying belt structure, a waste collecting assembly, a first finished product collecting assembly, a second finished product collecting assembly and a discharging conveying belt; the first material conveying belt structure and the second material conveying belt structure respectively comprise material conveying strips and a driving wheel, one end of the driving wheel is connected with a driving motor, and the other end of the driving wheel is connected with the material conveying strips; the upper surface and the lower surface of the material conveying strip are provided with a plurality of diode tabling grooves in a linear array along the length direction, an elastic drawstring accommodating groove is formed in the material conveying strip and located below the diode embedding groove, and an elastic drawstring is arranged in the elastic drawstring accommodating groove. The invention has the beneficial effects that: the cutting of the pins of the diodes can be completed in batches, and the adaptability can be adjusted according to the sizes of different models, so that the applicability is high, and the working efficiency is high. The prior art has the following defects: during the operation of cutting, the diode is that inseparable gomphosis is placed in diode gomphosis inslot, and in addition before cutting, thereby the supplementary clamp plate also can compress tightly the diode on the defeated material strip and avoid taking place to rock when cutting, leads to accomplishing the back of cutting, is difficult to break away from diode gomphosis groove during the diode ejection of compact, often needs the supplementary ejection of compact of staff, influences machining efficiency. In view of such circumstances, improvement is urgently required.

Disclosure of Invention

Based on the above, the invention aims to provide the anti-blocking diode pin cutting equipment which is provided with the auxiliary material ejecting structure, so that the anti-blocking function is realized, and the discharging efficiency is improved.

The invention provides an anti-embedding diode pin cutting device which comprises a cutter assembly, auxiliary pressing assemblies arranged on two opposite sides of the cutter assembly in the length direction, and a waste collecting tank arranged right below the cutter assembly; the auxiliary pressing component is arranged on the two sides of the conveying component, and the auxiliary pressing component is arranged on the two sides of the conveying component; a plurality of lower diode embedding grooves are uniformly and linearly distributed on the upper surface of the positioning seat along the length direction of the positioning seat; the conveying assembly comprises a bearing plate, a lifting shaft, a lifting driving motor, a sliding block and a linear sliding table, the sliding block is connected with the linear sliding table in a sliding mode, the lifting driving motor is installed on the sliding block, one end of the lifting shaft is connected with the power output end of the lifting driving motor, the other end of the lifting shaft is connected with the bottom of the bearing plate, and the positioning seat is correspondingly installed on the upper surface of the bearing plate; the length of the linear sliding table is set to be M, the length of the bearing plate is set to be N, and M is larger than 2N; auxiliary material ejecting structures are arranged on the bearing plates on the two sides; the auxiliary material ejecting structure comprises a push-pull driving motor, an L-shaped push-pull arm, a push-pull plate and a plurality of water-drop-shaped poking blocks, wherein the number of the water-drop-shaped poking blocks corresponds to that of the lower embedding grooves of the diodes; the push-pull driving motor is installed on the bearing plate, one end of the L-shaped push-pull arm is connected with the power output end of the push-pull driving motor, the other end of the L-shaped push-pull arm is connected with the middle of the push-pull plate, and one side face, far away from the push-pull driving motor, of the push-pull plate is in contact with the positioning seat; a plurality of positioning shafts with the quantity and the positions corresponding to the lower embedding grooves of the diodes are linearly and uniformly distributed on the lower portion, close to one side face of the push-pull driving motor, of the positioning seat, the bottom of each poking block extends downwards to be connected with a convex column, a plurality of jacks for the convex columns to be inserted are linearly and uniformly distributed in the push-pull plate along the length direction of the push-pull plate, and each positioning shaft penetrates through the poking block; when the push-pull driving motor drives the L-shaped push-pull arm to be in the maximum extending distance, the highest position of each poking block is lower than the lowest position of each diode lower embedding groove; when the push-pull driving motor drives the L-shaped push-pull arm to be at the minimum extending distance, the highest position of each poking block is higher than the lowest position of each diode lower embedding groove; lower positioning block mounting seats are arranged at positions of the waste collecting tank corresponding to the positioning seats at the two sides, and lower positioning blocks are movably mounted on the lower positioning block mounting seats at the two sides; a plurality of pin lower embedding grooves are uniformly distributed on the upper surfaces of the lower positioning blocks on the two sides along the length direction of the upper surfaces and at positions corresponding to the diode lower embedding grooves; a movable gap is formed between the lower surfaces of the lower positioning block mounting seats on the two sides and the upper surface of the bearing plate; the upper surfaces of the lower positioning blocks on the two sides are higher than the waste collecting tank; a cutting space is formed between the lower positioning blocks on the two sides; the cutter assembly comprises a cutter, a driving shaft, a mounting plate and a stamping driving motor, wherein the stamping driving motor is mounted on the mounting plate, one end of the driving shaft is connected with the power output end of the stamping driving motor, and the other end of the driving shaft is connected with the upper surface of the cutter; the auxiliary pressing assembly comprises an upper pressing plate mounting seat, an upper pressing block driving motor and a buffering upper pressing plate, the power output end of the upper pressing block driving motor is connected with the upper surface of the upper pressing plate mounting seat, the position, corresponding to the positioning seat, of the lower surface of the upper pressing plate mounting seat is connected with the buffering upper pressing plate through a spring, and an upper positioning block is arranged at the position, corresponding to the lower positioning block, of the lower surface of the upper pressing plate mounting seat; the distance between the lower locating piece of both sides sets up to A, the width of cutter sets up to B, both sides distance between the upper pressure plate mount pad sets up to D, both sides distance between the upper locating piece sets up to C, A = B = C = D.

Preferably, the upper surface of the lower positioning block mounting seat is provided with guide rail grooves along the length direction, and the lower surfaces of the lower positioning blocks on the two sides are provided with convex rails matched with the guide rail grooves.

According to the preferable scheme, a material leaking hole is formed in the bottom of the waste collecting tank, and a waste collecting tank corresponding to the material leaking hole is arranged below the waste collecting tank.

Preferably, a plurality of diode upper embedding grooves matched with the diode lower embedding grooves are uniformly distributed on the lower surfaces of the buffer upper pressing plates on the two sides along the length direction of the buffer upper pressing plates.

Preferably, a plurality of pin upper engaging grooves which are matched with the pin lower engaging grooves are uniformly formed in the lower surfaces of the upper positioning blocks at both sides along the length direction of the lower surfaces.

As the preferred scheme, the middle part of cutter lower surface with the position that the garbage collection groove corresponds is connected with the soft roller of silica gel perpendicularly through the connecting rod, the lateral surface of the soft roller of silica gel is provided with many soft adhesive tapes of fender bits along its length direction circumference is irregular.

The beneficial effects of the invention are as follows:

1. by arranging the auxiliary material ejecting structure, after the cutting action is finished, the upper pressure plate mounting seat is reset, and the auxiliary material ejecting structure ejects the diode positioned on the positioning seat, so that the diode is prevented from being tightly embedded into the lower embedding groove of the diode, a worker can take out the diode conveniently, and the efficiency is improved;

2. the diodes can be tightly positioned by arranging the matching of the lower diode embedding grooves and the upper diode embedding grooves and the matching of the lower pin embedding grooves and the upper pin embedding grooves, so that the cutting precision is ensured;

3. by arranging the soft silica gel roller, a plurality of soft scrap blocking rubber strips are irregularly arranged on the outer side surface of the soft silica gel roller along the length direction of the soft silica gel roller in the circumferential direction, so that the situation that the cut metal scraps splash to the opposite side to influence the cutting effect of the opposite side is avoided; the soft silica gel roller can stretch into the waste collecting tank to dredge the waste collecting tank, so that debris is prevented from staying on the surface of the waste collecting tank, and the blockage situation is also avoided;

4. guide rail grooves are formed in the upper surface of the lower positioning block mounting seat along the length direction of the upper surface, protruding rails matched with the guide rail grooves are formed in the lower surfaces of the two side lower positioning blocks, the lower positioning blocks are convenient to disassemble and clean, and the situation that scraps are accumulated in embedded grooves under pins to influence the cutting quality of the diodes is avoided.

Drawings

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

Fig. 2 is a front view of the present invention.

The reference signs are: the device comprises a lifting driving motor 14, a sliding block 13, a linear sliding table 10, a bearing plate 11, a positioning seat 12, a push-pull driving motor 16, an L-shaped push-pull arm 15, a push-pull plate 17, a convex column 18, a positioning shaft 19, a shifting block 20, a diode lower embedding groove 21, an upper pressing plate mounting seat 24, an upper pressing block driving motor 26, a buffering upper pressing plate 22, a diode upper embedding groove 23, an upper positioning block 25, a spring 27, a cutter 31, a driving shaft 29, a mounting plate 30, a stamping driving motor 28, a connecting rod 32, a silica gel soft roller 33, a pin lower embedding groove 34, a lower positioning block 35, a lower positioning block mounting seat 36, a waste collecting groove 37, a cutter assembly 39, an auxiliary pressing assembly 40, a scrap blocking soft rubber strip 38, a material leakage hole 41, an auxiliary material ejecting structure 42, a conveying assembly 43, a lifting shaft 44, a jack 45 and a waste collecting box 46.

Detailed Description

For a better understanding of the features and technical solutions of the present invention, as well as the specific objects and functions attained by the present invention, reference is made to the accompanying drawings and detailed description of the invention.

Referring to fig. 1-2, an anti-slug diode pin cutting apparatus includes a cutter assembly 39, auxiliary pressing assemblies 40 disposed at two opposite sides of the cutter assembly 39 in a length direction, and a waste collecting tank 37 disposed under the cutter assembly 39; the catch tank 37 is mounted on the table of the line by a support bar.

The device also comprises positioning seats 12 respectively arranged below the auxiliary pressing assemblies 40 at two sides and conveying assemblies 43 correspondingly arranged below the positioning seats 12 at the corresponding side; a plurality of diode lower embedding grooves 21 are uniformly and linearly distributed on the upper surface of the positioning seat 12 along the length direction;

the conveying assembly 43 comprises a bearing plate 11, a lifting shaft 44, a lifting driving motor 14, a sliding block 13 and a linear sliding table 10, the linear sliding table 10 is installed on a workbench of the assembly line, the sliding block 13 is connected with the linear sliding table 10 in a sliding manner, the lifting driving motor 14 is installed on the sliding block 13, one end of the lifting shaft 44 is connected with a power output end of the lifting driving motor 14, the other end of the lifting shaft 44 is connected with the bottom of the bearing plate 11, and the positioning seat 12 is correspondingly installed on the upper surface of the bearing plate 11; the length of the linear sliding table 10 is set to be M, the length of the bearing plate 11 is set to be N, and M is larger than 2N. In practical operation, the linear sliding table 10 drives the supporting plate 11, the lifting shaft 44 and the lifting driving motor 14 to move back and forth along the length direction of the linear sliding table 10 through the sliding block 13. The elevation driving motor 14 drives the supporting plate 11 to move up and down through the elevation shaft 44.

Auxiliary material ejecting structures 42 are arranged on the bearing plates 11 on the two sides; the auxiliary material ejecting structure 42 comprises a push-pull driving motor 16, an L-shaped push-pull arm 15, a push-pull plate 17 and a plurality of water-drop-shaped shifting blocks 20, wherein the number of the water-drop-shaped shifting blocks corresponds to that of the diode lower embedding grooves 21; the push-pull driving motor 16 is arranged on the bearing plate 11, one end of the L-shaped push-pull arm 15 is connected with the power output end of the push-pull driving motor 16, the other end of the L-shaped push-pull arm 15 is connected with the middle part of the push-pull plate 17, and one side surface of the push-pull plate 17 far away from the push-pull driving motor 16 is contacted with the positioning seat 12; a plurality of positioning shafts 19 with the number and the positions corresponding to the lower embedding grooves 21 of the diodes are linearly and uniformly distributed on the lower portion of one side surface of the positioning seat 12 close to the push-pull driving motor 16, the bottom of each poking block 20 is connected with a convex column 18 in a downward extending mode, a plurality of insertion holes 45 for the convex columns 18 to insert are linearly and uniformly distributed on the push-pull plate 17 along the length direction of the push-pull plate, and the width of each insertion hole 45 is larger than that of each convex column 18. Each positioning shaft 19 penetrates through the shifting block 20; in actual operation, the push-pull driving motor 16 causes the L-shaped push-pull arm 15 to drive the push-pull plate 17 to move back and forth in the length direction of the positioning seat 12, and the push-pull plate 17 synchronously drives the shifting block 20 to rotate at a predetermined angle with the positioning shaft 19 as a rotation supporting point. When the push-pull driving motor 16 causes the L-shaped push-pull arm 15 to be at the maximum extension distance, the highest position of each toggle block 20 is lower than the lowest position of each diode lower embedding groove 21; when the push-pull driving motor 16 causes the L-shaped push-pull arm 15 to be at the minimum extension distance, the highest position of each toggle block 20 is higher than the lowest position of each diode lower engagement groove 21, so that the diodes are jacked up. Through setting up supplementary liftout structure, after accomplishing the action of cutting, the top board mount pad resets, and supplementary liftout structure will be located the diode jack-up on the positioning seat to avoid the inseparable embedding of diode to take out the diode at diode lower gomphosis inslot, the staff of being convenient for, raise the efficiency.

Lower positioning block mounting seats 36 are respectively arranged at positions of the waste collecting tank 37 corresponding to the positioning seats 12 at the two sides, and lower positioning blocks 35 are movably mounted on the lower positioning block mounting seats 36 at the two sides; a plurality of pin lower embedding grooves 34 are uniformly distributed on the upper surfaces of the two side lower positioning blocks 35 along the length direction and at positions corresponding to the diode lower embedding grooves 21; a movable gap is formed between the lower surfaces of the lower positioning block mounting seats 36 on the two sides and the upper surface of the bearing plate 11; the upper surfaces of the lower positioning blocks 35 on the two sides are higher than the waste collecting tank 37; a cutting space is formed between the lower positioning blocks 35 at both sides.

The cutter assembly 39 comprises a cutter 31, a driving shaft 29, a mounting plate 30 and a stamping driving motor 28, the stamping driving motor 28 is mounted on the mounting plate 30, one end of the driving shaft 29 is connected with the power output end of the stamping driving motor 28, and the other end of the driving shaft 29 is connected with the upper surface of the cutter 31; the mounting plate 30 is fixedly mounted on a support of the production line. In actual operation, the punching driving motor 28 drives the cutter 31 to realize up-and-down position conversion through the driving shaft 29, thereby realizing cutting action.

The auxiliary pressing assembly 40 comprises an upper pressing plate mounting seat 24, an upper pressing block driving motor 26 and a buffering upper pressing plate 22, wherein the power output end of the upper pressing block driving motor 26 is connected with the upper surface of the upper pressing plate mounting seat 24, the position, corresponding to the positioning seat 12, of the lower surface of the upper pressing plate mounting seat 24 is connected with the buffering upper pressing plate 22 through a spring 27, and an upper positioning block 25 is arranged at the position, corresponding to the lower positioning block, of the lower surface of the upper pressing plate mounting seat 24; the upper press block driving motor 26 is installed on a bracket of the production line. In actual operation, the power output of upper press block driving motor 26 drives upper press plate mounting seat 24 to drive buffer upper press plate 22 to press down for a predetermined distance.

The distance between the lower positioning blocks on the two sides is set to be A, the width of the cutter is set to be B, the distance between the upper pressure plate mounting seats 24 on the two sides is set to be D, the distance between the positioning blocks on the two sides is set to be C, and A = B = C = D; through the structure, when the cutter is pressed downwards for cutting, cutting limit tracks of the cutter are formed between the upper pressure plate mounting seats 24, between the upper positioning blocks on two sides and between the lower positioning blocks on two sides, so that the cutter can be stably moved downwards for cutting, and the cutting quality is improved.

Guide rail grooves are formed in the upper surface of the lower positioning block mounting seat 36 along the length direction of the upper surface, and convex rails matched with the guide rail grooves are formed in the lower surfaces of the lower positioning blocks on the two sides. Through such structure setting, be convenient for dismantle cleanly to lower locating piece, avoid gathering the piece in the gomphosis inslot under the pin, influence the cutting quality of diode.

Material leakage hole 41 has been seted up to the tank bottom of catch tank 37, and catch tank 37's below is provided with catch tank 46 that corresponds with material leakage hole 41, through setting up catch tank, is convenient for regularly clear up the piece.

The lower surfaces of the buffer upper press plates 22 on both sides are uniformly provided with a plurality of upper diode fitting grooves 23 along the length direction thereof, which are matched with the lower diode fitting grooves 21.

The lower surfaces of the positioning blocks on the two sides are uniformly provided with a plurality of pin upper embedded grooves matched with the pin lower embedded grooves along the length direction.

The middle part of cutter lower surface and the position that the waste collecting vat 37 corresponds are connected with soft roller of silica gel 33 perpendicularly through connecting rod 32, and the lateral surface of the soft roller of silica gel 33 is provided with many soft adhesive tape 38 of fender bits along its length direction circumference is irregular. Through the structural arrangement, the situation that the cut metal scraps are splashed to the opposite side to influence the cutting effect of the opposite side is avoided; the soft roller of silica gel can stretch into in the garbage collection groove and dredge it to avoid the piece to stop in the groove face of garbage collection groove, also avoid appearing the condition of blockking up.

The operation steps of the embodiment are as follows:

1. the conveying assembly 43 drives the positioning seat 12 to move to one side of the loading and unloading for loading, after the loading is finished, the conveying assembly 43 drives the positioning seat 12 to move to a position corresponding to the cutter assembly 39, and the lifting drive motor 14 drives the bearing plate 11 to move downwards for a set distance, so that pins of the diode are correspondingly embedded into the lower pin embedding grooves 34;

2. the auxiliary pressing assembly 40 moves downwards for a set distance, so that the buffering upper pressing plate 22 is pressed on the upper surface of the positioning seat 12, and the upper positioning block 25 is pressed on the upper surface of the lower positioning block 35;

3. the cutter assembly 39 is pressed downwards to cut the diode pins on the two sides, and the cutting action is finished and then reset;

4. the lifting driving motor 14 drives the bearing plate 11 to move upwards for a set distance, so that pins of the diodes are correspondingly separated from the lower pin embedding grooves 34, the conveying assembly 43 drives the positioning seat 12 to move to one side of material loading and unloading, the auxiliary material jacking structure jacks up the diodes positioned on the positioning seat, and then the materials are unloaded;

5. and after the blanking is finished, feeding again, and continuing the steps.

The above-mentioned embodiments only express one embodiment of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. The utility model provides a prevent panel diode pin cutting tool which characterized in that: the automatic pressing device comprises a cutter component (39), auxiliary pressing components (40) arranged on two opposite sides of the cutter component (39) in the length direction, and a waste collecting tank (37) arranged right below the cutter component (39);

the auxiliary pressing assembly is characterized by further comprising positioning seats (12) which are respectively arranged below the auxiliary pressing assemblies (40) on the two sides, and conveying assemblies (43) which are correspondingly arranged below the positioning seats (12) on the corresponding side; a plurality of diode lower embedding grooves (21) are uniformly and linearly distributed on the upper surface of the positioning seat (12) along the length direction;

the conveying assembly (43) comprises a bearing plate (11), a lifting shaft (44), a lifting driving motor (14), a sliding block (13) and a linear sliding table (10), the sliding block (13) is connected with the linear sliding table (10) in a sliding mode, the lifting driving motor (14) is installed on the sliding block (13), one end of the lifting shaft (44) is connected with a power output end of the lifting driving motor (14), the other end of the lifting shaft (44) is connected with the bottom of the bearing plate (11), and the positioning seat (12) is correspondingly installed on the upper surface of the bearing plate (11); the length of the linear sliding table (10) is set to be M, the length of the bearing plate (11) is set to be N, and M is larger than 2N;

auxiliary material ejecting structures (42) are arranged on the bearing plates (11) on the two sides; the auxiliary material ejecting structure (42) comprises a push-pull driving motor (16), an L-shaped push-pull arm (15), a push-pull plate (17) and a plurality of water-drop-shaped shifting blocks (20) the number of which corresponds to that of the diode lower embedded grooves (21); the push-pull driving motor (16) is installed on the bearing plate (11), one end of the L-shaped push-pull arm (15) is connected with the power output end of the push-pull driving motor (16), the other end of the L-shaped push-pull arm (15) is connected with the middle of the push-pull plate (17), and one side face, far away from the push-pull driving motor (16), of the push-pull plate (17) is in contact with the positioning seat (12); a plurality of positioning shafts (19) with the number and the positions corresponding to the lower embedding grooves (21) of the diodes are linearly and uniformly distributed on the lower portion of one side face of the positioning seat (12) close to the push-pull driving motor (16), the bottom of each shifting block (20) is downwards extended and connected with a convex column (18), a plurality of insertion holes (45) for the convex columns (18) to be inserted are linearly and uniformly distributed on the push-pull plate (17) along the length direction of the push-pull plate, and each positioning shaft (19) penetrates through the shifting block (20); when the push-pull driving motor (16) causes the L-shaped push-pull arm (15) to be at the maximum extending distance, the highest position of each poking block (20) is lower than the lowest position of each diode lower embedding groove (21); when the push-pull driving motor (16) causes the L-shaped push-pull arm (15) to be at the minimum extending distance, the highest position of each shifting block (20) is higher than the lowest position of each diode lower embedding groove (21);

lower positioning block mounting seats (36) are respectively arranged at positions of the waste collecting tank (37) corresponding to the positioning seats (12) at the two sides, and lower positioning blocks (35) are respectively movably mounted on the lower positioning block mounting seats (36) at the two sides; a plurality of pin lower embedding grooves (34) are uniformly formed in the upper surfaces of the lower positioning blocks (35) on the two sides along the length direction of the upper surfaces and at positions corresponding to the diode lower embedding grooves (21); a movable gap is formed between the lower surfaces of the lower positioning block mounting seats (36) on the two sides and the upper surface of the bearing plate (11); the upper surfaces of the lower positioning blocks (35) on the two sides are higher than the waste collecting groove (37); a cutting space is formed between the lower positioning blocks (35) on the two sides;

the cutter assembly (39) comprises a cutter (31), a driving shaft (29), a mounting plate (30) and a stamping driving motor (28), the stamping driving motor (28) is mounted on the mounting plate (30), one end of the driving shaft (29) is connected with the power output end of the stamping driving motor (28), and the other end of the driving shaft (29) is connected with the upper surface of the cutter (31);

the auxiliary pressing assembly (40) comprises an upper pressing plate mounting seat (24), an upper pressing block driving motor (26) and a buffering upper pressing plate (22), wherein the power output end of the upper pressing block driving motor (26) is connected with the upper surface of the upper pressing plate mounting seat (24), the position, corresponding to the positioning seat (12), of the lower surface of the upper pressing plate mounting seat (24) is connected with the buffering upper pressing plate (22) through a spring (27), and an upper positioning block (25) is arranged at the position, corresponding to the lower positioning block, of the lower surface of the upper pressing plate mounting seat (24);

the distance between the lower locating blocks on the two sides is set to be A, the width of the cutter is set to be B, the distance between the upper pressure plate installing seats (24) on the two sides is set to be D, the distance between the upper locating blocks on the two sides is set to be C, and A = B = C = D.

2. The anti-slug diode pin singulation apparatus of claim 1, wherein: guide rail grooves are formed in the upper surface of the lower positioning block mounting seat (36) along the length direction of the upper surface, and convex rails matched with the guide rail grooves are formed in the lower surfaces of the lower positioning blocks on the two sides.

3. The anti-slug diode pin singulation apparatus of claim 1, wherein: a material leakage hole (41) is formed in the bottom of the waste collecting tank (37), and a waste collecting tank corresponding to the material leakage hole (41) is arranged below the waste collecting tank (37).

4. The anti-rule diode pin trimming apparatus of claim 1, characterized in that: the lower surfaces of the buffer upper pressing plates (22) at two sides are uniformly provided with a plurality of diode upper embedded grooves (23) matched with the diode lower embedded grooves (21) along the length direction.

5. The anti-slug diode pin singulation apparatus of claim 1, wherein: and a plurality of pin upper embedding grooves matched with the pin lower embedding grooves are uniformly distributed on the lower surfaces of the upper positioning blocks on the two sides along the length direction of the lower surfaces.

6. The anti-rule diode pin cutting apparatus of any one of claims 1-5, wherein: the middle part of cutter lower surface with the position that garbage collection groove (37) correspond is connected with soft roller of silica gel (33) through connecting rod (32) perpendicularly, the lateral surface of the soft roller of silica gel (33) is provided with many soft adhesive tape of fender bits (38) along its length direction circumference is irregular.