CN114367603A

CN114367603A - Efficient and adjustable diode pin cutting equipment

Info

Publication number: CN114367603A
Application number: CN202111670771.8A
Authority: CN
Inventors: 焦庆
Original assignee: Semtech Semiconductor Technology Dongguan Co Ltd
Current assignee: Semtech Semiconductor Technology Dongguan Co Ltd
Priority date: 2021-12-31
Filing date: 2021-12-31
Publication date: 2022-04-19
Anticipated expiration: 2041-12-31
Also published as: CN114367603B

Abstract

The invention provides efficient and adjustable diode pin cutting equipment which comprises an upper pressing assembly, a first lower pressing assembly, a second lower pressing assembly, a cutting assembly, a first material conveying belt structure, a second material conveying belt structure, a waste collecting assembly, a first finished product collecting assembly, a second finished product collecting assembly and a discharging conveying belt, wherein the upper pressing assembly is arranged on the upper pressing assembly; 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 LED lamp comprises a lamp body, a lamp holder and a lamp holder. 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.

Description

Efficient and adjustable diode pin cutting equipment

Technical Field

The invention relates to the technical field of diode processing, in particular to efficient and adjustable diode pin cutting equipment.

Background

The invention relates to the technical field of new energy processing equipment, in particular to an automatic pin cutting mechanism for a solar diode, which has the patent publication number of CN112366157A, and the patent name of the automatic pin cutting mechanism for the solar diode, wherein the automatic pin cutting mechanism for the solar diode can effectively improve the automation degree of diode processing work, simplify the processing mode, improve the processing speed, improve the working efficiency and save manpower by carrying out continuous pin cutting treatment on the diode one by one; including fixed frid, four groups landing legs and two sets of conveying axles, the bottom outside at fixed frid is evenly installed at the top of four groups landing legs, and two sets of conveying axles are longitudinal rotation respectively and are installed on the inner wall left side and the right side of fixed frid, and the front end of two sets of conveying axles all passes the preceding lateral wall of fixed frid and stretches out to the place ahead of fixed frid. According to the technology, the automatic pin cutting mechanism for the solar diode, which is used for processing the diode one by one, can effectively improve the automation degree of diode processing work, simplify the processing mode, improve the processing speed, improve the working efficiency, save labor, improve the length consistency after the diode processing is finished, effectively improve the production quality and improve the practicability and reliability. The defect that the working efficiency is low, the cutting can be carried out one by one each time, and the material conveying groove cannot be adjusted adaptively according to the size of a product model, so that the adaptability is low. In view of such circumstances, improvement is urgently required.

Disclosure of Invention

Therefore, the invention aims to provide the efficient and adjustable diode pin cutting equipment which can finish the pin cutting of diodes in batches, can be adaptively adjusted according to sizes of different models, and has high adaptability and high working efficiency.

The invention provides efficient and adjustable diode pin cutting equipment which comprises an upper pressing assembly, a first lower pressing assembly, a second lower pressing assembly, a cutting assembly, a first material conveying belt structure, a second material conveying belt structure, a waste collecting assembly, a first finished product collecting assembly, a second finished product collecting assembly and a discharging conveying belt, wherein the upper pressing assembly is arranged on the upper pressing assembly; the upper pressure assembly comprises a first lifting motor, a first lifting shaft, a first mounting plate, a first upper pressure plate and a second upper pressure plate, one end of the first lifting shaft is connected with the power output end of the first lifting motor, the other end of the first lifting shaft is connected with the first mounting plate, the first upper pressure plate is connected with the first mounting plate through a connecting rod, and the second upper pressure plate is connected with the first mounting plate through a connecting rod; the first lower pressing assembly is correspondingly arranged below the first upper pressing plate, and the second lower pressing assembly is correspondingly arranged below the second upper pressing plate; the cutting assembly is arranged below the first mounting plate and is positioned between the first upper pressing plate and the second upper pressing plate; the waste collecting assembly comprises a waste guide groove and a waste collecting box, wherein the waste guide groove is arranged right below the cutting assembly and is positioned between the first pressing assembly and the second pressing assembly; the waste collecting box is arranged below the waste guide groove and corresponds to the discharge hole of the waste guide groove; the first conveying belt structure is arranged close to the first lower pressing assembly and is positioned on one side far away from the waste guide groove; the second material conveying belt structure is arranged close to the second pressing component and is positioned on one side far away from the waste guide groove; the first finished product collecting assembly is arranged at one end of a discharge hole of the first material conveying belt structure; the second finished product collecting assembly is arranged at one end of a discharge hole of the second material conveying belt structure; the discharging conveying belt is arranged right below the waste guide groove and is positioned between the first finished product collecting assembly and the second finished product collecting assembly; 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 embedding grooves in a linear array along the length direction, elastic drawstring accommodating grooves are formed in the material conveying strip and below the diode embedding grooves, and elastic drawstrings are arranged in the elastic drawstring accommodating grooves; the bottom of the diode tabling groove is provided with strip-shaped holes communicated with the elastic drawstring accommodating groove, and the upper surface of the elastic drawstring is provided with a plurality of limiting blocks which penetrate through the strip-shaped holes and extend into the diode tabling groove in a linear array manner; the relative both sides of groove along its length direction are all accomodate to the elasticity stretching strap be provided with the waist type hole that the groove intercommunication was accomodate to the elasticity stretching strap, the both sides of elasticity stretching strap all through the bolt with waist type jogged joint.

As a preferred scheme, the outer side surfaces of the first upper pressing plate and the second upper pressing plate are respectively provided with a connecting plate right above the material conveying strips, and the lower surfaces of the connecting plates are connected with auxiliary pressing plates corresponding to the material conveying strips through buffer springs.

As preferred scheme, cutting assembly includes sharp slip table, die-cut motor, arbor, the cutter of falling the U-shaped, die-cut motor is installed on the slide of sharp slip table, the one end of arbor with the power take off end of die-cut motor is connected, the other end of arbor with the upper surface connection of the cutter of falling the U-shaped.

Preferably, the bottom of the inner cavity of the waste guide groove is inclined from high to low along the length direction of the inner cavity from the discharging conveying belt to one side of the waste collecting box.

As a preferable scheme, the first pressing component and the second pressing component both comprise a pressing block, a second lifting shaft, a second lifting motor and a second mounting plate, the second lifting motor is arranged on the second mounting plate, one end of the second lifting shaft is connected with a power output end of the second lifting motor, and the other end of the second lifting shaft is connected with the bottom of the pressing block; both sides the below of second mounting panel is provided with the regulating plate, first direction spout, two have all been seted up along its length direction's relative both sides to the regulating plate the bottom of second mounting panel all is provided with inserts the first lug of first direction spout, two the second mounting panel all through the bolt with the regulating plate is connected.

As a preferred scheme, the two connecting rods are connected with the first mounting plate through adjusting blocks, second guide sliding grooves are formed in the positions, corresponding to the adjusting blocks, of the bottom of the first mounting plate, and second convex blocks inserted into the second guide sliding grooves are arranged on the upper surface of each adjusting block; the adjusting block is connected with the first mounting plate through a bolt.

As preferred scheme, first defeated material band structure with one side that the second defeated material band structure is close to ejection of compact conveyer belt is provided with supplementary blanking structure, supplementary blanking structure includes electric telescopic handle, negative pressure gas is chewed, the negative pressure gas chew with electric telescopic handle's power take off end is connected, the negative pressure gas is chewed and is connected with the negative pressure air supply through the trachea.

Preferably, the first finished product collecting assembly and the second finished product collecting assembly respectively comprise a push-pull motor, a push-pull shaft, a push-pull plate and a collecting box, one end of the push-pull shaft is connected with a power output end of the push-pull motor, the other end of the push-pull shaft is connected with the push-pull plate, and the collecting box is arranged close to the push-pull plate and corresponds to the discharging conveying belt in position.

Preferably, the two opposite sides of the discharging conveying belt and the positions below the two collecting boxes are respectively provided with a first electronic scale.

Preferably, a second electronic scale is arranged below each waste collection box.

The invention has the beneficial effects that: the cutting assembly is arranged on the other side of the diode embedding groove, and the cutting assembly is used for cutting the diodes on the material conveying belt structure on the other side synchronously; the inner space of the diode tabling groove can be adjusted adaptively according to the sizes of different models, thereby improving the applicability of the structure and avoiding the corresponding replacement of the material conveying strip according to the model.

Drawings

Fig. 1 is a perspective view (from the view of the product outlet) of the present invention.

Fig. 2 is a side sectional view of a first or second conveyer belt structure.

Fig. 3 is an enlarged view at a of fig. 2.

Fig. 4 is a perspective view of the present invention (from the perspective of the waste gate).

Fig. 5 is a front view of the present invention.

Fig. 6 is a front view of the upper press assembly.

The reference signs are: a first lifting motor 10, a first lifting shaft 11, a connecting rod 12, a linear sliding table 13, a punching motor 14, a cutter shaft 15, a first upper press plate 16, a connecting plate 17, an auxiliary press plate 18, a buffer spring 19, an inverted U-shaped cutter 20, a first material conveying belt structure 21, a waste collecting box 22, a second electronic scale 23, an adjusting plate 24, a first guide chute 25, a second mounting plate 26, a waste guide groove 27, a second material conveying belt structure 28, an electric telescopic rod 30, a negative pressure air nozzle 29, a first finished product collecting component 31, a push-pull shaft 32, a push-pull plate 33, a collecting box 35, a first electronic scale 34, a discharge conveying belt 36, a diode embedding groove 37, a material conveying strip 38, an elastic pull belt accommodating groove 40, an elastic pull belt 39, a bolt 41, a waist-shaped hole 42, a strip-shaped hole 43, a push-pull motor 44, a limiting block 45, a cutting component 46, a lower press block 47, a second lifting shaft 48, a second lifting motor 49, an adjusting block 50, a waste adjusting block, The device comprises a first mounting plate 51, a second guide chute 52, a second lug 53, a second upper pressing plate 54, a second lower pressing assembly 55, a waste collecting assembly 56, an auxiliary blanking structure 57, an upper pressing assembly 58, a first lower pressing assembly 59, a second finished product collecting assembly 60 and a driving wheel 61.

Detailed Description

For further understanding of the features and technical means of the present invention, as well as the specific objects and functions attained by the present invention, the present invention will be described in further detail with reference to the accompanying drawings and detailed description.

Referring to fig. 1-6, an efficient and adjustable diode pin cutting device comprises an upper pressing assembly 58, a first lower pressing assembly 59, a second lower pressing assembly 55, a cutting assembly 46, a first conveying belt structure 21, a second conveying belt structure 28, a waste collecting assembly 56, a first finished product collecting assembly 31, a second finished product collecting assembly 60 and a discharging conveying belt 36, wherein the discharging conveying belt 36 is arranged right below a waste guide groove 27 and is positioned between the first finished product collecting assembly 31 and the second finished product collecting assembly 60. The upper pressing assembly 58, the first lower pressing assembly 59, the second lower pressing assembly 55, the cutting assembly 46, the first conveyor belt structure 21, the second conveyor belt structure 28, the waste collecting assembly 56, the first finished product collecting assembly 31, the second finished product collecting assembly 60 and the discharging conveyor belt 36 are all connected with the control system. The upper pressing assembly 58, the first lower pressing assembly 59, the second lower pressing assembly 55, the cutting assembly 46, the first conveyor belt structure 21, the second conveyor belt structure 28, the waste collecting assembly 56, the first finished product collecting assembly 31, the second finished product collecting assembly 60 and the discharging conveyor belt 36 are respectively and correspondingly mounted on the bracket (the drawing of the bracket is omitted in the technology).

The upper pressure assembly 58 comprises a first lifting motor 10, a first lifting shaft 11, a first mounting plate 51, a first upper pressure plate 16 and a second upper pressure plate 54, one end of the first lifting shaft 11 is connected with the power output end of the first lifting motor 10, the other end of the first lifting shaft 11 is connected with the first mounting plate 51, the first upper pressure plate 16 is connected with the first mounting plate 51 through a connecting rod 12, and the second upper pressure plate 54 is connected with the first mounting plate 51 through a connecting rod 12; the first hold-down assembly 59 is disposed below the first upper platen 16, and the second hold-down assembly 55 is disposed below the second upper platen 54. Connecting plates 17 are arranged on the outer side surfaces of the first upper pressing plate 16 and the second upper pressing plate 54 and located right above the material conveying strips 38, the lower surfaces of the connecting plates 17 are connected with auxiliary pressing plates 18 corresponding to the material conveying strips 38 through buffer springs 19, and after the first upper pressing plate 16 and the second upper pressing plate 54 are pressed downwards to the lower pressing blocks 47, the auxiliary pressing plates 18 correspondingly press the shells of the diodes, so that the situation that the cutting quality is influenced due to the fact that the diodes shake when being cut is further avoided. The two connecting rods 12 are connected with a first mounting plate 51 through adjusting blocks 50, second guide sliding grooves 52 are formed at the bottom of the first mounting plate 51 and at positions corresponding to the adjusting blocks 50, and second convex blocks 53 inserted into the second guide sliding grooves 52 are arranged on the upper surfaces of the adjusting blocks 50; the adjusting block 50 is connected to the first mounting plate 51 by bolts. With this arrangement, the relative positions of the first upper platen 16 and the second upper platen 54 can be finely adjusted according to the length of the leads to be cut.

The cutting assembly 46 is disposed below the first mounting plate 51 and between the first upper platen 16 and the second upper platen 54. The cutting assembly 46 comprises a linear sliding table 13, a punching motor 14, a cutter shaft 15 and an inverted U-shaped cutter 20, wherein the punching motor 14 is installed on a sliding seat of the linear sliding table 13, one end of the cutter shaft 15 is connected with a power output end of the punching motor 14, the other end of the cutter shaft 15 is connected with the upper surface of the inverted U-shaped cutter 20, and the linear sliding table 13 is installed on a support. In practical operation, the linear sliding table 13 drives the punching motor 14, the cutter shaft 15 and the inverted U-shaped cutter 20 to move back and forth between the first material conveying belt structure 21 and the second material conveying belt structure 28, so that the cutting operation of the diodes on the first material conveying belt structure 21 and the second material conveying belt structure 28 is realized.

The waste collection assembly 56 comprises a waste guide groove 27, the waste collection box 22, the waste guide groove 27 is arranged right below the cutting assembly 46 and between the first pressing-down assembly 59 and the second pressing-down assembly 55; the scrap collecting box 22 is disposed below the scrap chute 27 and corresponds to the discharge port of the scrap chute 27. The bottom of the waste chute 27 is sloped from high to low along its length from the outfeed conveyor belt 36 to the side of the waste collection bin 22. The pin waste material correspondence that cuts out falls into scrap chute 27 in, and the pin waste material slides down to scrap collecting box 22 along scrap chute 27 in, and scrap collecting box 22's below all is provided with second electronic scale 23, and second electronic scale 23 is connected with control system, and after the quantity display on second electronic scale 23 to the established weight of system, control system sent the warning instruction, lets the staff can in time change scrap collecting box 22.

The first conveyor belt structure 21 is arranged next to the first lower pressing component 59 and is positioned at the side far away from the waste guide groove 27; the second conveyor belt structure 28 is located adjacent the second hold-down assembly 55 and on a side remote from the waste chute 27. The first material conveying belt structure 21 and the second material conveying belt structure 28 both comprise material conveying strips 38 and a driving wheel 61, one end of the driving wheel 61 is connected with a driving motor, and the other end of the driving wheel 61 is connected with the material conveying strips 38, so that the material conveying strips 38 are driven to rotate; the upper surface and the lower surface of the material conveying strip 38 are provided with a plurality of diode embedding grooves 37 in a linear array along the length direction, an elastic drawstring accommodating groove 40 is arranged in the material conveying strip 38 and below the diode embedding grooves 37, and an elastic drawstring 39 is arranged in the elastic drawstring accommodating groove 40; the bottom of the diode tabling groove 37 is provided with strip-shaped holes 43 communicated with the elastic drawstring accommodating groove 40, and the upper surface of the elastic drawstring 39 is provided with a plurality of limiting blocks 45 which penetrate through the strip-shaped holes 43 and extend into the diode tabling groove 37 in a linear array manner; waist-shaped holes 42 communicated with the elastic drawstring accommodating grooves 40 are formed in the two opposite sides of the elastic drawstring accommodating grooves 40 in the length direction, and the two sides of the elastic drawstring 39 are connected with the waist-shaped holes 42 through bolts 41. In actual operation, the diodes are correspondingly arranged in the diode fitting grooves 37 for the cutting component 46 to cut. When the size of the diode tabling groove 37 needs to be adjusted, the bolts 41 on the two sides are loosened, the elastic drawstring 39 is slightly pulled leftwards or rightwards, so that the limiting block 45 adjusts the relative position in the diode tabling groove 37, and then the bolts 41 are screwed, so that the operation is simple and convenient, the diode tabling device is suitable for diodes of different models, and the applicability is high.

First defeated material band structure 21 and second defeated material band structure 28 are close to one side to ejection of compact conveyer belt 36 and are provided with supplementary blanking structure 57, and supplementary blanking structure 57 includes that electric telescopic handle 30, negative pressure gas chew 29, and the negative pressure gas is chewed 29 and is connected with electric telescopic handle 30's power take off end, and the negative pressure gas is chewed 29 and is connected with the negative pressure air supply through the trachea, and electric telescopic handle 30 installs on the support. After the cutting action is finished, the material conveying strip 38 rotates towards the direction of the finished product collecting assembly to carry out automatic blanking, under the normal condition, the diode automatically falls down in response to gravity, when the diode moves to the position of the auxiliary blanking structure 57, the diode does not fall down, the electric telescopic rod 30 drives the negative pressure air nozzle 29 to move to the position of the diode embedding groove 37 to adsorb the diode, and then the diode is put down. A photoelectric sensor connected with a control system is arranged on one side of the electric telescopic rod 30, and an auxiliary blanking structure 57 is connected with the control system.

The first finished product collecting assembly 31 is arranged at one end of a discharge hole of the first conveying belt structure 21; a second product collection assembly 60 is positioned at one end of the discharge opening of the second belt structure 28. The first finished product collecting assembly 31 and the second finished product collecting assembly 60 both comprise a push-pull motor 44, a push-pull shaft 32, a push-pull plate 33 and a collecting box 35, one end of the push-pull shaft 32 is connected with the power output end of the push-pull motor 44, the other end of the push-pull shaft 32 is connected with the push-pull plate 33, and the collecting box 35 is arranged adjacent to the push-pull plate 33 and corresponds to the discharging conveying belt 36 in position. First electronic scales 34 are arranged on two opposite sides of the discharging conveyor belt 36 and below the two collecting boxes 35. The first electronic scale 34 is connected to the control system. In operation, when the collection box 35 collects a predetermined weight of the system, the first electronic scale 34 feeds back information to the control system, and the control system sends out instructions to control the push-pull motor 44 to drive the push-pull plate 33 through the push-pull shaft 32 to push the collection box 35 to the position of the discharge conveyor belt 36.

The first pressing component 59 and the second pressing component 55 both comprise a pressing block 47, a second lifting shaft 48, a second lifting motor 49 and a second mounting plate 26, the second lifting motor 49 is arranged on the second mounting plate 26, one end of the second lifting shaft 48 is connected with the power output end of the second lifting motor 49, and the other end of the second lifting shaft 48 is connected with the bottom of the pressing block 47; the lower press block 47 is held on the same vertical plane as the inner side surfaces of the first upper press plate 16 and the second upper press plate 54. The relative height of the pressing block 47 can be adjusted by the second lifting motor 49 according to the requirement. An adjusting plate 24 is arranged below the second mounting plates 26 on the two sides, first guide sliding grooves 25 are formed in the two opposite sides of the adjusting plate 24 along the length direction of the adjusting plate, first protruding blocks inserted into the first guide sliding grooves 25 are arranged at the bottoms of the two second mounting plates 26, and the two second mounting plates 26 are connected with the adjusting plate 24 through bolts. With this arrangement, the relative position of the press block 47 can be finely adjusted according to the length of the lead to be cut.

In the embodiment, the first material conveying belt structure and the second material conveying belt structure are arranged, when cutting is carried out, diodes are placed in the diode embedding groove in batches, the diodes on the material conveying belt structure on one side are cut in batches through the cutting assembly, meanwhile, the material conveying belt structure on the other side can be synchronously fed, after the cutting action on one side is finished, the blanking and feeding actions can be started, meanwhile, the cutting assembly synchronously cuts the diodes on the material conveying belt structure on the other side, the operation is repeated, batch cutting can be carried out, the waiting time of the blanking and feeding actions is avoided, and the working efficiency is greatly improved; the inner space of the diode tabling groove can be adjusted adaptively according to the sizes of different models, thereby improving the applicability of the structure and avoiding the corresponding replacement of the material conveying strip according to the model.

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 foot equipment is cut out to high-efficient adjustable diode which characterized in that: the automatic material cutting device comprises an upper pressing assembly (58), a first lower pressing assembly (59), a second lower pressing assembly (55), a cutting assembly (46), a first material conveying belt structure (21), a second material conveying belt structure (28), a waste collecting assembly (56), a first finished product collecting assembly (31), a second finished product collecting assembly (60) and a discharging conveying belt (36);

the upper pressure assembly (58) comprises a first lifting motor (10), a first lifting shaft (11), a first mounting plate (51), a first upper pressure plate (16) and a second upper pressure plate (54), one end of the first lifting shaft (11) is connected with the power output end of the first lifting motor (10), the other end of the first lifting shaft (11) is connected with the first mounting plate (51), the first upper pressure plate (16) is connected with the first mounting plate (51) through a connecting rod (12), and the second upper pressure plate (54) is connected with the first mounting plate (51) through a connecting rod (12); the first lower pressing assembly (59) is correspondingly arranged below the first upper pressing plate (16), and the second lower pressing assembly (55) is correspondingly arranged below the second upper pressing plate (54);

the cutting assembly (46) is disposed below the first mounting plate (51) and between the first upper platen (16) and the second upper platen (54);

the waste collection assembly (56) comprises a waste guide groove (27), a waste collection box (22), the waste guide groove (27) is arranged right below the cutting assembly (46) and is positioned between the first pressing assembly (59) and the second pressing assembly (55); the waste collection box (22) is arranged below the waste guide groove (27) and corresponds to the discharge port of the waste guide groove (27);

the first material conveying belt structure (21) is arranged next to the first lower pressing assembly (59) and is positioned on the side far away from the waste guide groove (27); the second material conveying belt structure (28) is arranged next to the second pressing component (55) and is positioned on the side far away from the waste guide groove (27);

the first finished product collecting assembly (31) is arranged at one end of a discharge hole of the first material conveying belt structure (21); the second finished product collecting assembly (60) is arranged at one end of a discharge hole of the second conveying belt structure (28);

the discharge conveyor belt (36) is arranged right below the waste guide groove (27) and is positioned between the first finished product collecting assembly (31) and the second finished product collecting assembly (60);

the first material conveying belt structure (21) and the second material conveying belt structure (28) respectively comprise a material conveying strip (38) and a driving wheel (61), one end of the driving wheel (61) is connected with a driving motor, and the other end of the driving wheel (61) is connected with the material conveying strip (38); the upper surface and the lower surface of the material conveying strip (38) are provided with a plurality of diode embedding grooves (37) in a linear array along the length direction, elastic drawstring accommodating grooves (40) are arranged in the material conveying strip (38) and below the diode embedding grooves (37), and elastic drawstrings (39) are arranged in the elastic drawstring accommodating grooves (40); the bottom of the diode tabling groove (37) is provided with strip-shaped holes (43) communicated with the elastic drawstring accommodating groove (40), and the upper surface of the elastic drawstring (39) is provided with a plurality of limiting blocks (45) which penetrate through the strip-shaped holes (43) and extend into the diode tabling groove (37) in a linear array manner; the relative both sides of groove (40) are accomodate to the elasticity stretching strap along its length direction all be provided with waist type hole (42) that groove (40) intercommunication is accomodate to the elasticity stretching strap, the both sides of elasticity stretching strap (39) all through bolt (41) with waist type hole (42) are connected.

2. The efficient and adjustable diode pin cutting device as claimed in claim 1, wherein: and the outer side surfaces of the first upper pressing plate (16) and the second upper pressing plate (54) are respectively provided with a connecting plate (17) right above the material conveying strips (38), and the lower surface of each connecting plate (17) is connected with an auxiliary pressing plate (18) corresponding to the material conveying strips (38) through a buffer spring (19).

3. The efficient and adjustable diode pin cutting device as claimed in claim 1, wherein: cutting assembly (46) include sharp slip table (13), die-cut motor (14), arbor (15), the cutter of falling the U-shaped (20), die-cut motor (14) are installed on the slide of sharp slip table (13), the one end of arbor (15) with the power take off end of die-cut motor (14) is connected, the other end of arbor (15) with the upper surface connection of the cutter of falling the U-shaped (20).

4. The efficient and adjustable diode pin cutting device as claimed in claim 1, wherein: the bottom of the inner cavity of the waste guide groove (27) is inclined from high to low along the length direction from the discharging conveyor belt (36) to one side of the waste collection box (22).

5. The efficient and adjustable diode pin cutting device as claimed in claim 1, wherein: the first pressing component (59) and the second pressing component (55) respectively comprise a pressing block (47), a second lifting shaft (48), a second lifting motor (49) and a second mounting plate (26), the second lifting motor (49) is arranged on the second mounting plate (26), one end of the second lifting shaft (48) is connected with the power output end of the second lifting motor (49), and the other end of the second lifting shaft (48) is connected with the bottom of the pressing block (47); both sides the below of second mounting panel (26) is provided with regulating plate (24), first direction spout (25), two have all been seted up along its length direction's relative both sides in regulating plate (24 the bottom of second mounting panel (26) all is provided with inserts the first lug of first direction spout (25), two second mounting panel (26) all through the bolt with regulating plate (24) are connected.

6. The efficient and adjustable diode pin cutting device as claimed in claim 1, wherein: the two connecting rods (12) are connected with the first mounting plate (51) through adjusting blocks (50), second guide sliding grooves (52) are formed in positions, corresponding to the adjusting blocks (50), of the bottom of the first mounting plate (51), and second convex blocks (53) inserted into the second guide sliding grooves (52) are arranged on the upper surface of each adjusting block (50); the adjusting block (50) is connected with the first mounting plate (51) through a bolt.

7. The efficient and adjustable diode pin cutting device as claimed in claim 1, wherein: first defeated material band structure (21) with second defeated material band structure (28) are by being provided with supplementary blanking structure (57) to one side of ejection of compact conveyer belt (36), supplementary blanking structure (57) are chewed (29) including electric telescopic handle (30), negative pressure gas chew (29) with the power take off end of electric telescopic handle (30) is connected, negative pressure gas is chewed (29) and is connected with negative pressure air supply through the trachea.

8. The efficient and adjustable diode pin cutting device as claimed in claim 1, wherein: the first finished product collecting assembly (31) and the second finished product collecting assembly (60) respectively comprise a push-pull motor (44), a push-pull shaft (32), a push-pull plate (33) and a collecting box (35), one end of the push-pull shaft (32) is connected with the power output end of the push-pull motor (44), the other end of the push-pull shaft (32) is connected with the push-pull plate (33), and the collecting box (35) is arranged close to the push-pull plate (33) and corresponds to the discharging conveying belt (36) in position.

9. The efficient and adjustable diode pin cutting device as recited in claim 8, wherein: and first electronic scales (34) are arranged on two opposite sides of the discharging conveying belt (36) and below the two collecting boxes (35).

10. The efficient and adjustable diode pin cutting device as claimed in claim 1, wherein: and second electronic scales (23) are arranged below the waste collection boxes (22).