CN114210877A - Intelligent capacitor bending and cutting device for electronic component production and manufacturing - Google Patents

Abstract

The invention discloses an intelligent capacitor bending and cutting device for electronic component production and manufacturing, and relates to the technical field of electronic component production devices. According to the invention, through the mutual matching of the structures, the device has the effects of conveying the capacitors in batches at equal intervals, bending and cutting off the pins simultaneously, improving the production efficiency, along with high automation degree and no need of auxiliary operation of workers.

Description

Intelligent capacitor bending and cutting device for electronic component production and manufacturing

Technical Field

The invention relates to the technical field of electronic component production devices, in particular to an intelligent capacitance bending and cutting device for electronic component production and manufacturing.

Background

Generally, charges move under the action of force in an electric field, and when a medium exists between conductors, the charges are blocked from moving and accumulated on the conductors, so that the charges are accumulated and stored, and the amount of the stored charges is called as a capacitor.

In the production process of condenser, need bend and cut off the operation to two pins of electric capacity, traditional manufacturing procedure generally is workman manual operation, bends the back and breaks respectively to the pin, and the efficiency of this kind of mode is not high, can only bend alone and cut off the operation, and intensity of labour is too big, and is very inconvenient in the in-service use process.

Disclosure of Invention

The invention aims to provide an intelligent capacitor bending and cutting device for electronic component production and manufacturing, which has the effects of conveying capacitors in batches at equal intervals, bending and cutting off pins simultaneously, greatly improves the production efficiency, has high automation degree, does not need auxiliary operation of workers, and solves the problems that the traditional capacitor processing flow is generally manual operation of workers, the pins are respectively bent and then broken, the mode has low efficiency, only the bending and cutting off operations can be independently carried out, and the labor intensity is overlarge.

In order to achieve the purpose, the invention provides the following technical scheme: an intelligent capacitance bending and cutting device for electronic component production and manufacturing comprises a box body, wherein a discharge hole is formed in the surface of the box body, and a conveying pipe is fixedly connected to the upper end of the box body;

the inside fixed mounting of box has the conveyer belt, the top fixedly connected with mounting panel one and mounting panel two of box inner wall, the spout has been seted up on the surface of mounting panel two, the inner wall sliding connection of spout has the slide, the last fixed surface of slide is connected with spring one, the top of spring one with the inner wall fixed connection of spout, two retractable of fixedly connected with respectively are bent the board and are cut the board in the bottom surface of slide, still include the drive retractable is bent the board and is carried out intermittent type formula with the cut board and reciprocate, right the electric capacity pin on conveyer belt surface is bent the first driver part who cuts off.

Optionally, the first driving component comprises a motor, a mounting groove is formed on the surface of the first mounting plate, the motor is fixedly connected with the first mounting plate through a mounting groove, the end part of the output shaft of the motor is fixedly connected with a rotating plate, an output shaft is rotationally connected with the end part of the rotating plate in a fixed shaft way, a first gear is fixedly connected with a shaft arm of the output shaft, a second gear is meshed with the surface of the first gear, a ring body is fixedly and rotatably connected with the surface of the second gear, the end part of the output shaft is fixedly connected with a connecting plate, the bottom surface of the connecting plate is fixedly connected with the surface of the ring body, an opening is arranged on the surface of the second gear in a penetrating way, the second gear is fixedly connected with a limiting column through the opening, a first limiting groove is formed in the surface of the first mounting plate, the surface of the first limiting column slides up and down along the inner wall of the first limiting groove, and a cylinder is fixedly connected to the eccentric position of the second surface of the gear.

Optionally, the device further comprises a second driving component for driving the conveying belt to operate intermittently and carrying out intermittent distance transmission on the capacitance on the surface of the conveying belt.

Optionally, the second driving part includes the friction pulley, the fixed surface of friction pulley is connected with the rotary column, the armshaft dead axle of rotary column rotates and is connected with the panel, the tip of spacing post with the dead axle of surface of panel rotates and is connected, the rotary column with spacing post passes through gear drive assembly transmission and is connected.

Optionally, the device further comprises a feeding component for placing the capacitors equidistantly on the surface of the conveyor belt for conveying.

Optionally, the feeding component comprises a limiting sleeve, the limiting sleeve is fixedly connected to the surface of the first mounting plate, the inner wall of the limiting sleeve is connected with a telescopic rod in a sliding way, the end part of the telescopic rod is fixedly connected with a transverse moving plate, the surface of the transverse moving plate is provided with a second limit groove, the shaft arm dead axle of the cylinder body is rotationally connected with a sliding sleeve, the surface of the sliding sleeve slides along the inner wall of the second limit groove, the surface of the material conveying pipe is sleeved with a sleeve in a sliding manner, the back side of the sleeve is provided with a first inclined groove, the end part of the telescopic rod is abutted against the top of the inner wall of the first inclined groove, the inner wall of the limiting sleeve is provided with a second inclined groove, the inner wall of the second inclined groove is connected with a moving block in a sliding manner, a through groove is arranged on the surface of the material conveying pipe, the surface of the moving block slides along the inner wall of the through groove, the inner wall of the moving block is connected with a resisting block in a sliding mode, and the surface of the resisting block and the inner wall of the moving block are fixedly connected with a second spring.

Optionally, the top of the conveying pipe is fixedly connected with a storage bin.

Optionally, the retractable bending plate and the cutting plate are located right above the conveying belt.

Compared with the prior art, the invention has the following beneficial effects:

firstly, the capacitors are intensively poured into the storage bin by an operator, so that the capacitors can fall into the conveying pipe in a specific state, the abutting block abuts against the surface of the capacitors under the action of the elastic force of the second spring, the capacitors in the abutting state cannot fall off, the capacitors accumulated above the abutting block cannot fall off, the capacitors are placed on the surface of the conveying belt at equal intervals through the feeding part, the capacitors are intermittently conveyed through the second driving part, and the capacitors are output and collected through the discharge port after being processed.

And secondly, under the transmission fit of the first gear, the second gear, the telescopic bending plate and the cutting plate intermittently move downwards, and the capacitor pins at the bottom of the telescopic bending plate and the cutting plate are respectively bent and cut, so that the capacitor pins can be simultaneously bent and cut, and the processing efficiency is higher.

And when the friction wheel moves to the bottommost part and is contacted with the conveying belt, the upper surface of the conveying belt is driven to transmit to the right side, so that the capacitor transmitted on the surface of the conveying belt moves to a position right below the telescopic bending plate and the cutting plate, the subsequent processing operation is convenient, the device is more intelligent, and the processing efficiency is higher.

And fourthly, under the transmission matching of the second gear and the column body, the automatic equidistant material conveying process of the capacitor can be realized, and the labor intensity of workers is greatly reduced.

Drawings

FIG. 1 is an isometric view of a structure of the present invention;

FIG. 2 is a front cross-sectional view of the structure of the present invention;

FIG. 3 is a schematic view of the structure of the present invention in motion;

FIG. 4 is a rear cross-sectional view of the structure of the present invention;

FIG. 5 is an enlarged view of a portion of the structure of FIG. 2 in accordance with the present invention;

FIG. 6 is a front cross-sectional view of the structure of FIG. 5 in accordance with the present invention;

FIG. 7 is a right side cross-sectional view of a portion of the structure of FIG. 6 in accordance with the present invention;

FIG. 8 is a rear view of a portion of the structure of FIG. 5 in accordance with the present invention;

FIG. 9 is an enlarged view of the structure of FIG. 3 at A in accordance with the present invention;

fig. 10 is an enlarged view of the structure of fig. 2 at B according to the present invention.

In the figure: 1. a box body; 2. a discharge port; 4. a delivery pipe; 5. a conveyor belt; 6. a first mounting plate; 7. a second mounting plate; 8. a chute; 9. a slide plate; 10. a first spring; 11. a telescopic bending plate; 12. cutting the board; 13. a motor; 14. rotating the plate; 15. an output shaft; 16. a first gear; 17. a second gear; 18. a ring body; 19. a connecting plate; 20. a limiting column; 21. a first limiting groove; 22. a cylinder; 23. a friction wheel; 24. a limiting sleeve; 25. a telescopic rod; 26. transversely moving the plate; 27. a second limiting groove; 28. a sliding sleeve; 29. a sleeve; 30. a chute I; 31. a second chute; 32. a moving block; 33. a resisting block; 34. a second spring; 35. a storage bin; 36. turning the column; 37. a panel.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1 to 10, the present invention provides a technical solution: an intelligent capacitance bending and cutting device for electronic component production and manufacturing comprises a box body 1, a discharge hole 2 is formed in the surface of the box body 1, and a conveying pipe 4 is fixedly connected to the upper end of the box body 1.

The inner part of the box body 1 is fixedly provided with a conveying belt 5, the top part of the inner wall of the box body 1 is fixedly connected with a first mounting plate 6 and a second mounting plate 7, the surface of the second mounting plate 7 is provided with a chute 8, the inner wall of the chute 8 is connected with a sliding plate 9 in a sliding way, the upper surface of the sliding plate 9 is fixedly connected with a first spring 10, the top end of the first spring 10 is fixedly connected with the inner wall of the chute 8, the bottom surface of the sliding plate 9 is respectively and fixedly connected with two telescopic bending plates 11 and a cutting plate 12, the telescopic bending plates 11 are of a telescopic structure and can be realized by a spring structure, the device also comprises a first driving part for driving the telescopic bending plates 11 and the cutting plate 12 to intermittently move up and down, and a first driving part for bending and cutting off capacitor pins on the surface of the conveying belt 5, an operator firstly concentrates the capacitor in a storage bin 35 and enables the capacitor to fall into the conveying pipe 4 in a state that the pins face backwards, as shown in fig. 2 and fig. 10, at this time, the abutting block 33 abuts against the outer wall of the capacitor under the elastic force of the second spring 34, so that the capacitor in the abutting state cannot fall off, and the capacitor accumulated above the capacitor does not fall off, then the capacitors are placed on the surface of the conveying belt 5 at equal intervals through the feeding component for conveying, the retractable bending plate 11 and the cutting plate 12 intermittently move up and down through the first driving component, the capacitor pins on the surface of the conveying belt 5 are bent and cut off, and the production efficiency is greatly improved.

Further, the first driving part comprises a motor 13, a mounting groove is formed in the surface of the mounting plate I6, the motor 13 is fixedly connected with the mounting plate I6 through the mounting groove, a rotating plate 14 is fixedly connected to the end portion of an output shaft of the motor 13, an output shaft 15 is rotatably connected to the end portion of the rotating plate 14 in a fixed shaft manner, a first gear 16 is fixedly connected to a shaft arm of the output shaft 15, a second gear 17 is meshed with the surface of the first gear 16, a ring 18 is rotatably connected to the surface of the second gear 17 in a fixed shaft manner, a connecting plate 19 is fixedly connected to the end portion of the output shaft 15, the bottom surface of the connecting plate 19 is fixedly connected to the surface of the ring 18, an opening is formed in the surface of the second gear 17 in a penetrating manner, a limiting column 20 is fixedly connected to the second gear 17 through the opening, a first limiting groove 21 is formed in the surface of the mounting plate I6, the surface of the limiting column 20 slides up and down along the inner wall of the first limiting groove 21, and a column 22 is fixedly connected to the eccentric portion of the surface of the second gear 17, the motor 13 is started, the rotation of the output shaft of the motor 13 causes the rotation plate 14 to rotate counterclockwise as shown in fig. 6, the first gear 16 is driven by the output shaft 15 to do anticlockwise circular motion by taking the output shaft of the motor 13 as an axis, so that the second gear 17 rotates clockwise with the limit post 20 as the axis, and at this time, the second gear 17 continues to rotate clockwise, the cylinder 22 is driven to move down in a clockwise circular motion to abut against the sliding plate 9, and the first extension spring 10 is driven to move down, so that the retractable bending plate 11 and the cutting plate 12 move downwards, the bottom surface of the retractable bending plate 11 first contacts with the capacitor pins to bend the capacitor pins, the retractable bending plate 11 is extended and contracted with the continuous downward movement of the sliding plate 9, and then the cutting plate 12 is contacted with the capacitor pins to cut off, and the capacitor pins at the bottom of the cutting plate can be respectively bent and cut off through the process.

Further, the device comprises a second driving part for driving the conveying belt 5 to intermittently operate and intermittently convey the capacitance on the surface of the conveying belt at a fixed distance, wherein the second driving part comprises a friction wheel 23, a rotary column 36 is fixedly connected to the surface of the friction wheel 23, a panel 37 is rotatably connected to a shaft arm fixed shaft of the rotary column 36, the end part of the limiting column 20 is rotatably connected with the surface fixed shaft of the panel 37, the rotary column 36 is in transmission connection with the limiting column 20 through a gear transmission component, the limiting column 20 synchronously rotates in the rotation process of the first gear 16, the limiting column 20 rotates and drives the rotary column 36 to reversely rotate under the transmission of the gear transmission part, so that the friction wheel 23 rotates anticlockwise as shown in the state of figure 2, meanwhile, the second gear 17 is driven to vertically reciprocate under the limiting of the limiting column 20 through the anticlockwise circular motion process of the first gear 16 and the transmission of the ring body 18 and the connecting plate 19, the process of vertical reciprocating displacement of the second gear 17 drives the limiting column 20 to move up and down along the inner wall of the first limiting groove 21, as shown in fig. 2, the device is in the state shown in fig. 2, meanwhile, the cylinder 22 is positioned at the uppermost part and separated from the sliding plate 9, and moves to the bottommost part through the friction wheel 23 to be contacted with the conveying belt 5, so that the upper surface of the conveying belt 5 is driven towards the right side, the capacitor conveyed on the surface of the conveying belt is driven to move to the position under the telescopic bending plate 11 and the cutting plate 12, the friction wheel 23 is driven to move up and separated from the conveying belt 5 as the second gear 17 turns to move upwards, and the conveying belt 5 stops moving along with the second gear.

In order to realize the automatic equidistant material conveying process of the capacitor, the labor intensity of workers is greatly reduced, further, the device also comprises a material conveying component for conveying the capacitor equidistantly placed on the surface of the conveying belt 5, the material conveying component comprises a limiting sleeve 24, the limiting sleeve 24 is fixedly connected on the surface of the mounting plate I6, the inner wall of the limiting sleeve 24 is connected with a telescopic rod 25 in a sliding manner, the end part of the telescopic rod 25 is fixedly connected with a transverse moving plate 26, the surface of the transverse moving plate 26 is provided with a limiting groove II 27, a shaft arm fixed shaft of the column body 22 is rotatably connected with a sliding sleeve 28, the surface of the sliding sleeve 28 slides along the inner wall of the limiting groove II 27, the surface of the conveying pipe 4 is sleeved with a sleeve 29 in a sliding manner, the back side of the sleeve 29 is provided with a chute I30, the end part of the telescopic rod 25 is abutted against the top of the inner wall of the chute I30, the inner wall of the limiting sleeve 24 is provided with a chute II 31, and the inner wall of the chute II 31 is connected with a moving block 32 in a sliding manner, the surface of the conveying pipe 4 is provided with a through groove, the surface of the moving block 32 slides along the inner wall of the through groove, the inner wall of the moving block 32 is connected with a resisting block 33 in a sliding manner, the surface of the resisting block 33 and the inner wall of the moving block 32 are fixedly connected with a second spring 34, the sliding sleeve 28 synchronously moves to push the inner wall of the second limiting groove 27 through the process of clockwise circular motion of the column 22, the telescopic rod 25 is driven to transversely reciprocate under the limiting action of the limiting sleeve 24, the end part of the telescopic rod 25 is driven to push the groove wall of the first chute 30 through the transverse reciprocating displacement process of the telescopic rod 25, the sleeve 29 vertically reciprocates along the surface of the conveying pipe 4, when the sleeve 29 moves to the highest point along the surface of the conveying pipe 4, as shown in the state of fig. 9, the moving block 32 is clamped on the inner wall of the second chute 31, the second spring 34 is in a relaxed state, and the electric capacity at the bottommost in the conveying pipe 4 drops downwards to the surface of the conveying belt 5, at this time, as the sleeve 29 moves downwards, the second inclined groove 31 pushes the moving block 32 to move horizontally towards the right side, so that the second spring 34 is extruded, the abutting block 33 is driven to abut against the capacitor located at the lowest position at this time, the capacitor at the upper side stops dropping, the automatic equidistant material conveying process of the capacitor can be realized by repeating the processes, and the labor intensity of workers is greatly reduced.

In order to facilitate the centralized material conveying of the capacitor, a storage bin 35 is fixedly connected to the top of the material conveying pipe 4.

In order to enable the telescopic bending plate 11 and the cutting plate 12 to process the capacitor, further, the telescopic bending plate 11 and the cutting plate 12 are located right above the conveying belt 5.

The working principle is as follows: when the intelligent capacitor bending and cutting device for manufacturing electronic components is used, an operator firstly pours capacitors into the storage bin 35 in a centralized manner, so that the capacitors fall into the conveying pipe 4 in a state that pins face backwards, as shown in the states of fig. 2 and 10, the abutting block 33 abuts against the surface of the capacitors under the elastic force of the second spring 34, the capacitors in the abutting state cannot fall off, the capacitors stacked above the capacitors do not fall off, and the capacitors are placed on the surface of the conveying belt 5 at equal intervals through the feeding part for conveying.

Starting the motor 13, rotating the output shaft of the motor 13 to make the rotating plate 14 rotate counterclockwise as shown in fig. 6, making the first gear 16 perform counterclockwise circular motion by taking the output shaft of the motor 13 as the axis under the transmission of the output shaft 15, thereby driving the second gear 17 to rotate clockwise by taking the limiting post 20 as the axis, rotating the limiting post 20 synchronously, rotating the limiting post 20 and making the rotating post 36 perform reverse rotation under the transmission of the gear transmission part, further making the friction wheel 23 rotate counterclockwise as shown in fig. 2, meanwhile making the second gear 17 perform vertical reciprocating displacement under the limiting of the limiting post 20 under the transmission of the ring body 18 and the connecting plate 19 through the process of the counterclockwise circular motion of the first gear 16, making the second gear 17 perform vertical reciprocating displacement through the transmission of the ring body 18 and the connecting plate 19, making the process of the vertical reciprocating displacement of the second gear 17 make the limiting post 20 move up and down along the inner wall of the first limiting groove 21, as shown in fig. 2 moving to the state shown in fig. 3, when the device is in a state shown in fig. 2, at this time, the cylinder 22 is at the uppermost position and separated from the sliding plate 9, and the friction wheel 23 moves to the bottommost position and contacts with the conveying belt 5, so as to drive the upper surface of the conveying belt 5 to transmit towards the right side, so that the capacitor conveyed on the surface moves to a position right below the retractable bending plate 11 and the cutting plate 12, and as the gear II 17 moves upwards, the friction wheel 23 is driven to move upwards and separate from the conveying belt 5, the conveying belt 5 stops moving, and as the gear II 17 continues to rotate clockwise, the cylinder 22 moves downwards in a clockwise circular motion to abut against the sliding plate 9, and pushes the first extension spring 10 to move downwards, so as to move downwards the retractable bending plate 11 and the cutting plate 12, the bottom surface of the retractable bending plate 11 first contacts with the capacitor pins to bend the capacitor pins, and as the sliding plate 9 continues to move downwards to extend and retract the retractable bending plate 11, so as to contact and cut off the capacitor pins, the capacitor pins at the bottom of the capacitor pins can be respectively bent and cut off through the process, the friction wheel 23 is driven to synchronously move downwards to be contacted with the conveying belt 5 again along with the downward movement of the follow-up gear II 17, the conveying belt 5 is driven to convey again, the cut capacitor pins are output from the discharge port 2 to be collected, the capacitors of the bent pins move to the position right below the cutting plate 12, and similarly, the capacitors of the back row which are not processed move to the position right below the telescopic bending plate 11 to carry out follow-up operation;

as shown in fig. 5, the sliding sleeve 28 is driven to synchronously move to push the inner wall of the second limiting groove 27 through the process of clockwise circular motion of the column 22, so that the telescopic rod 25 performs transverse reciprocating motion under the limiting of the limiting sleeve 24, through the process of transverse reciprocating motion of the telescopic rod 25, the end portion of the telescopic rod 25 pushes the groove wall of the chute one 30 to drive the sleeve 29 to perform vertical reciprocating motion along the surface of the conveying pipe 4, when the sleeve 29 moves to the highest position along the surface of the conveying pipe 4, as shown in fig. 9, the moving block 32 is clamped in the chute two 31 at the moment, the spring two 34 is in a relaxed state, the capacitor at the bottommost part in the conveying pipe 4 falls down to the surface of the conveying belt 5, and as the sleeve 29 turns to move downwards, the chute two 31 pushes the moving block 32 to move towards the right side to press the spring two 34, so that the abutting block 33 abuts against the capacitor at the bottommost part at the moment to stop the falling of the capacitor at the upper side, the process is repeated, the automatic equidistant material conveying process of the capacitor can be realized, and the labor intensity of workers is greatly reduced.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides an intelligent electric capacity cutting device that bends of electronic components manufacturing usefulness, includes box (1), its characterized in that: a discharge hole (2) is formed in the surface of the box body (1), and a feed delivery pipe (4) is fixedly connected to the upper end of the box body (1);

the inside fixed mounting of box (1) has conveyer belt (5), the top fixedly connected with mounting panel (6) and mounting panel two (7) of box (1) inner wall, spout (8) have been seted up on the surface of mounting panel two (7), the inner wall sliding connection of spout (8) has slide (9), the last fixed surface of slide (9) is connected with spring (10), the top of spring (10) with the inner wall fixed connection of spout (8), two retractable of bottom surface difference fixedly connected with of slide (9) bend board (11) and cutting board (12), still including the drive retractable bends board (11) and cutting board (12) and carries out the intermittent type and reciprocates, right the electric capacity pin on conveyer belt (5) surface bends the first driver part who cuts off.

2. The intelligent capacitance bending and cutting device for manufacturing electronic components as claimed in claim 1, wherein: the first driving part comprises a motor (13), a mounting groove is formed in the surface of the first mounting plate (6), the motor (13) is fixedly connected with the first mounting plate (6) through the mounting groove, a rotating plate (14) is fixedly connected to the end portion of an output shaft of the motor (13), an output shaft (15) is rotatably connected to the end portion of the rotating plate (14) in a fixed shaft mode, a first gear (16) is fixedly connected to a shaft arm of the output shaft (15), a second gear (17) is meshed to the surface of the first gear (16), a ring body (18) is rotatably connected to the surface portion of the second gear (17) in a fixed shaft mode, a connecting plate (19) is fixedly connected to the end portion of the output shaft (15), the bottom surface of the connecting plate (19) is fixedly connected with the surface of the ring body (18), an opening is formed in the surface of the second gear (17) in a penetrating mode, and a limiting column (20) is fixedly connected to the second gear (17) through the opening, spacing groove (21) have been seted up on the surface of mounting panel (6), the surface of spacing post (20) is followed slide from top to bottom on the inner wall of spacing groove (21), eccentric department fixedly connected with cylinder (22) on gear two (17) surface.

3. The intelligent capacitance bending and cutting device for manufacturing electronic components as claimed in claim 2, wherein: the device also comprises a second driving component which drives the conveying belt (5) to operate intermittently and carries out intermittent distance transmission on the capacitance on the surface of the conveying belt.

4. An intelligent capacitance bending and cutting device for manufacturing electronic components as claimed in claim 3, wherein: the second driving part comprises a friction wheel (23), the surface of the friction wheel (23) is fixedly connected with a rotary column (36), a shaft arm fixed shaft of the rotary column (36) is rotatably connected with a panel (37), the end part of the limiting column (20) is rotatably connected with the surface fixed shaft of the panel (37), and the rotary column (36) is in transmission connection with the limiting column (20) through a gear transmission assembly.

5. An intelligent capacitance bending and cutting device for manufacturing electronic components as claimed in claim 2 or 3, wherein: the device also comprises a feeding component for conveying capacitors equidistantly arranged on the surface of the conveying belt (5).

6. The intelligent capacitance bending and cutting device for manufacturing electronic components as claimed in claim 5, wherein: the feeding part comprises a limiting sleeve (24), the limiting sleeve (24) is fixedly connected to the surface of the first mounting plate (6), an inner wall of the limiting sleeve (24) is connected with a telescopic rod (25) in a sliding mode, the end portion of the telescopic rod (25) is fixedly connected with a transverse moving plate (26), a limiting groove II (27) is formed in the surface of the transverse moving plate (26), a shaft arm of the column body (22) is connected with a sliding sleeve (28) in a fixed-shaft rotating mode, the surface of the sliding sleeve (28) slides along the inner wall of the limiting groove II (27), a sleeve (29) is sleeved in the surface sliding mode of the conveying pipe (4), a chute I (30) is formed in the back side of the sleeve (29), the end portion of the telescopic rod (25) is abutted to the top of the inner wall of the chute I (30), a chute II (31) is formed in the inner wall of the limiting sleeve (24), and a moving block (32) is connected to the inner wall of the chute II (31) in a sliding mode, the surface of the conveying pipe (4) is provided with a through groove, the surface of the moving block (32) slides along the inner wall of the through groove, the inner wall of the moving block (32) is connected with a resisting block (33) in a sliding mode, and the surface of the resisting block (33) and the inner wall of the moving block (32) are fixedly connected with a second spring (34) together.

7. The intelligent capacitance bending and cutting device for manufacturing electronic components as claimed in claim 1, wherein: the top of the conveying pipe (4) is fixedly connected with a storage bin (35).

8. The intelligent capacitance bending and cutting device for manufacturing electronic components as claimed in claim 1, wherein: the telescopic bending plate (11) and the cutting plate (12) are located right above the conveying belt (5).

Images