CN114229596A

CN114229596A - Processing system of copper-clad aluminum wire

Info

Publication number: CN114229596A
Application number: CN202111540950.XA
Authority: CN
Inventors: 孙嘉睿; 陈磊
Original assignee: Individual
Current assignee: Guangzhou Chuangluan Cable Technology Co ltd
Priority date: 2021-12-16
Filing date: 2021-12-16
Publication date: 2022-03-25
Anticipated expiration: 2041-12-16
Also published as: CN114229596B

Abstract

The invention relates to the technical field of electric wires and cables, in particular to a copper-clad aluminum wire processing system which comprises a base, wherein a stretching box is fixedly arranged on the base, a supporting plate is fixedly arranged on the top wall of the stretching box, a punching machine is fixedly arranged on the bottom wall of the supporting plate, a cutting knife is slidably arranged on an output shaft of the punching machine, two driving rollers are symmetrically arranged above the base, a conveying belt is wound on the two driving rollers together, a conducting wire is arranged on the conveying belt, an installation rod is fixedly arranged on the base, one of the driving rollers is rotatably arranged on the installation rod, a motor is fixedly arranged on the installation rod, and a main gear is fixedly arranged on an output shaft of the motor. According to the invention, the punch drives the push plate to replace the winding wheel on the winding roller, so that multiple times of machine halt is not required in a short time, and the winding wheel is replaced manually, thereby improving the working efficiency of the processing system of the copper-clad aluminum wire.

Description

Processing system of copper-clad aluminum wire

Technical Field

The invention relates to the technical field of electric wires and cables, in particular to a processing system of a copper-clad aluminum wire.

Background

The copper-clad aluminum wire is an electric wire which takes an aluminum core wire as a main body and is plated with a copper layer with a certain proportion on the outer surface, and can be used as a conductor for a coaxial cable and a conductor for an electric wire and a cable in electric equipment. The aluminum wire has small specific gravity, but the welding performance is not good, so the copper-clad aluminum wire can utilize the advantage of small specific gravity of aluminum and improve the welding performance by wrapping a copper layer outside the aluminum wire. The method is suitable for the industries of electric power and electric appliances, and the category grade is international and domestic.

Although the wire can be drawn and wound in the existing copper-clad aluminum wire processing process, the copper-clad aluminum wire needs to be wound after drawing processing, a winding wheel which is fully wound needs to be replaced when winding is completed, and a new winding wheel is placed to wind the copper-clad aluminum wire, so that continuous shutdown is needed, the winding wheel needs to be replaced manually, the manual labor burden is increased, a large amount of time is wasted, and the working efficiency of a copper-clad aluminum wire processing system is reduced.

Therefore, a processing system of the copper-clad aluminum wire is provided.

Disclosure of Invention

The invention aims to provide a processing system of a copper-clad aluminum wire, which is characterized in that a punch is used for driving a push plate to replace a winding wheel on a winding roller, so that multiple times of machine halt is not needed in a short time, and the winding wheel is manually replaced, so that the working efficiency of the processing system of the copper-clad aluminum wire is improved, and the problems in the background technology are solved.

In order to achieve the purpose, the invention provides the following technical scheme:

a processing system of copper-clad aluminum wires comprises a base, wherein a stretching box is fixedly installed on the base, a supporting plate is fixedly installed on the top wall of the stretching box, a punching machine is fixedly installed on the bottom wall of the supporting plate, a cutting knife is installed on an output shaft of the punching machine in a sliding mode, two transmission rollers are symmetrically installed above the base, a conveying belt is wound on the two transmission rollers together, a conducting wire is placed on the conveying belt, an installation rod is fixedly installed on the base, one of the transmission rollers is installed on the installation rod in a rotating mode, a motor is fixedly installed on the installation rod, a main gear is fixedly installed on an output shaft of the motor, a second connecting rod is fixedly installed on the bottom wall of the supporting plate, a winding roller is rotatably installed at one end of the second connecting rod, a plurality of winding wheels are installed on the winding roller in a sliding mode, and a winding area is arranged on the winding roller, one pot head of wind-up roll is equipped with the annular push pedal, fixedly connected with automatically promotes the pushing mechanism that the rolling wheel removed to the rolling district on the annular push pedal, be connected with on the master gear and be used for driving assembly of driving roller, wind-up roll and annular push pedal drive.

Preferably, pushing mechanism includes the head rod of fixed mounting on the backup pad diapire, the one end of head rod is rotated and is installed the first gear with master gear intermeshing, fixed mounting has first belt pulley in the axis of rotation of first gear, two reciprocal lead screws of symmetry fixedly connected with on the lateral wall of annular push pedal, two the one end of reciprocal lead screw all is overlapped and is equipped with two cylinders, and two cylinders and two reciprocal lead screws threaded transmission respectively are connected, reciprocal lead screw runs through the cylinder, two equal fixed mounting has the second belt pulley on the cylinder, around being equipped with first belt jointly on first belt pulley and two second belt pulleys, the one end of wind-up roll is rotated and is installed T type pole, and two cylinders rotate and install the both ends at T type pole.

Preferably, transmission assembly includes second connecting rod and the third connecting rod of fixed mounting on the backup pad diapire, the one end of second connecting rod is rotated and is installed the second gear with master gear intermeshing, the one end of third connecting rod is rotated and is installed the third gear with master gear intermeshing, fixed mounting has the third belt pulley in the axis of rotation of third gear, fixed mounting has the fourth belt pulley in the axis of rotation of driving roller, jointly around being equipped with the second belt on third belt pulley and the fourth belt pulley, fixed mounting has the T template on the base.

Preferably, fixed mounting has the stock on the base, the one end of stock is rotated and is installed the cam, fixed mounting fifth belt pulley on the cam, fixed mounting has the sixth belt pulley in the axis of rotation of second gear, wind jointly on fifth belt pulley and the sixth belt pulley and be equipped with the third belt.

Preferably, fixed mounting has the guide arm on the punching machine lateral wall, from left to right in the guide arm in proper order fixed mounting have first induction coil, second induction coil, third induction coil and fourth induction coil, fixedly connected with quarter butt on the diapire of backup pad, fixed mounting has first ring magnet on the bottom of quarter butt, and motor and first ring magnet electric connection, fixed mounting has the fixed plate on first ring magnet's the diapire, be fixed with second ring magnet, third ring magnet and fourth ring magnet on the fixed plate.

Preferably, two T type grooves, two have been seted up to the symmetry in the wind-up roll equal fixed mounting has two conductive spring, two on the diapire in T type groove equal slidable mounting has two baffles in the T type groove, and two baffles respectively with two conductive spring fixed connection, two the equal electric connection of conductive spring is on the fourth induction coil.

Preferably, an installation groove is formed in an output shaft of the punching machine, two connectors are symmetrically installed on the inner wall of the installation groove, a cutting knife used for connecting the two connectors is installed in the installation groove in a sliding mode, a glue sprayer is sleeved on the outer side wall of the output shaft of the punching machine, and the glue sprayer is electrically connected with the two connectors.

Preferably, a first electromagnetic hydrant is fixedly mounted on a rotating shaft of the first gear, a second electromagnetic hydrant is fixedly mounted on a rotating shaft of the second gear, a third electromagnetic hydrant is fixedly mounted on a rotating shaft of the third gear, the third electromagnetic hydrant, the second electromagnetic hydrant and the second induction coil are electrically connected, the third induction coil is electrically connected with the second electromagnetic hydrant, the first electromagnetic hydrant and the fourth induction coil are electrically connected, a first bidirectional switch is fixedly mounted on an inner top wall of the second annular magnet, a second bidirectional switch is fixedly mounted on an inner bottom wall of the second annular magnet, the first bidirectional switch is electrically connected with the second bidirectional switch, and the third induction coil and the fourth induction coil are electrically connected to the first bidirectional switch and the second bidirectional switch.

Preferably, first magnetic blocks are fixedly installed in the first electromagnetic hydrant, the second electromagnetic hydrant and the third electromagnetic hydrant, springs are fixedly connected to the outer side walls of the first magnetic block, the second electromagnetic hydrant and the third electromagnetic hydrant, inserting rods are slidably installed in the first electromagnetic hydrant, the second electromagnetic hydrant and the third electromagnetic hydrant, clamping grooves matched with the inserting rods are formed in the first gear, the second gear and the third gear, a second magnetic block is fixedly installed at one end of each inserting rod, and the second magnetic blocks are fixedly connected with one ends of the springs.

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

1. the rolling wheel on the rolling roller is replaced by the push plate driven by the punching machine, so that the rolling wheel is not required to be stopped for many times in a short time, and the rolling wheel is replaced by people, so that the working efficiency of a processing system of the copper-clad aluminum wire is improved.

2. The punching machine drives the conveying belt to rotate, so that the conveying belt does not need to be additionally driven to rotate, and the manufacturing and using cost of a processing system of the copper-clad aluminum wire is reduced.

3. The punching machine drives the glue sprayer to intermittently spray glue on the lead, so that the manufacturing and using cost of the processing system of the copper-clad aluminum wire is reduced.

Drawings

FIG. 1 is a schematic front view of the present invention;

FIG. 2 is a schematic view of the structure of the take-up roll portion of the present invention;

FIG. 3 is a schematic view of the second gear portion of the present invention;

FIG. 4 is a schematic view of a third gear portion of the present invention;

FIG. 5 is a perspective view of a second ring magnet according to the present invention;

FIG. 6 is a cross-sectional view of a first gear portion of the present invention;

FIG. 7 is a cross-sectional view of a second gear portion of the present invention;

FIG. 8 is a cross-sectional view of a third gear portion of the present invention;

FIG. 9 is an enlarged view of the structure of portion A of FIG. 1 in accordance with the present invention;

FIG. 10 is an enlarged view of portion B of FIG. 6 in accordance with the present invention;

FIG. 11 is an enlarged view of the structure of portion C of FIG. 2 according to the present invention;

FIG. 12 is an enlarged view of the structure of portion D of FIG. 7 in accordance with the present invention;

fig. 13 is an enlarged view of the structure of portion E of fig. 8 according to the present invention.

In the figure: 1. a base; 2. a stretching box; 3. a support plate; 4. a conveyor belt; 5. a driving roller; 6. a wire; 7. a punch press; 8. a cutting knife; 9. a first connecting rod; 10. a wind-up roll; 11. a winding wheel; 12. a ring-shaped push plate; 13. a cam; 14. a first gear; 15. a first pulley; 16. a reciprocating screw rod; 17. a drum; 18. a second pulley; 19. a first belt; 20. a guide bar; 21. a short bar; 22. a first ring magnet; 23. a fixing plate; 24. a second annular magnet; 25. a third ring magnet; 26. a fourth ring magnet; 27. mounting a rod; 28. a motor; 29. a main gear; 30. a second connecting rod; 31. a third connecting rod; 32. a second gear; 33. a third gear; 34. a third belt pulley; 35. a fourth belt pulley; 36. a second belt; 37. a T-shaped plate; 38. a long rod; 39. a fifth belt pulley; 40. a sixth belt pulley; 41. a third belt; 42. a T-shaped groove; 43. a conductive spring; 44. a baffle plate; 45. a glue sprayer; 46. a joint; 47. mounting grooves; 48. a first electromagnetic hydrant; 49. a second electromagnetic hydrant; 50. a third electromagnetic hydrant; 51. a first bidirectional switch; 52. a second bidirectional switch; 53. a first magnetic block; 54. a spring; 55. inserting a rod; 56. a second magnetic block; 57. t-shaped rod.

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.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, features defined as "first", "second", may explicitly or implicitly include one or more of the described features. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise. Furthermore, the terms "mounted," "connected," and "connected" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1 to 13, the present invention provides a copper-clad aluminum wire processing system, which has the following technical scheme:

a processing system of copper-clad aluminum wires comprises a base 1, a drawing box 2 is fixedly installed on the base 1, a supporting plate 3 is fixedly installed on the top wall of the drawing box 2, a punching machine 7 is fixedly installed on the bottom wall of the supporting plate 3, a cutting knife 8 is slidably installed on an output shaft of the punching machine 7, two transmission rollers 5 are symmetrically installed above the base 1, a conveying belt 4 is wound on the two transmission rollers 5 together, a wire 6 is placed on the conveying belt 4, an installation rod 27 is fixedly installed on the base 1, one of the transmission rollers 5 is rotatably installed on the installation rod 27, a motor 28 is fixedly installed on the installation rod 27, a main gear 29 is fixedly installed on the output shaft of the motor 28, a second connecting rod 30 is fixedly installed on the bottom wall of the supporting plate 3, a winding roller 10 is rotatably installed at one end of the second connecting rod 30, a plurality of winding wheels 11 are slidably installed on the winding roller 10, and a winding area is arranged on the winding roller 10, one end of the wind-up roll 10 is sleeved with an annular push plate 12, the annular push plate 12 is fixedly connected with a pushing mechanism which automatically pushes the wind-up wheel 11 to move to the wind-up area, and the main gear 29 is connected with a transmission component which is used for driving the transmission roller 5, the wind-up roll 10 and the annular push plate 12 to drive.

The punching machine 7 drives the cutting knife 8 to generate current when moving up and down, so that the driving motor 28 drives the main gear 29, the conveying belt 4 and the winding roller 10 are driven to wind the wires 6, after the wires 6 are cut by the cutting knife 8, the winding roller 10 is driven by the main gear 29 to wind the cut wires 6, after the winding is finished, the main gear 29 drives the pushing structure, the annular push plate 12 is driven to push the winding wheel 11 to move, the winding wheel 11 which is wound is made to fall, a new winding wheel 11 is made to move to a winding area to wind the other wires 6, the conveying belt 4 and the winding roller 10 are driven by the punching machine 7 to rotate, the manufacturing and using cost of a processing system of copper-clad aluminum wires is reduced, the winding wheel 11 on the winding roller 10 is replaced by the push plate driven by the punching machine 7, and therefore, multiple times of machine halt is not needed in a short time, the winding wheel 11 is manually replaced, so that the working efficiency of the processing system of the copper-clad aluminum wire is improved.

Referring to fig. 1, 2, 3 and 4, as an embodiment of the present invention, the pushing mechanism includes a first connecting rod 9 fixedly installed on the bottom wall of the supporting plate 3, a first gear 14 engaged with a main gear 29 is rotatably installed at one end of the first connecting rod 9, a first belt pulley 15 is fixedly installed on a rotating shaft of the first gear 14, two reciprocating screw rods 16 are symmetrically and fixedly connected to the outer side wall of the annular pushing plate 12, two rollers 17 are respectively sleeved at one end of each of the two reciprocating screw rods 16, and two cylinders 17 are in threaded transmission connection with two reciprocating screw rods 16 respectively, the reciprocating screw rods 16 penetrate through the cylinders 17, second belt pulleys 18 are fixedly mounted on the two cylinders 17, a first belt 19 is wound on the first belt pulley 15 and the two second belt pulleys 18 together, a T-shaped rod 57 is rotatably mounted at one end of the winding roller 10, and the two cylinders 17 are rotatably mounted at two ends of the T-shaped rod 57.

When the motor 28 drives the main gear 29 to rotate, the main gear 29 is meshed with the first gear 14, so that the main gear 29 can drive the first gear 14 to rotate, the first belt pulley 15 is driven to rotate after the first gear 14 rotates, the second belt pulley 18 is driven to rotate through the first belt 19, the roller 17 is driven to rotate after the second belt pulley 18 rotates, the reciprocating screw rod 16 is driven to rotate after the roller 17 rotates, the annular push plate 12 is driven to horizontally move through the rotation of the reciprocating screw rod 16, so that the winding wheel 11 falls off, the annular push plate 12 is driven to move through the motor 28, so that the winding wheel 11 on the winding roller 10 is automatically replaced, the machine does not need to stop for multiple times in a short time, the winding wheel 11 is manually replaced, and the working efficiency of a copper-clad aluminum wire processing system is improved.

Referring to fig. 1, 2, 3, 4, 7 and 8, the transmission assembly includes a second connecting rod 30 and a third connecting rod 31 fixedly mounted on the bottom wall of the supporting plate 3, one end of the second connecting rod 30 is rotatably mounted with a second gear 32 engaged with the main gear 29, one end of the third connecting rod 31 is rotatably mounted with a third gear 33 engaged with the main gear 29, a third belt pulley 34 is fixedly mounted on the rotating shaft of the third gear 33, a fourth belt pulley 35 is fixedly mounted on the rotating shaft of the transmission roller 5, a second belt 36 is wound around the third belt pulley 34 and the fourth belt pulley 35, and a T-shaped plate 37 is fixedly mounted on the base 1.

When the motor 28 drives the main gear 29 to rotate, since the main gear 29 is meshed with the first gear 14, the second gear 32 and the third gear 33, the first gear 14, the second gear 32 and the third gear 33 are driven to rotate by the main gear 29, the third belt pulley 34, the fourth belt pulley 35, the second belt 36 and the driving roller 5 can be driven to rotate after the first gear 14, the second gear 32 and the third gear 33 are driven to rotate, the conveying belt 4 can be driven to rotate by the punch 7 after the driving roller 5 rotates, and therefore, the conveying belt 4 does not need to be driven to rotate additionally, and the manufacturing and using cost of the processing system of the copper-clad aluminum wire is reduced.

Referring to fig. 1, a long rod 38 is fixedly installed on a base 1, a cam 13 is rotatably installed at one end of the long rod 38, a fifth belt pulley 39 is fixedly installed on the cam 13, a sixth belt pulley 40 is fixedly installed on a rotating shaft of a second gear 32, and a third belt 41 is wound around the fifth belt pulley 39 and the sixth belt pulley 40.

When the motor 28 drives the main gear 29 to rotate, the main gear 29 drives the second gear 32 to rotate, so as to drive the sixth belt pulley 40 to rotate, after the sixth belt pulley 40 rotates, the fifth belt pulley 39 and the cam 13 can be driven to rotate through the third belt 41, the cam 13 rotates to extrude the conveyor belt 4 upwards, so that the lead 6 can be better attached to the take-up pulley 11, and thus the working stability of the processing system of the copper-clad aluminum wire is improved.

Referring to fig. 1 and 5, as an embodiment of the present invention, a guide rod 20 is fixedly mounted on an outer side wall of a press 7, a first induction coil, a second induction coil, a third induction coil and a fourth induction coil are fixedly mounted in the guide rod 20 from left to right, a short rod 21 is fixedly connected to a bottom wall of a support plate 3, a first annular magnet 22 is fixedly mounted on a bottom end of the short rod 21, a motor 28 is electrically connected to the first annular magnet 22, a fixing plate 23 is fixedly mounted on a bottom wall of the first annular magnet 22, and a second annular magnet 24, a third annular magnet 25 and a fourth annular magnet 26 are fixed on the fixing plate 23.

When the punch 7 moves up and down, a first induction coil, a second induction coil, a third induction coil and a fourth induction coil are fixedly installed in the guide rod 20 from left to right in sequence, magnetic induction lines generated by the first annular magnet 22, the second annular magnet 24, the third annular magnet 25 and the fourth annular magnet 26 can be correspondingly cut and generate currents correspondingly by driving the guide rod 20 to move up and down, aiming at the currents generated by the cutting, the first induction coil cuts the magnetic induction lines of the first annular magnet 22, the second induction coil cuts the magnetic induction lines of the second annular magnet 24, the third induction coil cuts the magnetic induction lines of the third annular magnet 25, the fourth induction coil cuts the magnetic induction lines of the fourth annular magnet 26, only the current generated by the induction coil cutting the magnetic induction lines of the corresponding magnets can influence the next action, and the current generated by the corresponding magnets is not dense enough so that the cutting current can not drive the next action, the magnetic induction wire generated by cutting the first ring magnet 22 through the first induction coil is used for supplying power to the motor 28, so that the motor 28 drives the main gear 29 to rotate, the guide rod 20 is driven by the punch 7 to move up and down, and the motor 28 is electrified, so that the motor 28 is driven to work without additionally arranging a power supply, and the manufacturing and using cost of the processing system of the copper-clad aluminum wire is reduced.

As an embodiment of the invention, referring to fig. 1, 2, and 9, two T-shaped grooves 42 are symmetrically formed in the wind-up roll 10, two conductive springs 43 are fixedly mounted on bottom walls of the two T-shaped grooves 42, two baffles 44 are slidably mounted in the two T-shaped grooves 42, the two baffles 44 are respectively fixedly connected with the two conductive springs 43, and the two conductive springs 43 are electrically connected to the fourth induction coil.

When the fourth induction coil in the punch 7 drives the guide rod 20 to cut the magnetic induction line generated by the fourth annular magnet 26, the generated current makes the conductive spring 43 contract, thereby causing the baffle 44 to contract inwards, avoiding obstructing the annular push plate 12 from pushing the winding wheel 11 to move, replacing the winding wheel 11 on the winding roller 10, when the magnetic induction line of the fourth induction coil cutting fourth annular magnet 26 does not generate current or the generated current does not flow to the conductive spring 43, the conductive spring 43 recovers, causing the baffle 44 to stretch outwards to clamp the winding wheel 11, thereby fixing the winding wheel 11, and thereby improving the working stability of the processing system of the copper-clad aluminum wire.

Referring to fig. 1, 2 and 7, as an embodiment of the present invention, an installation groove 47 is formed in an output shaft of the punch 7, two connectors 46 are symmetrically installed on an inner wall of the installation groove 47, a cutting knife 8 for connecting the two connectors 46 is slidably installed in the installation groove 47, a glue sprayer 45 is sleeved on an outer side wall of the output shaft of the punch 7, and the glue sprayer 45 is electrically connected with the two connectors 46.

When punching machine 7 drives cutting knife 8 downstream, when cutting knife 8 downstream touches wire 6, cutting knife 8 can upwards displace a section distance, make two electric connection switch-ons between the joint 46, make glue spraying device 45 circular telegram, thereby wire 6 after the cutting spouts the glue, make absorption that wire 6 can be better on wind-up wheel 11, when punching machine 7 drives cutting knife 8 upward movement, with the help of gravity, make joint 46 and spout the electric connection disconnection between glue spraying device 45, make glue spraying device 45 stop spouting glue to wire 6, spout glue spraying device 45 through punching machine 7 drive to wire 6 intermittent type nature and spout glue, thereby manufacturing and use cost of the system of processing of copper clad aluminum wire have been reduced.

As an embodiment of the present invention, referring to FIGS. 1, 6 and 8, referring to fig. 12 and 13, a first electromagnetic hydrant 48 is fixedly mounted on a rotating shaft of the first gear 14, a second electromagnetic hydrant 49 is fixedly mounted on a rotating shaft of the second gear 32, a third electromagnetic hydrant 50 is fixedly mounted on a rotating shaft of the third gear 33, the third electromagnetic hydrant 50 and the second electromagnetic hydrant 49 are electrically connected to the second induction coil, the third induction coil is electrically connected to the second electromagnetic hydrant 49, the first electromagnetic hydrant 48 is electrically connected to the fourth induction coil, a first bidirectional switch 51 is fixedly mounted on an inner top wall of the second annular magnet 24, a second bidirectional switch 52 is fixedly mounted on an inner bottom wall of the second annular magnet 24, the first bidirectional switch 51 is electrically connected to the second bidirectional switch 52, and the third induction coil and the fourth induction coil are both electrically connected to the first bidirectional switch 51 and the second bidirectional switch 52.

When the punch 7 drives the guide rod 20 to cut the magnetic induction lines generated by the second annular magnet 24, the third annular magnet 25 and the fourth annular magnet 26, currents are generated on the corresponding second induction coil, the corresponding third induction coil and the fourth induction coil, the currents generated by the second induction coil cutting the magnetic induction lines of the second annular magnet 24 enable the third electromagnetic hydrant 50 and the second electromagnetic hydrant 49 to be electrified, the currents generated by the third induction coil and the fourth induction coil enable the second electromagnetic hydrant 49 and the first electromagnetic hydrant 48 to be electrified respectively, when the guide rod 20 moves downwards and touches the second bidirectional switch 52, the electrical connection among the third induction coil, the conductive spring 43 and the second electromagnetic hydrant 49 is switched on, the electrical connection between the first electromagnetic hydrant 48 and the fourth induction coil is switched on, when the guide rod 20 moves upwards and touches the first bidirectional switch 51, so that the electrical connection between the third induction coil and the second electromagnetic hydrant 49 is broken, and the electrical connection between the first electromagnetic hydrant 48, the conductive spring 43 and the fourth induction coil is broken.

Referring to fig. 6, 7, 8, 10, 12 and 13, as an embodiment of the present invention, a first magnetic block 53 is fixedly installed in each of a first electromagnetic hydrant 48, a second electromagnetic hydrant 49 and a third electromagnetic hydrant 50, a spring 54 is fixedly connected to each of outer side walls of the first magnetic block 53, the second electromagnetic hydrant 49 and the third electromagnetic hydrant 50, a plunger 55 is slidably installed in each of the first electromagnetic hydrant 48, the second electromagnetic hydrant 49 and the third electromagnetic hydrant 50, a slot matched with the plunger 55 is opened in each of the first gear 14, the second gear 32 and the third gear 33, a second magnetic block 56 is fixedly installed at one end of the plunger 55, and the second magnetic block 56 is fixedly connected to one end of the spring 54.

When the first electromagnetic hydrant 48, the second electromagnetic hydrant 49 and the third electromagnetic hydrant 50 are powered on, the first magnetic block 53 and the second magnetic block 56 inside the first magnetic block are powered on and generate magnetism, but the magnetism of the first magnetic block 53 and the magnetism of the second magnetic block 56 are repulsive, so that the second magnetic block 56 drives the inserted link 55 to move into the slot, thereby the external teeth of the gear and the rotating shaft of the gear are connected with each other, thereby the rotating shaft can be driven to rotate by the external teeth, the spring 54 is stretched, when the first electromagnetic hydrant 48, the second electromagnetic hydrant 49 and the third electromagnetic hydrant 50 are powered off, the repulsive force among the magnetic blocks is counteracted mutually, thereby the spring 54 restores the original state to drive the inserted link 55 to the original position, and the rotating shaft in the gear is disconnected from the gear.

The working principle is as follows: when the punch 7 drives the guide rod 20 and the cutting knife 8 to move downwards, when the guide rod 20 cuts magnetic induction lines generated by the first annular magnet 22, the second annular magnet 24, the third annular magnet 25 and the fourth annular magnet 26, currents are generated on the corresponding first induction coil, the second induction coil, the third induction coil and the fourth induction coil, the currents generated by the first induction coil are used for switching on the motor 28, the motor 28 drives the main gear 29 to rotate, the currents generated by the second induction coil enable the third electromagnetic hydrant 50 and the second electromagnetic hydrant 49 to be electrified, the inserted bars 55 in the third gear 33 and the second gear 32 are moved into the slots, the main gear 29 can drive the rotating shafts of the third gear 33 and the second gear 32 to rotate, and the fifth belt pulley 39, the sixth belt pulley 40, the third belt 41, the cam 13, the third belt pulley 34, the third belt pulley 40, the third belt pulley 41, the cam 13 and the third belt pulley 34 are driven, The fourth belt pulley 35, the second belt 36 and the driving roller 5 rotate, the current generated by the third induction coil and the fourth induction coil cannot flow to the second electromagnetic hydrant 49, the first electromagnetic hydrant 48 and the conductive spring 43, when the guide rod 20 touches the second two-way switch 52, the electrical connection between the third induction coil and the second electromagnetic hydrant 49 is connected, the electrical connection between the first electromagnetic hydrant 48 and the fourth induction coil is connected, when the cutting knife 8 moves downwards to touch the lead 6, the cutting knife 8 moves upwards for a certain distance, the electrical connection between the two connectors 46 is connected, the glue sprayer 45 is powered on, the cut lead 6 is sprayed with glue, when the cutting is completed, the punch 7 drives the guide rod 20 and the cutting knife 8 to move upwards, when the cutting knife 8 moves upwards, the electrical connection between the connectors 46 and the glue sprayer 45 is disconnected under the action of gravity, the glue sprayer 45 stops spraying glue on the lead 6, the glue sprayer 45 is driven by the punch 7 to intermittently spray glue on the lead 6, so that the manufacturing and using cost of a processing system of the copper-clad aluminum wire is reduced, when the guide rod 20 moves upwards, the guide rod 20 cuts magnetic induction wires generated by the first annular magnet 22, the second annular magnet 24, the third annular magnet 25 and the fourth annular magnet 26, so that currents are generated on the corresponding first induction coil, the second induction coil, the third induction coil and the fourth induction coil, the current generated by the third induction coil 25 enables the second electromagnetic hydrant 49 to be electrified, the main gear 29 drives the rotating shaft of the second gear 32 to rotate, the cut lead 6 is wound, when the current generated by the fourth induction coil flows to the first electromagnetic hydrant 48, the rotating shaft of the first gear 14 rotates and the conductive spring 43 is electrified, the conductive spring 43 contracts, so that the baffle 44 moves downwards, the annular push plate 12 is prevented from being blocked to push the winding wheel 11 to move, the winding wheel 11 on the winding roller 10 is replaced, the rotating shaft of the first gear 14 rotates to drive the first belt pulley 15, the second belt pulley 18, the first belt 19, the roller 17 and the reciprocating screw rod 16 to rotate, the reciprocating screw rod 16 rotates to drive the annular push plate 12 to move, thereby leading the winding wheel 11 to fall off and finishing the replacement of the winding wheel 11 on the winding roller 10, when the guide rod 20 moves upward and touches the first two-way switch 51, the electrical connection between the third induction coil and the second electromagnetic hydrant 49 is broken, the first electromagnetic hydrant 48 is electrically disconnected from the fourth induction coil, and the current generated by the third induction coil is prevented from flowing to the second electromagnetic hydrant 49, the conductive spring 43 and the first electromagnetic hydrant 48 during the downward movement.

The electric elements in the document are electrically connected with an external main controller and 220V mains supply through a transformer, the main controller can be a conventional known device controlled by a computer and the like, the product model provided by the invention is only used according to the structural characteristics of the product, the product can be adjusted and modified after being purchased, so that the product is more matched with and accords with the technical scheme of the invention, the product model is a technical scheme of the optimal application of the technical scheme, the product model can be replaced and modified according to the required technical parameters, and the product model is familiar to the technical personnel in the field, so that the technical scheme provided by the invention can clearly obtain the corresponding use effect.

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

1. The utility model provides a system of processing of copper clad aluminum wire, includes base (1), its characterized in that: the automatic drawing device is characterized in that a drawing box (2) is fixedly mounted on a base (1), a supporting plate (3) is fixedly mounted on the top wall of the drawing box (2), a punching machine (7) is fixedly mounted on the bottom wall of the supporting plate (3), a cutting knife (8) is slidably mounted on an output shaft of the punching machine (7), two driving rollers (5) are symmetrically mounted above the base (1), two driving rollers (5) are jointly wound with a conveying belt (4), a wire (6) is placed on the conveying belt (4), a mounting rod (27) is fixedly mounted on the base (1), one of the driving rollers (5) is rotatably mounted on the mounting rod (27), a motor (28) is fixedly mounted on the mounting rod (27), a main gear (29) is fixedly mounted on the output shaft of the motor (28), and a second connecting rod (30) is fixedly mounted on the bottom wall of the supporting plate (3), one end of second connecting rod (30) is rotated and is installed wind-up roll (10), slidable mounting has a plurality of rolling wheels (11) on wind-up roll (10), be equipped with the rolling district on wind-up roll (10), the pot head of wind-up roll (10) is equipped with annular push pedal (12), fixedly connected with promotes automatically that wind-up wheel (11) removes the pushing mechanism in rolling district on annular push pedal (12), be connected with on master gear (29) and be used for driving roller (5), wind-up roll (10) and annular push pedal (12) driven transmission assembly.

2. The processing system of the copper-clad aluminum wire according to claim 1, characterized in that: the pushing mechanism comprises a first connecting rod (9) fixedly installed on the bottom wall of the supporting plate (3), a first gear (14) meshed with a main gear (29) is installed at one end of the first connecting rod (9) in a rotating mode, a first belt pulley (15) is fixedly installed on a rotating shaft of the first gear (14), two reciprocating lead screws (16) are symmetrically and fixedly connected to the outer side wall of the annular pushing plate (12), two rollers (17) are sleeved at one ends of the reciprocating lead screws (16), the two rollers (17) are in threaded transmission connection with the two reciprocating lead screws (16) respectively, the reciprocating lead screws (16) penetrate through the rollers (17), second belt pulleys (18) are fixedly installed on the two rollers (17), and a first belt (19) is wound on the first belt pulley (15) and the two second belt pulleys (18) together, one end of the winding roller (10) is rotatably provided with a T-shaped rod (57), and the two rollers (17) are rotatably arranged at two ends of the T-shaped rod (57).

3. The processing system of the copper-clad aluminum wire according to claim 2, characterized in that: drive assembly includes second connecting rod (30) and third connecting rod (31) of fixed mounting on backup pad (3) diapire, the one end of second connecting rod (30) is rotated and is installed second gear (32) with master gear (29) intermeshing, the one end of third connecting rod (31) is rotated and is installed third gear (33) with master gear (29) intermeshing, fixed mounting has third belt pulley (34) in the axis of rotation of third gear (33), fixed mounting has fourth belt pulley (35) in the axis of rotation of driving roller (5), jointly around being equipped with second belt pulley (36) on third belt pulley (34) and fourth belt pulley (35), fixed mounting has T template (37) on base (1).

4. The processing system of the copper-clad aluminum wire according to claim 3, characterized in that: fixed mounting has stock (38) on base (1), cam (13) are installed in the one end rotation of stock (38), fixed mounting fifth belt pulley (39) are gone up in cam (13), fixed mounting has sixth belt pulley (40) in the axis of rotation of second gear (32), on fifth belt pulley (39) and sixth belt pulley (40) jointly around being equipped with third belt (41).

5. The copper-clad aluminum wire processing system according to claim 4, wherein: fixed mounting has guide arm (20) on punching machine (7) lateral wall, from left to right in guide arm (20) from left to right in proper order fixed mounting have first induction coil, second induction coil, third induction coil and fourth induction coil, fixedly connected with quarter butt (21) on the diapire of backup pad (3), fixed mounting has first ring magnet (22) on the bottom of quarter butt (21), and motor (28) and first ring magnet (22) electric connection, fixed mounting has fixed plate (23) on the diapire of first ring magnet (22), be fixed with second ring magnet (24), third ring magnet (25) and fourth ring magnet (26) on fixed plate (23).

6. The processing system of the copper-clad aluminum wire according to claim 5, wherein: two T type grooves (42), two have been seted up to symmetry in wind-up roll (10) equal fixed mounting has two electrically conductive spring (43), two on the diapire of T type groove (42) equal slidable mounting has two baffle (44) in T type groove (42), and two baffle (44) respectively with two electrically conductive spring (43) fixed connection, two the equal electric connection of electrically conductive spring (43) is on fourth induction coil.

7. The processing system of the copper-clad aluminum wire according to claim 6, wherein: the utility model discloses a glue spraying machine, including punching machine (7), be equipped with in the output shaft of punching machine (7) mounting groove (47), the symmetry is installed on the inner wall of mounting groove (47) and is connected two (46), slidable mounting has cutting knife (8) that are used for connecting two joints (46) in mounting groove (47), the cover is equipped with on the lateral wall of punching machine (7) output shaft and spouts gluey ware (45), spout gluey ware (45) and two joints (46) electric connection.

8. The processing system of the copper-clad aluminum wire according to claim 7, wherein: the electromagnetic clutch is characterized in that a first electromagnetic hydrant (48) is fixedly mounted on a rotating shaft of the first gear (14), a second electromagnetic hydrant (49) is fixedly mounted on a rotating shaft of the second gear (32), a third electromagnetic hydrant (50) is fixedly mounted on a rotating shaft of the third gear (33), the third electromagnetic hydrant (50), the second electromagnetic hydrant (49) and the second induction coil are electrically connected, the third induction coil is electrically connected with the second electromagnetic hydrant (49), the first electromagnetic hydrant (48) is electrically connected with the fourth induction coil, a first bidirectional switch (51) is fixedly mounted on an inner top wall of the second annular magnet (24), a second bidirectional switch (52) is fixedly mounted on an inner bottom wall of the second annular magnet (24), the first bidirectional switch (51) is electrically connected with the second bidirectional switch (52), and the third induction coil and the fourth induction coil are electrically connected with the first bidirectional switch (51) and the second bidirectional switch (51) A bidirectional switch (52).

9. The processing system of the copper-clad aluminum wire according to claim 8, wherein: first magnetic blocks (53) are fixedly mounted in the first electromagnetic hydrant (48), the second electromagnetic hydrant (49) and the third electromagnetic hydrant (50), springs (54) are fixedly connected to the outer side walls of the first magnetic blocks (53), the second electromagnetic hydrant (49) and the third electromagnetic hydrant (50), inserting rods (55) are slidably mounted in the first electromagnetic hydrant (48), the second electromagnetic hydrant (49) and the third electromagnetic hydrant (50), clamping grooves matched with the inserting rods (55) are formed in the first gear (14), the second gear (32) and the third gear (33), second magnetic blocks (56) are fixedly mounted at one ends of the inserting rods (55), and the second magnetic blocks (56) are fixedly connected with one ends of the springs (54).