CN113617977B

CN113617977B - Cable intelligence cutting device

Info

Publication number: CN113617977B
Application number: CN202111184978.4A
Authority: CN
Inventors: 张军
Original assignee: Nantong Dongfeng Special Cable Co ltd
Current assignee: Nantong Jiashijie Electric Co ltd
Priority date: 2021-10-12
Filing date: 2021-10-12
Publication date: 2021-12-28
Anticipated expiration: 2041-10-12
Also published as: CN113617977A

Abstract

The invention relates to the field of cable processing, in particular to an intelligent cable cutting device which comprises a device bracket, a feeding mechanism, a transmission mechanism, a pushing rack, a sensor, a cutting mechanism, a pulling mechanism and a positioning mechanism, wherein the device bracket comprises a supporting bracket, a double-sided rack, an adjusting slide rail and a positioning bulge, the feeding mechanism comprises a feeding shaft, a feeding belt wheel, a feeding press wheel and a feeding slide block, the transmission mechanism comprises a transmission bracket, the transmission shaft, the drive wheel, electro-magnet I with inhale and coil I, it is provided with four to promote the rack, cutting mechanism includes two telescopic machanism, two telescopic machanism are flexible to serve equal fixedly connected with cutting tool, pull the mechanism including pull the frame, pull the axle, pull the wheel, pull the pinch roller, pull the motor, the drive wheel, electro-magnet II with inhale and coil II, positioning mechanism includes the locating support, extrude support and locating wheel, can be according to the cable of the user demand fly-cutting appointed length of difference.

Description

Cable intelligence cutting device

Technical Field

The invention relates to the field of cable processing, in particular to an intelligent cutting device for a cable.

Background

At present, the existing civil cable cutting procedures are complex, each procedure needs to be participated by a plurality of persons, some procedures also need manual operation, and all procedures need to be manually connected, therefore, a semi-finished product placing field and a personnel flowing channel are reserved among the procedures and are used for manually transporting the semi-finished products of each procedure to the next procedure; the existing production line of the civil cable not only consumes a large amount of human resources, but also occupies a large space, and manual connection of all working procedures has high requirements on physical strength and skill of operators, so that the efficiency is low. And none of the prior art devices can rapidly cut a cable of a specified length according to different use requirements.

Disclosure of Invention

The invention aims to provide an intelligent cable cutting device which can quickly cut cables with specified lengths according to different use requirements.

The purpose of the invention is realized by the following technical scheme:

an intelligent cable cutting device comprises a device support, a feeding mechanism, a transmission mechanism, a pushing rack, a sensor, a cutting mechanism, a pulling mechanism and a positioning mechanism, wherein the device support comprises a supporting support, a double-sided rack, adjusting slide rails and positioning bulges;

the feeding mechanism comprises a feeding shaft, feeding belt wheels, feeding press wheels and feeding slide blocks, wherein the feeding press wheels are fixedly connected to the middle of the feeding shaft, the feeding belt wheels are fixedly connected to the end portions of the feeding shaft, the feeding slide blocks are rotatably connected to the feeding shaft, the diameters of the feeding press wheels are larger than those of the feeding belt wheels, the number of the feeding mechanisms is two, the four feeding slide blocks are vertically and slidably connected to the supporting bracket, and a compression spring I is fixedly connected between each feeding slide block and the supporting bracket;

the transmission mechanism comprises a transmission bracket, transmission shafts, transmission wheels, an electromagnet I and a suction disc I, the transmission bracket is rotatably connected with the two transmission shafts, the two transmission shafts are in meshing transmission, one of the transmission shafts is provided with a power mechanism for driving the transmission shafts to rotate, the power mechanism is preferably a servo motor internally provided with a band-type brake, the two transmission shafts are respectively and rotatably connected with transmission wheels, the two transmission wheels are respectively and fixedly connected with an electromagnet I, the two transmission shafts are respectively and slidably connected with a suction disc I, a compression spring II is fixedly connected between the suction disc I and the transmission shafts, the two transmission mechanisms are respectively provided, the two transmission supports are respectively and slidably connected with a support bracket, a compression spring III is fixedly connected between the transmission support and the support bracket, four feeding belt wheels are respectively in transmission connection with the four transmission shafts, and the transmission ratio between the feeding belt wheels and the transmission shafts is one;

four pushing racks are arranged, the four pushing racks are all connected to the supporting bracket in a sliding mode, a compression spring IV is fixedly connected between each pushing rack and the supporting bracket, four driving wheels are respectively in meshed transmission with the four pushing racks, four sensors are arranged, the four sensors are respectively connected to four adjusting slide rails in a sliding mode, the four sensors are respectively located at the front ends of the four pushing racks, and positioning screws are connected to the four sensors through threads;

the cutting mechanism comprises two telescopic mechanisms, cutting tools are fixedly connected to the telescopic ends of the two telescopic mechanisms, the two telescopic mechanisms are fixedly connected to the supporting bracket, the two telescopic mechanisms are respectively connected with two sensors positioned on the lower side, and the sensors can be extrusion sensors or contact sensors;

the dragging mechanism comprises a dragging frame, dragging shafts, dragging wheels, dragging press wheels, dragging motors, driving wheels, electromagnets II and a dragging and mixing disk II, the dragging frame is connected to a supporting bracket in a sliding mode, a compression spring V is fixedly connected between the supporting bracket and the dragging frame, the dragging frame is connected with two dragging shafts in a rotating mode, the middle parts of the two dragging shafts are fixedly connected with the dragging press wheels, the two ends of the two dragging shafts are fixedly connected with the dragging wheels, the diameter of the dragging press wheels is larger than that of the dragging wheels, the four dragging wheels are respectively in meshing transmission with four double-sided racks, the dragging motors are fixedly connected to the dragging frame, the output shafts of the dragging motors are connected with the driving wheels in a rotating mode, the electromagnets II are fixedly connected to the driving wheels, the output shafts of the dragging motors are connected with the sucking and mixing disk II in a sliding mode, a compression spring VI is fixedly connected between the sucking and mixing disk II and the output shafts of the dragging motors, the driving wheels are in meshing transmission with one of the double-sided racks, the pulling motor is connected with the power mechanism and one of the two sensors positioned on the upper side, and the electromagnet I is connected with the electromagnet II and the other of the two sensors positioned on the upper side;

the positioning mechanism comprises a positioning support, an extrusion support and a positioning wheel, the positioning support is fixedly connected to the supporting support, the positioning support is connected with three extrusion supports in a sliding mode, the three extrusion supports are connected with the positioning wheel in a rotating mode, and a compression spring VII is fixedly connected between each extrusion support and the corresponding positioning support.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic view of the connection structure of the feeding mechanism and the transmission mechanism of the present invention;

FIG. 2 is a first schematic structural diagram of the intelligent cable cutting device according to the present invention;

FIG. 3 is a schematic structural diagram II of the intelligent cable cutting device according to the present invention;

FIG. 4 is a schematic view of the device holder and sensor attachment configuration of the present invention;

FIG. 5 is a schematic view of the attachment structure of the device holder and the cutting device of the present invention;

FIG. 6 is a schematic view of the feed mechanism of the present invention;

FIG. 7 is a first schematic view of the linkage of the transmission mechanism and the push rack of the present invention;

FIG. 8 is a second schematic view of the linkage of the transmission mechanism and the push rack of the present invention;

FIG. 9 is a schematic view of the push rack configuration of the present invention;

FIG. 10 is a schematic diagram of a sensor configuration of the present invention;

FIG. 11 is a schematic view of the cutting mechanism of the present invention;

FIG. 12 is a first drawing mechanism of the present invention;

FIG. 13 is a second drawing mechanism configuration of the present invention;

fig. 14 is a schematic structural view of the positioning mechanism of the present invention.

In the figure: a device holder 10; a support bracket 11; a double-sided rack 12; adjusting the slide rail 13; a positioning boss 14; a feeding mechanism 20; a feed shaft 21; a feeding belt pulley 22; a feeding pinch roller 23; a feeding slide block 24; a transmission mechanism 30; a transmission bracket 31; a drive shaft 32; a transmission wheel 33; an electromagnet I34; a suction disc I35; pushing the rack 40; a sensor 50; a cutting mechanism 60; a telescoping mechanism 61; a cutting tool 62; a pulling mechanism 70; pulling the frame 71; pulling the shaft 72; a pulling wheel 73; pulling the pinch roller 74; pulling the motor 75; the drive wheel 76; an electromagnet II 77; suction plate II 78; a positioning mechanism 80; a positioning bracket 81; a pressing bracket 82; the wheel 83 is positioned.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

In order to solve the technical problem of cutting the length of the cable according to different use requirements, the following detailed description is made on the structure and function of an intelligent cable cutting device, which comprises a device bracket 10, a feeding mechanism 20, a transmission mechanism 30, a pushing rack 40, a sensor 50, a cutting mechanism 60, a pulling mechanism 70 and a positioning mechanism 80;

when the cable needs to be cut, the cable sequentially passes through the positioning mechanism 80, the two feeding mechanisms 20 and the cutting mechanism 60, the two feeding mechanisms 20 move, the two feeding mechanisms 20 drive the cable to move forwards for a specified length, the cutting mechanism 60 is started, and the cutting mechanism 60 cuts the cable extending out of the two feeding mechanisms 20 for a certain length;

further, a transmission mechanism 30 for transmitting the movement length of the cable is further arranged, the transmission mechanism 30 is driven by the two feeding mechanisms 20 to move, the two transmission mechanisms 30 respectively drive the four pushing racks 40 to move, the four pushing racks 40 move forwards to a specified distance and respectively extrude the corresponding sensors 50, wherein the two sensors 50 are connected with the cutting mechanism 60, the two sensors 50 control the cutting mechanism 60 to move to cut the cable, the cut length of the cable is further controlled, the transmission mechanism 30 and the pulling mechanism 70 are connected with the other two sensors 50, the automatic control device continuously works, the four sensors 50 are arranged at different positions, the time for the pushing racks 40 to extrude the sensors 50 is further controlled, the cut length of the cable can be controlled, and the processing process of the device is controlled;

the structure and function of the device bracket 10 are explained below, the device bracket 10 includes a support bracket 11, two-sided racks 12, adjusting slide rails 13 and positioning protrusions 14, the support bracket 11 is fixedly connected with four two-sided racks 12, the support bracket 11 is fixedly connected with four adjusting slide rails 13, and the support bracket 11 is fixedly connected with positioning protrusions 14;

the structure and the function of the feeding mechanism 20 are explained below, the feeding mechanism 20 comprises a feeding shaft 21, feeding belt wheels 22, feeding press wheels 23 and feeding slide blocks 24, the middle part of the feeding shaft 21 is fixedly connected with the feeding press wheels 23, the end parts of the feeding shaft 21 are fixedly connected with the feeding belt wheels 22, the feeding shaft 21 is rotatably connected with the feeding slide blocks 24, the diameter of the feeding press wheels 23 is larger than that of the feeding belt wheels 22, the feeding mechanism 20 is provided with two feeding slide blocks 24, the four feeding slide blocks 24 are vertically and slidably connected to the support bracket 11, and a compression spring I is fixedly connected between the feeding slide blocks 24 and the support bracket 11;

as shown in fig. 6, the rotation directions of the two feeding shafts 21 are opposite, when the two feeding shafts 21 rotate, the two feeding shafts 21 respectively drive the corresponding feeding pinch rollers 23 to rotate, and when the two feeding pinch rollers 23 rotate, the cables passing through between the two feeding pinch rollers 23 are pushed to move forward, so that the cables are driven to move forward by a specified length;

furthermore, because the length of the cable may need to move forward for a long distance, the length of the cable moving forward needs to be scaled, so that the diameter of the feeding pinch roller 23 is larger than that of the feeding belt wheel 22, and when the feeding belt wheel 22 rotates for one turn, the cable can be driven to move forward for a long length, and then the distance of the corresponding pushing rack 40 moving forward is scaled;

the structure and function of the transmission mechanism 30 will be explained below, as shown in fig. 1, 7 and 8, the transmission mechanism 30 includes a transmission bracket 31, transmission shafts 32, transmission wheels 33, electromagnets i 34 and a suction disc i 35, the transmission bracket 31 is rotatably connected with two transmission shafts 32, the two transmission shafts 32 are in meshing transmission, one of the transmission shafts 32 is provided with a power mechanism for driving the transmission shaft 32 to rotate, the power mechanism is preferably a servo motor with a brake inside, the two transmission shafts 32 are rotatably connected with the transmission wheels 33, the two transmission wheels 33 are fixedly connected with the electromagnets i 34, the two transmission shafts 32 are respectively and slidably connected with the suction disc i 35, a compression spring ii is fixedly connected between the suction disc i 35 and the transmission shafts 32, the transmission mechanism 30 is provided with two transmission brackets 31, the two transmission brackets 31 are respectively and slidably connected with the support bracket 11, and a compression spring iii is fixedly connected between the transmission bracket 31 and the support bracket 11, the four feeding belt wheels 22 are respectively in transmission connection with the four transmission shafts 32, and the transmission ratio between the feeding belt wheels 22 and the transmission shafts 32 is one;

firstly, an electromagnet I34 is started, the electromagnet I34 sucks an attraction disc I35, the attraction disc I35 overcomes the elasticity of a compression spring II, a power mechanism is started, the power mechanism drives a transmission shaft 32 to rotate, the two transmission shafts 32 rotate together, the two transmission shafts 32 respectively drive two feeding belt wheels 22 to rotate, the two feeding belt wheels 22 respectively drive two feeding shafts 21 to rotate, the two feeding shafts 21 respectively drive two feeding press wheels 23 to move, and the two feeding press wheels 23 push a cable to move forwards;

when the power mechanism is started, the four transmission shafts 32 rotate together, when the four transmission shafts 32 rotate, the corresponding electromagnets I34 are driven to rotate through the attraction disc I35, the electromagnets I34 drive the transmission wheels 33 to rotate, and the transmission wheels 33 drive the pushing racks 40 to move forwards, so that the cutting length of the cable is controlled;

the structure and the function of the pushing rack 40 and the sensors 50 are explained below, four pushing racks 40 are provided, four pushing racks 40 are all slidably connected to the supporting bracket 11, a compression spring iv is fixedly connected between the pushing racks 40 and the supporting bracket 11, four transmission wheels 33 are respectively engaged with the four pushing racks 40 for transmission, four sensors 50 are provided, the four sensors 50 are respectively slidably connected to four adjusting slide rails 13, the four sensors 50 are respectively positioned at the front ends of the four pushing racks 40, and the four sensors 50 are all connected with positioning screws through threads;

the position of the sensor 50 on the adjusting slide rail 13 is adjusted in advance according to the use requirement, wherein the two sensors 50 on the lower side are respectively connected with the two telescopic mechanisms 61, namely the two sensors 50 on the lower side control cutting, when the two sensors 50 on the lower side are extruded, the sensor 50 is connected with the two telescopic mechanisms 61 through the technical means commonly used in the field, the telescopic mechanisms 61 can be hydraulic cylinders or electric push rods, the two sensors 50 on the lower side drive the telescopic mechanisms 61 to move, the telescopic ends of the two telescopic mechanisms 61 are close to each other to cut cables, and therefore the cutting time can be controlled by controlling the positions of the two sensors 50 on the lower side on the adjusting slide rail 13;

one of the two sensors 50 positioned at the upper side is connected with the power mechanism and the pulling motor 75, band-type brakes are arranged in the power mechanism and the pulling motor 75, when the sensor is extruded by the corresponding pushing rack 40, the sensor controls the power mechanism and the pulling motor 75 to stop rotating, so that the position of the sensor 50 is controlled, the movement time of the transmission mechanism 30 and the pulling mechanism 70 is controlled, the time of the transmission mechanism 30 for driving the cable to move forwards is controlled, and the movement length of the cable is controlled;

the other sensor 50 and the electromagnet I34 which are positioned on the upper side are connected with the electromagnet II 77, after cutting is completed, the rack 40 and the pulling mechanism 70 need to be pushed to reset, preparation is made for next cutting, when the sensor 50 is extruded, the sensor 50 controls the electromagnet I34 and the electromagnet II 77 to be powered off, the electromagnet I34 is disconnected with the electromagnet II 77, the sucking and kneading disc I35 and the sucking and kneading disc II 78 reset under the pulling of the compression spring II and the compression spring VI, the power mechanism and the band-type brake of the pulling motor 75 cannot play a role in stopping the driving wheel 33 and the driving wheel 76, the rack 40 and the pulling mechanism 70 are pushed to reset under the pulling of the compression spring IV and the compression spring V, and preparation is made for next cutting;

furthermore, to further explain the positions of the four sensors 50, it is preferable that the sensor 50 connected to the cutting mechanism 60 is placed at the rearmost end, the rack 40 is pushed to extrude the sensors 50 connected to the two telescoping mechanisms 61 first, when the telescoping mechanisms 61 are extruded, the telescoping ends of the telescoping mechanisms 61 reciprocate once, the cutting mechanism 60 cuts the cable, and then the rack 40 is pushed to move forward, the rack 40 is pushed to contact with the sensor 50 connected to the power mechanism and the pull motor 75 and the sensor 50 connected to the electromagnet i 34 and the electromagnet ii 77, when the power mechanism and the pull motor 75 stop rotating, the electromagnet i 34 and the electromagnet ii 77 are not electrified, and the rack 40 and the pull mechanism 70 are pushed to reset;

the structure and function of the cutting mechanism 60 will be described below, the cutting mechanism 60 includes two telescoping mechanisms 61, the cutting tool 62 is fixedly connected to the telescoping ends of the two telescoping mechanisms 61, the two telescoping mechanisms 61 are fixedly connected to the support bracket 11, the two telescoping mechanisms 61 are respectively connected to the two sensors 50 located at the lower side, and the sensors 50 may be extrusion sensors or contact sensors;

when the sensor 50 is extruded, the telescopic ends of the two telescopic mechanisms 61 extend out, and the telescopic ends of the two telescopic mechanisms 61 drive the two cutting tools 62 to move close to each other to cut the cable;

the dragging mechanism 70 comprises a dragging frame 71, dragging shafts 72, dragging wheels 73, dragging press wheels 74, a dragging motor 75, driving wheels 76, electromagnets II 77 and a sucking and coiling II 78, wherein the dragging frame 71 is connected to the supporting bracket 11 in a sliding manner, a compression spring V is fixedly connected between the supporting bracket 11 and the dragging frame 71, the dragging frame 71 is connected with two dragging shafts 72 in a rotating manner, the middle parts of the two dragging shafts 72 are fixedly connected with the dragging press wheels 74, the two ends of the two dragging shafts 72 are fixedly connected with the dragging wheels 73, the diameter of the dragging press wheels 74 is larger than that of the dragging wheels 73, the four dragging wheels 73 are respectively in meshing transmission with the four double-sided racks 12, the dragging motor 75 is fixedly connected to the dragging frame 71, the output shaft of the dragging motor 75 is connected with the driving wheels 76 in a rotating manner, the electromagnets II 77 are fixedly connected to the driving wheels 76, the output shaft of the dragging motor 75 is connected with the sucking and coiling II 78 in a sliding manner, a compression spring VI is fixedly connected between the sucking disc II 78 and an output shaft of the dragging motor 75, the driving wheel 76 is in meshing transmission with one of the double-sided racks 12, the dragging motor 75 is connected with a power mechanism and one of the two sensors 50 positioned on the upper side, and the electromagnet I34 is connected with the electromagnet II 77 and the other of the two sensors 50 positioned on the upper side;

during processing, the electromagnet I34 and the electromagnet II 77 are started, the electromagnet I34 and the electromagnet II 77 attract and combine the corresponding attraction disc I35 and the attraction disc II 78, so that the power mechanism and the pulling motor 75 can drive the transmission wheel 33 and the driving wheel 76 to rotate, the power mechanism and the pulling motor 75 are started, the rotating speed of the output shaft of the power mechanism is greater than that of the output shaft of the pulling motor 75, the power mechanism drives the transmission wheel 33 to rotate, the transmission wheel 33 drives the feeding mechanism 20 to move, the cable is driven to move forwards, the driving wheel 76 rotates simultaneously, the driving wheel 76 drives the pulling mechanism 70 to move forwards, the moving speed of the pulling mechanism 70 is less than that of the cable, the cable overtakes the pulling mechanism 70, the cable passes between the two pulling pressure wheels 74, the preferred pulling pressure wheel 74 is made of elastic material, and in order to ensure that the cable is in a tight state during cutting, the cutting precision is guaranteed, a pulling wheel 73 is further arranged, the pulling wheel 73 is driven by the double-sided rack 12 to rotate, the double-sided rack 12 drives the pulling shaft 72 to rotate, the pulling shaft 72 drives the pulling pressing wheel 74 to rotate, the diameter of the pulling pressing wheel 74 is larger than that of the pulling wheel 73, the linear velocity of the pulling pressing wheel 74 is larger than that of the pulling wheel 73, the diameter of the pulling pressing wheel 74 needs to be reasonably set, the linear velocity of the pulling pressing wheel 74 is larger than that of a cable moving forwards, and the two pulling pressing wheels 74 extrude and stretch the cable, so that the cable is always in a tight state in the forward moving process;

the structure and function of the positioning mechanism 80 are explained below, the positioning mechanism 80 comprises a positioning bracket 81, an extrusion bracket 82 and a positioning wheel 83, the positioning bracket 81 is fixedly connected to the support bracket 11, the positioning bracket 81 is slidably connected with the three extrusion brackets 82, the three extrusion brackets 82 are rotatably connected with the positioning wheel 83, and a compression spring VII is fixedly connected between the extrusion brackets 82 and the positioning bracket 81;

the cable to be processed penetrates through the three positioning wheels 83, the three extrusion supports 82 extrude the positioning wheels 83 under the elastic force of the compression spring VII, the three positioning wheels 83 extrude the cable, the cable is positioned, and the three positioning wheels 83 can position the cables with different diameters.

Claims

1. The utility model provides a cable intelligence cutting device, includes device support (10) and two feeding mechanism (20) of sliding connection on device support (10) to and two drive mechanism (30) of sliding connection on device support (10), its characterized in that: the device bracket (10) is fixedly connected with a cutting mechanism (60), and the two feeding mechanisms (20) are in transmission connection through two transmission mechanisms (30);

the feeding mechanism (20) comprises a feeding shaft (21) and a feeding pinch roller (23) fixedly connected to the middle part of the feeding shaft (21), a feeding slide block (24) is rotatably connected to the feeding shaft (21), and feeding belt wheels (22) are fixedly connected to both ends of the feeding shaft (21);

the transmission mechanism (30) comprises a transmission support (31) and two transmission shafts (32) which are rotatably connected to the transmission support (31), the two transmission shafts (32) are in meshing transmission, one transmission shaft (32) is provided with a power mechanism for driving the transmission shaft (32) to rotate, the two transmission shafts (32) are both rotatably connected with transmission wheels (33), the two transmission wheels (33) are both fixedly connected with electromagnets I (34), the two transmission shafts (32) are both slidably connected with suction discs I (35), and compression springs II are fixedly connected between the suction discs I (35) and the transmission shafts (32);

the device comprises a device support (10), a support frame (11) and four driving wheels (33), wherein the device support (10) is connected with four pushing racks (40) in a sliding mode, a compression spring IV is fixedly connected between each pushing rack (40) and the support frame (11), the four driving wheels (33) are respectively meshed with the four pushing racks (40) for transmission, the device support (10) is connected with four sensors (50) in a sliding mode, and the four sensors (50) are respectively located at the front ends of the four pushing racks (40);

the cutting mechanism (60) comprises two telescopic mechanisms (61) and a cutting tool (62) fixedly connected to the telescopic ends of the two telescopic mechanisms (61), and the two telescopic mechanisms (61) are respectively connected with two sensors (50) positioned on the lower side;

the device comprises a device support (10), a pulling mechanism (70) is connected on the device support (10) in a sliding mode, a compression spring V is fixedly connected between the pulling mechanism (70) and the device support (10), the pulling mechanism (70) comprises a pulling frame (71), pulling shafts (72), pulling wheels (73), pulling pinch rollers (74), a pulling motor (75), a driving wheel (76), an electromagnet II (77) and a sucking and kneading disc II (78), the pulling frame (71) is connected with the two pulling shafts (72) in a rotating mode, the middle parts of the two pulling shafts (72) are fixedly connected with the pulling pinch rollers (74), the two ends of the two pulling shafts (72) are fixedly connected with the pulling wheels (73), the diameter of the pulling pinch rollers (74) is larger than that of the pulling wheels (73), the pulling frame (71) is fixedly connected with the pulling motors (75), an output shaft of the pulling motors (75) is connected with the driving wheel (76) in a rotating mode, and the electromagnet II (77) is fixedly connected with the driving wheel (76), an output shaft of the dragging motor (75) is connected with a sucking disc II (78) in a sliding mode, a compression spring VI is fixedly connected between the sucking disc II (78) and the output shaft of the dragging motor (75), one of the two sensors (50) located on the upper side is connected with the power mechanism and the dragging motor (75), and the other sensor (50) located on the upper side and the electromagnet I (34) are connected with the electromagnet II (77).

2. The intelligent cable cutting device as claimed in claim 1, wherein: the diameter of the feeding pinch roller (23) is larger than that of the feeding belt wheel (22).

3. The intelligent cable cutting device as claimed in claim 1, wherein: the feeding sliding block (24) is connected to the device support (10) in a sliding mode, and a compression spring I is fixedly connected between the feeding sliding block (24) and the supporting support (11).

4. The intelligent cable cutting device as claimed in claim 1, wherein: the transmission supports (31) on the two transmission mechanisms (30) are connected to the device support (10) in a sliding mode, a compression spring III is fixedly connected between the transmission supports (31) and the supporting support (11), and the four feeding belt wheels (22) are in transmission connection with the four transmission shafts (32) respectively.

5. The intelligent cable cutting device as claimed in claim 1, wherein: and a positioning mechanism (80) for positioning the cable is fixedly connected to the device bracket (10).