CN112382447A - Vehicle-mounted camera cable processing equipment - Google Patents

Abstract

The invention relates to a cable processing device, in particular to a vehicle-mounted camera cable processing device which comprises a crushing mechanism, a separating mechanism and an extrusion discharging mechanism.

Description

Vehicle-mounted camera cable processing equipment

Technical Field

The invention relates to cable processing equipment, in particular to vehicle-mounted camera cable processing equipment.

Background

In the recovery processing of on-vehicle camera, the cable carries out the traditional cable treatment facility of independent processing, in the disengaging process of copper line and cable leather, need utilize the air current and shake the bed and cooperate just can separate, the in-process of vibrations easily produces the dust, so designed this kind of on-vehicle camera cable treatment facility.

Disclosure of Invention

The technical problem mainly solved by the invention is to provide vehicle-mounted camera cable processing equipment, the equipment can crush, the equipment can separate a copper wire and a cable sheath, the equipment can discharge the copper wire, and the equipment can extrude and discharge the cable sheath to reduce the floor area.

In order to solve the technical problem, the invention relates to a cable processing device, in particular to a vehicle-mounted camera cable processing device which comprises a crushing mechanism, a separating mechanism and an extrusion discharging mechanism, wherein the device can crush, can separate a copper wire and a cable sheath, can discharge the copper wire, and can extrude and discharge the cable sheath to reduce the floor area.

The crushing mechanism is connected with the separating mechanism, and the separating mechanism is connected with the extrusion discharging mechanism.

As a further optimization of the technical scheme, the crushing mechanism of the vehicle-mounted camera cable processing equipment comprises a gear, a belt pulley, a belt, a motor belt pulley, a motor, a support leg, a driven gear, a belt shaft belt pulley, a transmission belt, a linkage belt pulley, a discharge pipe, an air cavity, an air outlet, an L-shaped plate, a belt shaft belt pulley A, a belt I, a crusher shell, a raw material inlet, a belt pulley I, a hydraulic cylinder, a cutter wheel shaft, a cutter wheel, a toothed rotating ring, a cutting ring, a gear A, a gear B, a belt shaft cutter wheel, an impeller and a matching groove, wherein the gear is connected with the belt pulley, the belt pulley is in friction connection with the belt pulley, the belt pulley is connected with the motor, the support leg is connected with the crusher shell, the gear is meshed with the driven gear, the driven gear is connected with the belt shaft belt pulley, and the, the driving belt is in friction connection with the linkage belt pulley, the linkage belt pulley is connected with a belt shaft belt pulley A, the belt shaft belt pulley A is in rotation connection with the crusher shell, an air cavity is connected with the crusher shell, an air outlet and a matching groove are arranged on the air cavity, the matching groove is in sliding connection with an L-shaped plate, the L-shaped plate is connected with a hydraulic cylinder, the hydraulic cylinder is connected with the air cavity, the belt shaft belt pulley A is in friction connection with a belt I, the belt I is in friction connection with a belt pulley I, a raw material inlet is arranged on the crusher shell, a gear is connected with a cutter wheel shaft, the cutter wheel shaft is in rotation connection with the crusher shell, the cutter wheel shaft is connected with a cutter wheel, the toothed rotating ring is in rotation connection with the crusher shell, the toothed rotating ring is connected with a ring cutter, the gear A is engaged with the toothed rotating ring, the gear A is engaged with a gear B, the gear B is connected, the impeller is connected with a belt pulley A with a shaft.

As a further optimization of the technical scheme, the separation mechanism of the vehicle-mounted camera cable treatment equipment comprises a base, a separation box, a plastic outlet, a transfer pipe, a copper wire collection box, an air outlet, a gear I with a shaft, a sliding rack with a step seat, a step groove, a filter plate, a groove wheel, a servo motor, a belt A, a groove wheel I, a cleaning port, a separation inlet, a filter plate A, a separating wheel with a shaft, a wind wheel, an air inlet, a coupler, a wind power motor, a discharge plate, a lead screw and a threaded hole, wherein the motor and a support leg are connected with the base, the base is connected with the separation box, the separation box is provided with the plastic outlet, the separation box is communicated with the copper wire collection box through the transfer pipe, the copper wire collection box is provided with the air outlet, the gear I with the shaft is connected with the discharge plate, the gear I with the copper wire collection box is rotatably connected with the copper, the sliding rack with the stepped seat is connected with the stepped groove in a sliding way, the stepped groove is arranged on two sides of the copper wire collecting box, the filter plate is connected with the copper wire collecting box in a sliding way, the grooved wheel is connected with the servo motor, the servo motor is connected with the copper wire collecting box, the grooved wheel is connected with the belt A in a friction way, the belt A is connected with the grooved wheel I in a friction way, both the grooved wheel I and the grooved wheel are connected with the lead screw, the lead screw is connected with the copper wire collecting box in a rotating way, the lead screw is connected with the threaded hole in, the separation entry all sets up on the separator box, and the clearance mouth is linked together with the air outlet, and the separation entry is linked together with the discharging pipe, and filter plate A links to each other with the separator box, and filter plate A rotates with the belt shaft separating wheel to be connected, is equipped with the wind wheel on the belt shaft separating wheel, and the wind entry sets up on the separator box, and belt shaft separating wheel passes through the shaft coupling with the wind-driven generator and links to each other, and the play flitch contacts with copper line collecting box.

As a further optimization of the technical scheme, the extrusion discharging mechanism of the vehicle-mounted camera cable processing equipment comprises an extrusion outlet, an extrusion box, an extrusion inlet, an extrusion coupling, an extrusion motor, a force transmission shaft, a wind wheel a and an extrusion screw, wherein the extrusion outlet is arranged on the extrusion box, the extrusion box is provided with the extrusion inlet, the extrusion inlet is communicated with a plastic outlet, the extrusion motor is connected with the force transmission shaft through the extrusion coupling, the force transmission shaft is rotatably connected with the extrusion box, the extrusion box is connected with a base, and the force transmission shaft is provided with the wind wheel a and the extrusion screw.

As further optimization of the technical scheme, the extrusion screw of the vehicle-mounted camera cable processing equipment is made of high manganese steel.

The vehicle-mounted camera cable processing equipment has the beneficial effects that:

according to the vehicle-mounted camera cable processing equipment, the equipment can crush, the equipment can separate the copper wire and the cable sheath, the equipment can discharge the copper wire, and the equipment can extrude and discharge the cable sheath to reduce the floor area.

Drawings

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

Fig. 1 is a first structural schematic diagram of a vehicle-mounted camera cable processing device according to the present invention.

Fig. 2 is a schematic structural diagram of a vehicle-mounted camera cable processing device according to a second embodiment of the invention.

Fig. 3 is a schematic structural diagram of a vehicle-mounted camera cable processing device according to a third embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a vehicle-mounted camera cable processing device according to a fourth embodiment of the present invention.

Fig. 5 is a first structural schematic diagram of the crushing mechanism 1 of the vehicle-mounted camera cable processing equipment.

Fig. 6 is a schematic structural diagram of a crushing mechanism 1 of the vehicle-mounted camera cable processing equipment according to the second embodiment of the invention.

Fig. 7 is a third schematic structural diagram of the crushing mechanism 1 of the vehicle-mounted camera cable processing equipment.

Fig. 8 is a fourth schematic structural diagram of the crushing mechanism 1 of the vehicle-mounted camera cable processing device according to the invention.

Fig. 9 is a fifth schematic structural diagram of the crushing mechanism 1 of the vehicle-mounted camera cable processing device according to the invention.

Fig. 10 is a first structural schematic diagram of the separation mechanism 2 of the vehicle-mounted camera cable processing device of the invention.

Fig. 11 is a second schematic structural diagram of the separating mechanism 2 of the vehicle-mounted camera cable processing device according to the invention.

Fig. 12 is a third schematic structural diagram of the separating mechanism 2 of the vehicle-mounted camera cable processing device according to the invention.

Fig. 13 is a fourth schematic structural diagram of the separation mechanism 2 of the vehicle-mounted camera cable processing apparatus according to the present invention.

Fig. 14 is a fifth schematic structural diagram of the separation mechanism 2 of the vehicle-mounted camera cable processing device according to the present invention.

Fig. 15 is a first structural schematic diagram of the extrusion discharging mechanism 3 of the vehicle-mounted camera cable processing equipment.

Fig. 16 is a second structural schematic diagram of the extrusion discharging mechanism 3 of the vehicle-mounted camera cable processing equipment.

In the figure: a crushing mechanism 1; gear 1-1; 1-2 of belt pulleys; 1-3 of a belt; 1-4 of a motor belt pulley; 1-5 of a motor; 1-6 of supporting legs; 1-7 of driven gears; belt pulley 1-8 with shaft; 1-9 of a transmission belt; 1-10 of a linkage belt pulley; 1-11 parts of a discharge pipe; 1-12 of a wind cavity; air outlets 1-13; 1-14 parts of L-shaped plates; belt shaft pulley A1-15; belt I1-16; a pulverizer housing 1-17; a raw material inlet 1-18; pulley I1-19; 1-20 parts of hydraulic cylinder; a cutter arbor 1-21; 1-22 parts of a cutter wheel; toothed rotating rings 1-23; 1-24 parts of cutting ring; gear a 1-25; gear B1-26; knife wheels with shafts 1-27; impellers 1-28; 1-29 of matching groove; a separation mechanism 2; a base 2-1; a separation tank 2-2; 2-3 of plastic outlet; 2-4 of a transfer pipe; 2-5 parts of a copper wire collection box; 2-6 of an air outlet; a belt shaft gear I2-7; 2-8 of a sliding rack with a step seat; 2-9 parts of a stepped groove; 2-10 parts of a filter plate; 2-11 grooved wheels; 2-12 of a servo motor; belt A2-13; sheave I2-14; cleaning the opening 2-15; separation inlets 2-16; filter plates A2-17; separating wheel with shaft 2-18; 2-19 of wind wheel; 2-20 of an air inlet; 2-21 of a coupler; 2-22 of a wind motor; 2-23 parts of a discharge plate; 2-24 parts of a lead screw; 2-25 parts of a threaded hole; an extrusion discharging mechanism 3; an extrusion outlet 3-1; 3-2 of an extrusion box; 3-3 of an extrusion inlet; 3-4, extruding the coupler; 3-5 of an extrusion motor; 3-6 of a force transmission shaft; wind wheel A3-7; and 3-8 of extruding screws.

Detailed Description

The first embodiment is as follows:

the present embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, and fig. 16, the present invention relates to a cable processing apparatus, and more specifically, to a vehicle-mounted camera cable processing apparatus, which includes a crushing mechanism 1, a separating mechanism 2, and an extrusion discharging mechanism 3, the apparatus is capable of crushing, separating a copper wire and a cable sheath, discharging the copper wire, and extruding and discharging the cable sheath to reduce a floor area.

The crushing mechanism 1 is connected with the separating mechanism 2, and the separating mechanism 2 is connected with the extrusion discharging mechanism 3.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, and the embodiment is further described, wherein the pulverizing mechanism 1 comprises a gear 1-1, a pulley 1-2, a belt 1-3, a motor pulley 1-4, a motor 1-5, a leg 1-6, a driven gear 1-7, a belt pulley 1-8, a driving belt 1-9, a linkage pulley 1-10, a discharging pipe 1-11, an air cavity 1-12, an air outlet 1-13, an L-shaped plate 1-14, a belt pulley a1-15, a belt I1-16, a pulverizer housing 1-17, a raw material inlet 1-18, a pulley I1-19, a water outlet 1-13, an air outlet 1-14, a, 1-20 parts of hydraulic cylinder, 1-21 parts of cutter wheel shaft, 1-22 parts of cutter wheel, 1-23 parts of rotating ring with teeth, 1-24 parts of cutting ring, A1-25 parts of gear A, B1-26 parts of gear B, 1-27 parts of cutter wheel with shaft, 1-28 parts of impeller and 1-29 parts of matching groove, wherein the gear 1-1 is connected with the pulley 1-2 part of belt wheel, the pulley 1-2 part of belt wheel is connected with the belt 1-3 part of belt wheel, the belt 1-3 part is connected with the pulley 1-4 part of motor wheel, the pulley 1-4 part of motor wheel is connected with the motor 1-5 part of belt wheel, the supporting leg 1-6 part is connected with the crusher shell 1-17 part, the gear 1-1 part is engaged with the driven gear 1-7 part, the driven gear 1-7 part is connected with the pulley 1, the transmission belt 1-9 is in frictional connection with the linkage belt pulley 1-10, the linkage belt pulley 1-10 is connected with the belt shaft belt pulley A1-15, the belt shaft belt pulley A1-15 is in rotational connection with the crusher shell 1-17, the air cavity 1-12 is connected with the crusher shell 1-17, the air cavity 1-12 is provided with an air outlet 1-13 and a matching groove 1-29, the matching groove 1-29 is in sliding connection with the L-shaped plate 1-14, the L-shaped plate 1-14 is connected with the hydraulic cylinder 1-20, the hydraulic cylinder 1-20 is connected with the air cavity 1-12, the belt shaft belt pulley A1-15 is in frictional connection with the belt I1-16, the belt I1-16 is in frictional connection with the belt pulley I1-19, the raw material inlet 1-18 is arranged on the crusher shell 1-17, the gear 1-1 is connected with the knife wheel shaft 1, the cutter wheel shafts 1-21 are rotationally connected with the crusher shell 1-17, the cutter wheel shafts 1-21 are connected with the cutter wheels 1-22, the toothed rotating rings 1-23 are rotationally connected with the crusher shell 1-17, the toothed rotating rings 1-23 are connected with the cutting rings 1-24, the gears A1-25 are meshed with the toothed rotating rings 1-23, the gears A1-25 are meshed with the gears B1-26, the gears B1-26 are connected with the cutter wheels with shafts 1-27, the cutter wheels with shafts 1-27 are rotationally connected with the crusher shell 1-17, the cutter wheels with shafts 1-27 are connected with the belt pulleys I1-19, the impellers 1-28 are connected with the belt pulleys A1-15, waste cables are put into the crusher shell 1-17 from the raw material inlets 1-18, the running motors 1-5 drive the motor pulleys 1-4 to rotate, the motor belt pulley 1-4 can drive the belt pulley 1-2 to rotate through the belt 1-3, the belt pulley 1-2 can drive the gear 1-1 to rotate, the gear 1-1 can drive the cutter wheel 1-22 to rotate through the cutter wheel shaft 1-21, meanwhile, the gear 1-1 can drive the driven gear 1-7 to rotate, the driven gear 1-7 can drive the belt shaft belt pulley A1-15 to rotate through the belt shaft belt pulley 1-8, the transmission belt 1-9 and the transmission belt of the linkage belt pulley 1-10, the belt shaft belt pulley A1-15 can drive the belt shaft cutter wheel 1-27 to rotate through the belt I1-16 and the transmission belt of the belt pulley I1-19, the rotation of the belt shaft cutter wheel 1-27 and the cutter wheel 1-22 is reverse, so that the grinding can be respectively realized during the rotation process, when materials pass through the space between the cutter wheel 1-27 with the shaft and the cutter wheel 1-22, the materials are sheared, the crushing effect is enhanced, meanwhile, the cutter wheel 1-27 with the shaft drives the rotating ring 1-23 with teeth to rotate through the transmission of the gear B1-26 and the gear A1-25, the rotating ring 1-23 with teeth drives the cutting ring 1-24 to do circular motion, and therefore the effect of auxiliary crushing is achieved, the multi-dimensional crushing synergy can be achieved on the whole, and the crushing efficiency is improved.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, and fig. 16, and is further described in the present embodiment, where the separating mechanism 2 includes a base 2-1, a separating tank 2-2, a plastic outlet 2-3, a transfer pipe 2-4, a copper wire collecting tank 2-5, an air outlet 2-6, a gear with a shaft I2-7, a sliding rack with a stepped seat 2-8, a stepped groove 2-9, a filter plate 2-10, a grooved wheel 2-11, a servo motor 2-12, a belt a2-13, a grooved wheel I2-14, a cleaning port 2-15, a separating inlet 2-16, a filter plate a2-17, a separating wheel with a shaft 2-18, a wind wheel 2-19, 2-20 parts of an air inlet, 2-21 parts of a coupler, 2-22 parts of an air motor, 2-23 parts of a discharge plate, 2-24 parts of a lead screw and 2-25 parts of a threaded hole, 1-5 parts of a motor and 1-6 parts of a support leg are all connected with a base 2-1, the base 2-1 part is connected with a separation box 2-2, a plastic outlet 2-3 is arranged on the separation box 2-2, the separation box 2-2 is communicated with a copper wire collection box 2-5 through a transfer pipe 2-4, an air outlet 2-6 is arranged on the copper wire collection box 2-5, a gear I2-7 with a shaft is connected with the discharge plate 2-23, a gear I2-7 with a shaft is rotatably connected with the copper wire collection box 2-5, a gear I2-7 with a sliding rack with a stepped seat is meshed with the sliding rack 2-8 with the stepped seat, and a, step grooves 2-9 are arranged at two sides of a copper wire collecting box 2-5, filter plates 2-10 are in sliding connection with the copper wire collecting box 2-5, grooved wheels 2-11 are connected with servo motors 2-12, servo motors 2-12 are connected with the copper wire collecting box 2-5, grooved wheels 2-11 are in friction connection with belts A2-13, belts A2-13 are in friction connection with grooved wheels I2-14, grooved wheels I2-14 and grooved wheels 2-11 are connected with lead screws 2-24, the lead screws 2-24 are in rotational connection with the copper wire collecting box 2-5, the lead screws 2-24 are in rotational connection with threaded holes 2-25, threaded holes 2-25 are arranged on a sliding rack 2-8 with a step seat, cleaning ports 2-15 and separating inlets 2-16 are arranged on a separating box 2-2, the cleaning port 2-15 is communicated with the air outlet 1-13, the separation inlet 2-16 is communicated with the discharge pipe 1-11, the filter plate A2-17 is connected with the separation box 2-2, the filter plate A2-17 is rotationally connected with the separation wheel 2-18 with the shaft, the separation wheel 2-18 with the shaft is provided with the wind wheel 2-19, the wind inlet 2-20 is arranged on the separation box 2-2, the separation wheel 2-18 with the shaft is connected with the wind motor 2-22 through the coupling 2-21, the discharge plate 2-23 is contacted with the copper wire collection box 2-5, the wind motor 2-22 is operated to drive the separation wheel 2-18 with the shaft to rotate, the separation wheel 2-18 with the shaft drives the wind wheel 2-19 to rotate, the wind wheel 2-19 can form upward gas flow, thereby forming a negative pressure state under the wind wheel 2-19, the crushed materials are sucked into a separation box 2-2 through a discharge pipe 1-11 and then move upwards, copper wires pass through a filter plate A2-17 and enter a copper wire collection box 2-5 along a transfer pipe 2-4, then wind is discharged from a wind outlet 2-6, the copper wires are retained in the copper wire collection box 2-5 due to the blocking effect of the filter plate 2-10, cable sheaths rotate along with a separation wheel 2-18 with a shaft, a synchronous operation extrusion motor 3-5 drives an extrusion coupler 3-4 to rotate, the extrusion coupler 3-4 drives a wind wheel A3-7 to rotate through a force transmission shaft 3-6, so that negative pressure is formed at an extrusion inlet 3-3, and when the cable sheaths rotating along with the separation wheel 2-18 with the shaft move to a communication position between a plastic outlet 2-3 and the separation box 2-2, the cable sheaths are sucked by the negative pressure formed at the extrusion inlet 3-3, the copper wire is sucked into the extrusion box 3-2, when the copper wire needs to be poured, the servo motor 2-12 can be operated to drive the grooved pulley 2-11 to rotate, the grooved pulley 2-11 can drive the grooved pulley I2-14 to synchronously rotate through the belt A2-13, the grooved pulley 2-11 and the grooved pulley I2-14 can drive the screw rod 2-24 to rotate, the screw rod 2-24 can drive the sliding rack with the stepped seat 2-8 to move through matching with the threaded hole 2-25, the sliding rack with the stepped seat 2-8 can drive the gear with the shaft I2-7 to rotate 180 degrees, and the gear with the shaft I2-7 can drive the discharge plate 2-23 to rotate 180 degrees, so that the copper wire is poured out.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, and fig. 16, and the embodiment further describes the embodiment, where the extrusion discharging mechanism 3 includes an extrusion outlet 3-1, an extrusion box 3-2, an extrusion inlet 3-3, an extrusion coupler 3-4, an extrusion motor 3-5, a force transmission shaft 3-6, a wind wheel a3-7, an extrusion screw 3-8, the extrusion outlet 3-1 is disposed on the extrusion box 3-2, the extrusion box 3-2 is provided with the extrusion inlet 3-3, the extrusion inlet 3-3 is communicated with the plastic outlet 2-3, the extrusion motor 3-5 is connected with the force transmission shaft 3-6 through the extrusion coupler 3-4, the force transmission shaft 3-6 is rotatably connected with the extrusion box 3-2, the extrusion box 3-2 is connected with the base 2-1, the wind wheel A3-7 and the extrusion screw 3-8 are arranged on the force transmission shaft 3-6, the extrusion screw 3-8 is driven to rotate when the force transmission shaft 3-6 rotates, materials sucked by the wind wheel A3-7 are conveyed to the extrusion outlet 3-1, and the extrusion outlet 3-1 is smaller, so certain extrusion is achieved in the conveying process, and the occupied area is reduced.

The fifth concrete implementation mode:

the present embodiment will be described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, and fig. 16, and the first embodiment will be further described, in which the material of the extrusion spirals 3 to 8 is high manganese steel.

The working principle of the device is as follows: the equipment can crush, waste cables are placed into a crusher shell 1-17 from a raw material inlet 1-18, a motor 1-5 is operated to drive a motor belt pulley 1-4 to rotate, the motor belt pulley 1-4 drives a belt pulley 1-2 to rotate through a belt 1-3, the belt pulley 1-2 drives a gear 1-1 to rotate, the gear 1-1 drives a knife flywheel 1-22 to rotate through a knife flywheel shaft 1-21, meanwhile, the gear 1-1 drives a driven gear 1-7 to rotate, the driven gear 1-7 drives a belt shaft pulley A1-15 through a belt shaft pulley 1-8, a transmission belt 1-9 and a transmission belt of a linkage belt pulley 1-10 to rotate, the belt shaft pulley A1-15 can rotate through a belt I1-16, The transmission belt of the belt pulley I1-19 drives the cutter wheel 1-27 with the belt shaft to rotate, the rotation of the cutter wheel 1-27 with the belt shaft and the rotation of the cutter wheel 1-22 with the belt shaft are reverse, so that the grinding effect can be enhanced when the materials pass through the space between the cutter wheel 1-27 with the belt shaft and the cutter wheel 1-22, meanwhile, the cutter wheel 1-27 with the belt shaft can drive the rotating ring 1-23 with teeth to rotate through the transmission of the gear B1-26 and the gear A1-25, and the rotating ring 1-23 with teeth can drive the ring cutter 1-24 to do circular motion, so that the auxiliary grinding effect is achieved, the multi-dimensional grinding synergy can be realized on the whole, and the grinding efficiency is improved; the device can separate copper wires and cable sheaths, the wind power motor 2-22 is operated to drive the separation wheel 2-18 with a shaft to rotate, the separation wheel 2-18 with the shaft drives the wind wheel 2-19 to rotate, the wind wheel 2-19 can form upward gas flow, so that a negative pressure state is formed below the wind wheel 2-19, crushed materials are sucked into the separation box 2-2 through the discharge pipe 1-11 and then move upwards, the copper wires can penetrate through the filter plate A2-17 and enter the collection box 2-5 along the transfer pipe 2-4 and then are discharged from the wind outlet 2-6, the copper wires are retained in the copper wire collection box 2-5 due to the blocking effect of the filter plate 2-10, the cable sheaths can rotate along with the separation wheel 2-18 with the shaft, the synchronous operation extrusion motor 3-5 drives the extrusion coupling 3-4 to rotate, the extrusion coupler 3-4 drives the wind wheel A3-7 to rotate through the force transmission shaft 3-6, so that negative pressure is formed at the extrusion inlet 3-3, and when a cable leather rotating along with the separation wheel 2-18 with the shaft moves to the communication position of the plastic outlet 2-3 and the separation box 2-2, the cable leather is attracted by the negative pressure formed at the extrusion inlet 3-3 and is sucked into the extrusion box 3-2; the device can discharge a copper wire, when the copper wire needs to be poured, the servo motor 2-12 can be operated to drive the grooved pulley 2-11 to rotate, the grooved pulley 2-11 can drive the grooved pulley I2-14 to synchronously rotate through the belt A2-13, the grooved pulley 2-11 and the driven grooved pulley I2-14 can drive the screw rod 2-24 to rotate, the screw rod 2-24 can drive the sliding rack with the stepped seat 2-8 to move through matching with the threaded hole 2-25, the sliding rack with the stepped seat 2-8 can drive the gear with the shaft I2-7 to rotate 180 degrees, and the gear with the shaft I2-7 can drive the discharge plate 2-23 to rotate 180 degrees, so that the copper wire is poured out; the device can extrude and discharge the cable sheath to reduce the occupied area, the force transmission shaft 3-6 can drive the extrusion screw 3-8 to rotate when rotating, and materials attracted by the wind wheel A3-7 are conveyed to the extrusion outlet 3-1, and the extrusion outlet 3-1 is smaller, so that certain extrusion is received in the conveying process, and the occupied area is reduced.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (5)

1. The utility model provides an on-vehicle camera cable treatment facility, includes rubbing crusher constructs (1), separating mechanism (2), extrusion discharge mechanism (3), its characterized in that: the crushing mechanism (1) is connected with the separating mechanism (2), and the separating mechanism (2) is connected with the extrusion discharging mechanism (3).

2. The in-vehicle camera cable processing apparatus according to claim 1, characterized in that: the crushing mechanism (1) comprises a gear (1-1), a belt pulley (1-2), a belt (1-3), a motor belt pulley (1-4), a motor (1-5), supporting legs (1-6), a driven gear (1-7), a belt pulley with a shaft (1-8), a transmission belt (1-9), a linkage belt pulley (1-10), a discharge pipe (1-11), an air cavity (1-12), an air outlet (1-13), an L-shaped plate (1-14), a belt pulley with a shaft A (1-15), a belt I (1-16), a crushing machine shell (1-17), a raw material inlet (1-18), a belt pulley I (1-19), a hydraulic cylinder (1-20), a cutter wheel shaft (1-21), a cutter wheel (1-22), A toothed rotating ring (1-23), a cutting ring (1-24), a gear A (1-25), a gear B (1-26), a knife wheel with a shaft (1-27), an impeller (1-28) and a matching groove (1-29), wherein the gear (1-1) is connected with a belt pulley (1-2), the belt pulley (1-2) is connected with a belt (1-3) in a friction way, the belt (1-3) is connected with a motor belt pulley (1-4) in a friction way, the motor belt pulley (1-4) is connected with a motor (1-5), a support leg (1-6) is connected with a crusher shell (1-17), the gear (1-1) is meshed with a driven gear (1-7), the driven gear (1-7) is connected with a belt pulley with a shaft (1-8), the belt pulley with a shaft (1-8) is connected with a transmission belt (1-9) in a friction way, the transmission belt (1-9) is in frictional connection with the linkage belt pulley (1-10), the linkage belt pulley (1-10) is connected with the belt shaft belt pulley A (1-15), the belt shaft belt pulley A (1-15) is in rotational connection with the crusher shell (1-17), the air cavity (1-12) is connected with the crusher shell (1-17), the air cavity (1-12) is provided with an air outlet (1-13) and a matching groove (1-29), the matching groove (1-29) is in sliding connection with the L-shaped plate (1-14), the L-shaped plate (1-14) is connected with the hydraulic cylinder (1-20), the hydraulic cylinder (1-20) is connected with the air cavity (1-12), the belt shaft belt pulley A (1-15) is in frictional connection with the belt I (1-16), the belt I (1-16) is in frictional connection with the belt pulley I (1-19), the raw material inlet (1-18) is arranged on the crusher shell (1-17), the gear (1-1) is connected with the cutter wheel shaft (1-21), the cutter wheel shaft (1-21) is rotationally connected with the crusher shell (1-17), the cutter wheel shaft (1-21) is connected with the cutter wheel (1-22), the rotating ring with teeth (1-23) is rotationally connected with the crusher shell (1-17), the rotating ring with teeth (1-23) is connected with the cutting ring (1-24), the gear A (1-25) is meshed with the rotating ring with teeth (1-23), the gear A (1-25) is meshed with the gear B (1-26), the gear B (1-26) is connected with the cutter wheel with shaft (1-27), the cutter wheel with shaft (1-27) is rotationally connected with the crusher shell (1-17), the knife wheels (1-27) with shafts are connected with belt pulleys I (1-19), and the impellers (1-28) are connected with belt pulleys A (1-15) with shafts.

3. The in-vehicle camera cable processing apparatus according to claim 1, characterized in that: the separating mechanism (2) comprises a base (2-1), a separating box (2-2), a plastic outlet (2-3), a transfer pipe (2-4), a copper wire collecting box (2-5), an air outlet (2-6), a gear I (2-7) with a shaft, a sliding rack (2-8) with a stepped seat, a stepped groove (2-9), a filter plate (2-10), a grooved pulley (2-11), a servo motor (2-12), a belt A (2-13), a grooved pulley I (2-14), a cleaning port (2-15), a separating inlet (2-16), a filter plate A (2-17), a separating wheel (2-18) with a shaft, a wind wheel (2-19), an air inlet (2-20), a coupler (2-21), a wind motor (2-22), The copper wire separating device comprises a discharge plate (2-23), a screw rod (2-24) and threaded holes (2-25), a motor (1-5) and support legs (1-6) are connected with a base (2-1), the base (2-1) is connected with a separating box (2-2), a plastic outlet (2-3) is arranged on the separating box (2-2), the separating box (2-2) is communicated with a copper wire collecting box (2-5) through a transfer pipe (2-4), an air outlet (2-6) is arranged on the copper wire collecting box (2-5), a gear I (2-7) with a shaft is connected with the discharge plate (2-23), a gear I (2-7) with the shaft is rotationally connected with the copper wire collecting box (2-5), the gear I (2-7) with the shaft is meshed with a sliding rack (2-8) with a stepped seat, sliding racks (2-8) with stepped seats are connected with stepped grooves (2-9) in a sliding manner, the stepped grooves (2-9) are arranged on two sides of a copper wire collecting box (2-5), a filter plate (2-10) is connected with the copper wire collecting box (2-5) in a sliding manner, grooved wheels (2-11) are connected with servo motors (2-12), the servo motors (2-12) are connected with the copper wire collecting box (2-5), the grooved wheels (2-11) are connected with a belt A (2-13) in a friction manner, the belt A (2-13) is connected with the grooved wheels I (2-14) in a friction manner, the I (2-14) and the grooved wheels (2-11) are connected with lead screws (2-24), the lead screws (2-24) are rotationally connected with the copper wire collecting box (2-5), the lead screws (2-24) are rotationally connected with threaded holes (2-25), threaded holes (2-25) are arranged on a sliding rack (2-8) with a stepped seat, cleaning ports (2-15) and separating inlets (2-16) are arranged on a separating box (2-2), the cleaning ports (2-15) are communicated with air outlets (1-13), the separating inlets (2-16) are communicated with a discharge pipe (1-11), a filter plate A (2-17) is connected with the separating box (2-2), the filter plate A (2-17) is rotationally connected with a separating wheel (2-18) with a shaft, a wind wheel (2-19) is arranged on the separating wheel (2-18) with the shaft, a wind inlet (2-20) is arranged on the separating box (2-2), the separating wheel (2-18) with the shaft is connected with a wind motor (2-22) through a coupler (2-21), the discharging plate (2-23) is contacted with the copper wire collecting box (2-5).

4. The in-vehicle camera cable processing apparatus according to claim 1, characterized in that: the extrusion discharging mechanism (3) comprises an extrusion outlet (3-1), an extrusion box (3-2), an extrusion inlet (3-3), an extrusion coupler (3-4), an extrusion motor (3-5), a force transmission shaft (3-6), a wind wheel A (3-7) and an extrusion spiral (3-8), the extrusion outlet (3-1) is arranged on the extrusion box (3-2), the extrusion box (3-2) is provided with the extrusion inlet (3-3), the extrusion inlet (3-3) is communicated with the plastic outlet (2-3), the extrusion motor (3-5) is connected with the force transmission shaft (3-6) through the extrusion coupler (3-4), the force transmission shaft (3-6) is rotationally connected with the extrusion box (3-2), the extrusion box (3-2) is connected with a base (2-1), the force transmission shaft (3-6) is provided with a wind wheel A (3-7) and an extrusion screw (3-8).

5. The in-vehicle camera cable processing apparatus according to claim 4, characterized in that: the extrusion screw (3-8) is made of high manganese steel.

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