CN114496401B - Corrosion-resistant cable applied to new energy automobile and production equipment - Google Patents

Abstract

The invention discloses an anti-corrosion cable applied to a new energy automobile and production equipment, comprising a cable coiling machine, an extruder discharge port and a cooling mechanism, wherein the cable coiling machine is arranged corresponding to the extruder discharge port; the invention has the beneficial effects that the anti-corrosion cable applied to the new energy automobile adopts the double-layer outer skin and the armor layer of the hard plastic, the anti-corrosion performance of equipment is enhanced, and the production equipment of the anti-corrosion cable adopts the linear distance linkage driving assembly in a matched manner to synchronously drive the wire speed of the coiling machine, so that the cable traction is prevented from being changed in the processing process, and the cable is prevented from being broken.

Description

Corrosion-resistant cable applied to new energy automobile and production equipment

Technical Field

The invention relates to the technical field of new energy automobiles, in particular to an anti-corrosion cable applied to a new energy automobile and production equipment.

Background

Along with exploitation of petroleum and natural gas resources, the consumption speed of petrochemical resources is increased, and the application of automobiles is the most of the petrochemical resources, but the petrochemical resources are always consumed, and the petrochemical resources are required to be used as important production resources such as refining and the like, so that automobiles using new energy are generated, and charging piles are adopted to charge the automobiles for matching with the application of the new energy, the continuous voyage is provided for the automobiles, the circuit connection of the automobiles is mainly powered by cables, the existing cables are usually buried underground in the application process, the cables are easily corroded by various components below the ground in the application process, the cables are damaged, the existing protection mode is mainly protected by external rubber sheaths, the existing armor layer is mainly wrapped by steel materials, the corrosion and rust are easily generated after the sheaths are damaged, meanwhile, the existing cable processing process is mainly protected by wrapping extrusion, but the cable outlet rate is required to be kept consistent with the extrusion material, the existing cable output rate is mainly controlled by a motor, the cable coiling diameter is easily changed along with the cable coiling diameter, and the cable is not easily controlled by referring to the cable coiling rate.

Disclosure of Invention

The invention aims to solve the problems, designs an anti-corrosion cable applied to a new energy automobile and production equipment, and solves the problems of the prior background technology.

The technical scheme of the invention for achieving the purpose is as follows: the production equipment of the anti-corrosion cable applied to the new energy automobile comprises a cable coiling machine, an extruder discharge port and a cooling mechanism, wherein the cable coiling machine is arranged corresponding to the extruder discharge port;

the active pushing mechanism is suitable for conveying materials for the cable winder;

a linear distance linkage driving assembly is arranged between the cable coiling machine and the active pushing mechanism;

the cooling mechanism is provided with a constant-temperature water supplementing assembly;

the cable coiling machine is provided with a wiring and arranging structure;

the linear distance linkage driving assembly comprises: the device comprises a supporting plate, a rotating speed gear, a speed detecting shaft, a linear speed detector, a driving gear, a reducing gear, a driving motor and a servo controller;

one side of initiative push mechanism is connected with the backup pad, be provided with the speed gear in the backup pad, one side meshing of speed gear is connected with the speed gear that examines, the center of speed gear is connected with the speed axle that examines, the speed axle that examines is connected with linear velocity detector, the axle head of cable lap-former is provided with drive gear outward, one side of drive gear is provided with gear reduction and drive gear meshing, be connected with driving motor on the gear reduction, be provided with servo controller on the driving motor, servo controller is connected with linear velocity detector.

The number of teeth of the speed reducing gear is smaller than the number of teeth of the driving gear.

The active pushing mechanism comprises: the device comprises a supporting seat, a pair of fixing plates, a pair of slots, a pair of inserted rods, a connecting plate, a travelling motor, a driving roller, an adjusting screw seat and an adjusting screw rod;

the support seat is arranged between the cable lap former and the cooling mechanism, a pair of symmetrical fixing plates are arranged on the support seat, a pair of slots are respectively arranged on the fixing plates, a pair of inserting rods are arranged in the slots, the end parts of the inserting rods are provided with connecting plates, a travelling motor is arranged on the connecting plates, driving rollers are connected to the driving ends of the travelling motor, a pair of adjusting screw thread seats are arranged between the slots, adjusting screw threads are connected with adjusting screws, the end parts of the adjusting screws are movably connected with the connecting plates, and the diameters of the plate blocks with rectangular structures and the driving rollers are larger than the width of the connecting plates.

The wiring arrangement structure comprises: the device comprises a transverse moving rail, a transverse moving sliding block, a linear screw rod module and a threading groove;

the cable lapping machine is characterized in that a transverse moving rail is arranged on one side of the cable lapping machine, a transverse moving sliding block is arranged on the transverse moving rail, a linear screw rod module is arranged on the transverse moving rail, the transverse moving sliding block is assembled on the linear screw rod module, a wire penetrating groove is formed in the transverse moving sliding block, the wire penetrating groove is a long-strip-shaped plate block of a door-shaped structure, a through hole is formed in the center of the wire penetrating groove, and two ends of the through hole are slope-shaped notch openings respectively.

The cooling mechanism includes: the device comprises a cooling tank, two pairs of supporting legs, an upper water port, a water outlet, a control valve, a pair of sliding grooves, a door-shaped frame, a threaded rod, a threaded sleeve and a rolling wire wheel;

the cooling tank is installed between supporting seat and extruder discharge gate, the bottom surface of cooling tank is provided with two pairs of landing legs, the both ends of cooling tank are provided with upper water gap and delivery port respectively, be provided with control valve on delivery port and the upper water gap respectively, the both ends of cooling tank are provided with a pair of spout, are equipped with a door type frame in a pair of spout, the interior bottom surface of door type frame is provided with the threaded rod, the cover is equipped with the thread bush on the threaded rod, the bottom of thread bush is provided with the rolling wire wheel.

The constant temperature moisturizing subassembly includes: a cooling water tank, a driving water pump, a driving water pipe, a water return pipe and a cooler;

the cooling device is characterized in that a cooling water tank is arranged below the cooling water tank, one side of the cooling water tank is connected with a driving water pump, a driving water pipe is connected to the driving water pump, one end of the driving water pipe is connected to a water feeding port, a water return pipe is arranged on the water outlet and is connected with the cooling water tank, a temperature detector is arranged on the cooling water tank, and a cooler is arranged on one side of the cooling water tank.

The cooler is a plate cooler.

The utility model provides a be applied to new energy automobile's anticorrosion cable, includes cable inner core and cable sheath, the cable sheath parcel is on the cable inner core, be provided with the filling layer between cable inner core and the cable sheath, the outside parcel of filling layer has the hard plastics winding layer, the hard plastics winding layer is spiral structure and spirals outside the filling layer, the cable sheath is bilayer structure.

The cable sheath is of a double-layer structure, wherein the outer layer is a rubber anti-corrosion layer, and the inner layer is a woven reticular metal wire layer.

And a lining anti-corrosion layer is arranged between the filling layer and the hard plastic winding layer.

The anti-corrosion cable for the new energy automobile, which is manufactured by the technical scheme of the invention, adopts the double-layer outer skin and the armor layer of the hard plastic, so that the anti-corrosion performance of equipment is enhanced, and the production equipment of the anti-corrosion cable adopts the linear distance linkage driving assembly to synchronously drive the coiling machine at linear speed, so that the cable traction is prevented from being changed in the processing process, and the cable is prevented from being broken.

Drawings

Fig. 1 is a schematic diagram of a front view structure of a production device of an anti-corrosion cable applied to a new energy automobile.

Fig. 2 is a schematic side view of an active pushing mechanism of the production equipment of the anti-corrosion cable applied to the new energy automobile.

Fig. 3 is a schematic diagram of a front view structure of an active pushing mechanism of the production equipment of the anti-corrosion cable applied to the new energy automobile.

Fig. 4 is a schematic top view of an active pushing mechanism of the production equipment of the anti-corrosion cable applied to the new energy automobile.

Fig. 5 is a schematic side view of a cooling mechanism of the production equipment of the anti-corrosion cable applied to the new energy automobile.

Fig. 6 is a schematic diagram of a side view structure of a cable winder of the production equipment of the anti-corrosion cable applied to the new energy automobile.

Fig. 7 is a schematic view of a partially enlarged structure of a production device of an anti-corrosion cable applied to a new energy automobile.

Fig. 8 is a schematic diagram of a front cross-sectional structure of an anti-corrosion cable applied to a new energy automobile.

Fig. 9 is a schematic diagram of a front view structure of an anti-corrosion cable applied to a new energy automobile.

Fig. 10 is a schematic diagram of a side-view cross-sectional structure of an anti-corrosion cable applied to a new energy automobile according to the present invention.

In the figure: 1. a cable winder; 2. a discharge port of the extruder; 3. a support plate; 4. a rotational speed gear; 5. a speed detecting gear; 6. a speed detecting shaft; 7. a linear velocity detector; 8. a drive gear; 9. a reduction gear; 10. a driving motor; 11. a servo controller; 12. a support base; 13. a fixing plate; 14. a slot; 15. a rod; 16. a connecting plate; 17. a travel motor; 18. driving the roller; 19. adjusting the screw seat; 20. adjusting a screw; 21. a traversing rail; 22. a traversing slide block; 23. a linear screw rod module; 24. a wire penetrating groove; 25. a cooling tank; 26. a support leg; 27. a water feeding port; 28. a water outlet; 29. a control valve; 30. a chute; 31. a door-shaped frame; 32. a threaded rod; 33. a thread sleeve; 34. a rolling wire wheel; 35. a cooling water tank; 36. driving a water pump; 37. a driving water pipe; 38. a water return pipe; 39. a cooler; 40. a cable core; 41. a cable sheath; 42. a filling layer; 43. a hard plastic winding layer; 44. and (5) lining an anti-corrosion layer.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings, as shown in fig. 1 to 10.

All electric components in the scheme are connected with an adaptive power supply through wires by a person skilled in the art, and an appropriate controller is selected according to actual conditions so as to meet control requirements, specific connection and control sequences, and the electric connection is completed by referring to the following working principles in the working sequence among the electric components, wherein the detailed connection means are known in the art, and the following main description of the working principles and processes is omitted from the description of electric control.

Examples: according to the description, as shown in fig. 1-7, the production equipment for the anti-corrosion cable applied to the new energy automobile comprises a cable coiling machine 1, an extruder discharge port 2 and a cooling mechanism, wherein the cable coiling machine 1 is arranged corresponding to the extruder discharge port 2, the cooling mechanism is arranged between the extruder discharge port 2 and the cable coiling machine 1, one side of the cable coiling machine 1 is provided with an active pushing mechanism, in the specific implementation process, the cable coiling machine 1 is aligned to the extruder discharge port 2, the cable extruded by the extruder discharge port 2 is pushed out by the active pushing mechanism, and the cable is coiled by the cable coiling machine 1;

the active pushing mechanism is suitable for conveying materials for the cable winder 1 and pushing the cable to the cable winder 1 for winding;

a linear distance linkage driving assembly is arranged between the cable winder 1 and the active pushing mechanism and used for detecting the rotating speed of the active pushing mechanism and controlling the cable winder 1 to rotate;

the cooling mechanism is provided with a constant temperature water supplementing component and is used for cooling a cable from the discharge port 2 of the extruder, and meanwhile, water is supplemented for the cooling mechanism through the constant temperature water supplementing component;

the cable coiling machine 1 is provided with a wiring and arranging structure which can control coiled cables to perform horizontal position conversion;

as can be seen from fig. 1 to 7 of the specification, the linear distance linkage driving assembly includes: the connection and positional relationship of the support plate 3, the rotation speed gear 4, the speed detecting gear 5, the speed detecting shaft 6, the linear speed detector 7, the driving gear 8, the reduction gear 9, the driving motor 10 and the servo controller 11 are as follows;

one side of the active pushing mechanism is connected with a supporting plate 3, a rotating speed gear 4 is arranged on the supporting plate 3, one side of the rotating speed gear 4 is connected with a speed checking gear 5 in a meshed manner, the center of the speed checking gear 5 is connected with a speed checking shaft 6, the speed checking shaft 6 is connected with a linear speed detector 7, a driving gear 8 is arranged outside the shaft end of the cable lap former 1, one side of the driving gear 8 is provided with a reduction gear 9 which is meshed with the driving gear 8, a driving motor 10 is connected to the reduction gear 9, a servo controller 11 is arranged on the driving motor 10, and the servo controller 11 is connected with the linear speed detector 7;

in the specific implementation process, the rotating speed of the active pushing mechanism is detected through the rotating speed gear 4 on the supporting plate 3, and then the rotating speed gear 5 is meshed with the rotating speed gear 4, so that the rotating speed gear 5 drives the rotating speed shaft 6 to rotate, the rotating speed shaft 6 drives the linear speed detector 7 to drive, the rotating ring speed of the rotating speed shaft 6 is used for detecting the linear speed, the rotating speed of the driving motor 10 is controlled through the signal of the linear speed detector 7 by the servo controller 11, so that the synchronous linear speed is kept when the driving motor 10 drives the roller shaft to rotate, the tooth ratio of the rotating speed gear 4 and the rotating speed gear 5 is the same, the tooth number of the reducing gear 9 is smaller than the tooth number of the driving gear 8, the rotating speed gear 4 and the rotating speed gear 5 rotate at the same speed, and the reducing gear 9 adopts a small tooth ratio, so that the coiling speed can be controlled more finely.

As can be seen from fig. 1 to 7 of the specification, the active pushing mechanism includes: the supporting seat 12, the pair of fixing plates 13, the pair of slots 14, the pair of inserting rods 15, the connecting plate 16, the travelling motor 17, the driving roller 18, the adjusting screw seat 19 and the adjusting screw 20 are connected in the following manner;

the support seat 12 is arranged between the cable lap former 1 and the cooling mechanism, a pair of symmetrical fixing plates 13 are arranged on the support seat 12, a pair of slots 14 are respectively arranged on the pair of fixing plates 13, a pair of inserting rods 15 are arranged in the pair of slots 14, the end parts of the pair of inserting rods 15 are provided with connecting plates 16, a travelling motor 17 is arranged on the connecting plates 16, driving rollers 18 are connected to the driving ends of the travelling motor 17, an adjusting thread seat 19 is arranged between the pair of slots 14, an adjusting screw rod 20 is connected to the internal threads of the adjusting thread seat 19, the end parts of the adjusting screw rods 20 are movably connected with the connecting plates 16, the connecting plates 16 are rectangular plates, and the diameter of the driving rollers 18 is larger than the width of the connecting plates 16;

in a specific implementation process, a pair of fixing plates 13 are supported by a supporting seat 12, a pair of slots 14 are respectively arranged on the pair of fixing plates 13 and used for inserting a pair of inserting rods 15, an adjusting screw rod 20 can be meshed with an adjusting screw seat 19, and then a connecting plate 16 is driven to move relatively under the stabilization of the pair of inserting rods 15, so that a travelling motor 17 drives a driving roller 18 to squeeze two sides of a cable, and the cable travels to the cable winder 1 under the driving of the driving roller 18.

As can be seen from fig. 1 to 7 of the specification, the wiring structure includes: the connection and the positional relationship of the traversing rail 21, the traversing slide block 22, the linear screw rod module 23 and the threading groove 24 are as follows;

a transverse moving rail 21 is arranged on one side of the cable winder 1, a transverse moving sliding block 22 is arranged on the transverse moving rail 21, a linear screw rod module 23 is arranged on the transverse moving rail 21, the transverse moving sliding block 22 is assembled on the linear screw rod module 23, a threading groove 24 is arranged on the transverse moving sliding block 22, the threading groove 24 is a strip-shaped plate block with a door-shaped structure, a through hole is formed in the center of the threading groove, and two ends of the through hole are slope-shaped notch respectively;

in the specific implementation process, the traversing slide block 22 on the traversing rail 21 can be driven to slide through the linear screw rod module 23, and the traversing slide block moves linearly on the traversing rail 21 and moves linearly along the axial direction of the roll shaft of the cable coiling machine 1, so that the horizontal coiling position of the cable is changed through the wire through groove 24.

As can be seen from fig. 1 to 7 of the specification, the cooling mechanism comprises: the cooling tank 25, the two pairs of support legs 26, the water inlet 27, the water outlet 28, the control valve 29, the pair of sliding grooves 30, the door-shaped frame 31, the threaded rod 32, the threaded sleeve 33 and the rolling wire wheel 34 are connected in the following manner and are positioned in the following manner;

the cooling tank 25 is arranged between the supporting seat 12 and the discharge hole 2 of the extruder, two pairs of supporting legs 26 are arranged on the bottom surface of the cooling tank 25, an upper water port 27 and a water outlet 28 are respectively arranged at two ends of the cooling tank 25, control valves 29 are respectively arranged on the water outlet 28 and the upper water port 27, a pair of sliding grooves 30 are arranged at two ends of the cooling tank 25, a door-shaped frame 31 is assembled in the pair of sliding grooves 30, a threaded rod 32 is arranged on the inner bottom surface of the door-shaped frame 31, a thread bush 33 is sleeved on the threaded rod 32, and a rolling line wheel 34 is arranged at the bottom end of the thread bush 33;

in a specific implementation process, two pairs of supporting legs 26 are arranged on the bottom surface of the cooling tank 25, a water inlet 27 and a water outlet 28 are arranged on the cooling tank 25, the water inlet 27 is used for water supply and the water outlet 28 is used for water discharge, a control valve 29 can control the opening and closing of the water inlet 27 and the water outlet 28, the gate-shaped frame 31 can be subjected to position adjustment through the pair of sliding grooves 30, so that the rolling wire wheels 34 on the gate-shaped frame 31 are subjected to position movement, the position of the cable support is changed, the threaded rod 32 can be rotated to drive the threaded sleeve 33 to move up and down, and the rolling wire wheels 34 on the threaded sleeve 33 are driven to change in height.

As can be seen from fig. 1 to 7 of the specification, the constant temperature water replenishing assembly includes: a cooling water tank 35, a driving water pump 36, a driving water pipe 37, a water return pipe 38, and a cooler 39, which are connected to each other in the following manner and in the following positional relationship;

a cooling water tank 35 is arranged below the cooling water tank 25, one side of the cooling water tank 35 is connected with a driving water pump 36, a driving water pipe 37 is connected to the driving water pump 36, one end of the driving water pipe 37 is connected to the water inlet 27, a water return pipe 38 is arranged on the water outlet 28 and connected with the cooling water tank 35, a temperature detector is arranged on the cooling water tank 25, and a cooler 39 is arranged on one side of the cooling water tank 35.

In a specific implementation process, the cooler 39 is a plate cooler 39, which is used for reducing the temperature of the cooling water tank 35, and the driving water pump 36 connected with the cooling water tank 35 can be used for leading water into the water inlet 27 from the driving water pipe 37, so that the water supplementing to the cooling water tank 25 is completed, and the water after heat exchange is guided back into the cooling water tank 35 through the water return pipe 38.

As can be seen from fig. 8-10 of the specification, the present disclosure further discloses an anti-corrosion cable applied to a new energy automobile, which comprises a cable core 40 and a cable sheath 41, wherein the cable sheath 41 is wrapped on the cable core 40, a filling layer 42 is arranged between the cable core 40 and the cable sheath 41, a hard plastic winding layer 43 is wrapped outside the filling layer 42, the hard plastic winding layer 43 is spirally wound outside the filling layer 42, the cable sheath 41 is of a double-layer structure, in the specific implementation process, the cable core 40 is wrapped and protected by the cable sheath 41, a filling layer 42 is arranged between the cable core 40 and the cable sheath 41, the filling layer 42 is used for filling the cable sheath 41, the hard plastic winding layer 43 is arranged on the filling layer 42 for wrapping and protecting the cable core 40, and meanwhile, the hard plastic winding layer 43 is spirally wound on the filling layer 42, so that the problem of metal corrosion is avoided while the structural strength is improved.

The cable sheath 41 has a double-layer structure, wherein the outer layer is a rubber anti-corrosion layer, and the inner layer is a woven reticular metal wire layer, which are respectively used for corrosion prevention and scratch resistance improvement of the cable.

The inner lining anti-corrosion layer 44 is arranged between the filling layer 42 and the hard plastic winding layer 43, and the inner lining anti-corrosion layer 44 made of rubber material can further play a role in internal anti-corrosion, and even if the cable sheath 41 is damaged, the inner lining anti-corrosion layer can play a role in anti-corrosion.

In summary, the anti-corrosion cable applied to the new energy automobile adopts the double-layer outer skin and the armor layer of the hard plastic, so that the anti-corrosion performance of equipment is enhanced, and the production equipment of the anti-corrosion cable is matched with the linear distance linkage driving assembly to synchronously drive the wire speed of the coiling machine, so that the cable traction is prevented from being changed in the processing process, and the cable is prevented from being broken.

The above technical solution only represents the preferred technical solution of the present invention, and some changes that may be made by those skilled in the art to some parts of the technical solution represent the principles of the present invention, and the technical solution falls within the scope of the present invention.

Claims (5)

1. The production equipment of the anti-corrosion cable applied to the new energy automobile comprises a cable coiling machine (1), an extruder discharge port (2) and a cooling mechanism, wherein the cable coiling machine (1) and the extruder discharge port (2) are correspondingly arranged, and the cooling mechanism is arranged between the extruder discharge port (2) and the cable coiling machine (1), and is characterized in that an active pushing mechanism is arranged on one side of the cable coiling machine (1);

the active pushing mechanism is suitable for conveying materials for the cable winder (1);

a linear distance linkage driving assembly is arranged between the cable winder (1) and the active pushing mechanism;

the cooling mechanism is provided with a constant-temperature water supplementing assembly;

the cable coiling machine (1) is provided with a wiring and arranging structure;

the linear distance linkage driving assembly comprises: a supporting plate (3), a rotating speed gear (4), a speed detecting gear (5), a speed detecting shaft (6), a linear speed detector (7), a driving gear (8), a reducing gear (9), a driving motor (10) and a servo controller (11);

one side of the driving pushing mechanism is connected with a supporting plate (3), a rotating speed gear (4) is arranged on the supporting plate (3), one side of the rotating speed gear (4) is connected with a speed detecting gear (5) in a meshed mode, the center of the speed detecting gear (5) is connected with a speed detecting shaft (6), the speed detecting shaft (6) is connected with a linear speed detector (7), a driving gear (8) is arranged outside the shaft end of the cable coiling machine (1), a reduction gear (9) is arranged on one side of the driving gear (8) and meshed with the driving gear (8), a driving motor (10) is connected to the reduction gear (9), a servo controller (11) is arranged on the driving motor (10), and the servo controller (11) is connected with the linear speed detector (7);

the number of teeth of the rotating speed gear (4) is the same as the number of teeth of the speed detecting gear (5), and the number of teeth of the speed reducing gear (9) is smaller than the number of teeth of the driving gear (8);

the active pushing mechanism comprises: the device comprises a supporting seat (12), a pair of fixing plates (13), a pair of slots (14), a pair of inserting rods (15), a connecting plate (16), a travelling motor (17), a driving roller (18), an adjusting screw seat (19) and an adjusting screw (20);

the support seat (12) is arranged between the cable lap former (1) and the cooling mechanism, a pair of symmetrical fixing plates (13) are arranged on the support seat (12), a pair of slots (14) are respectively arranged on the pair of fixing plates (13), a pair of inserting rods (15) are arranged in the pair of slots (14), connecting plates (16) are arranged at the ends of the pair of inserting rods (15), a travelling motor (17) is arranged on the connecting plates (16), driving rollers (18) are connected to the driving ends of the travelling motor (17), an adjusting screw seat (19) is arranged between the pair of slots (14), an adjusting screw (20) is connected to the internal threads of the adjusting screw seat (19), the ends of the adjusting screw (20) are movably connected with the connecting plates (16), and the connecting plates (16) are rectangular plates and the diameters of the driving rollers (18) are larger than the widths of the connecting plates (16);

the wiring arrangement structure comprises: a traversing rail (21), a traversing slide block (22), a linear screw rod module (23) and a threading groove (24);

a transverse moving rail (21) is arranged on one side of the cable winder (1), a transverse moving sliding block (22) is arranged on the transverse moving rail (21), a linear screw rod module (23) is arranged on the transverse moving rail (21), the transverse moving sliding block (22) is assembled on the linear screw rod module (23), a threading groove (24) is formed in the transverse moving sliding block (22), the threading groove (24) is a strip-shaped plate block with a door-shaped structure, a through hole is formed in the center of the threading groove, and slope-shaped notch is formed in two ends of the through hole respectively;

the cooling mechanism includes: the cooling device comprises a cooling groove (25), two pairs of supporting legs (26), an upper water port (27), a water outlet (28), a control valve (29), a pair of sliding grooves (30), a door-shaped frame (31), a threaded rod (32), a threaded sleeve (33) and a rolling wire wheel (34);

the cooling tank (25) is arranged between the supporting seat (12) and the discharge hole (2) of the extruder, two pairs of supporting legs (26) are arranged on the bottom surface of the cooling tank (25), a water inlet (27) and a water outlet (28) are respectively arranged at two ends of the cooling tank (25), a control valve (29) is respectively arranged on the water outlet (28) and the water inlet (27), a pair of sliding grooves (30) are arranged at two ends of the cooling tank (25), a door-shaped frame (31) is assembled in the pair of sliding grooves (30), a threaded rod (32) is arranged on the inner bottom surface of the door-shaped frame (31), a thread sleeve (33) is sleeved on the threaded rod (32), and a rolling wire wheel (34) is arranged at the bottom end of the thread sleeve (33);

the constant temperature moisturizing subassembly includes: a cooling water tank (35), a driving water pump (36), a driving water pipe (37), a water return pipe (38), and a cooler (39);

the cooling water tank (35) is arranged below the cooling water tank (25), one side of the cooling water tank (35) is connected with a driving water pump (36), a driving water pipe (37) is connected to the driving water pump (36), one end of the driving water pipe (37) is connected to the water feeding port (27), a water return pipe (38) is arranged on the water outlet (28) and is connected with the cooling water tank (35), a temperature detector is arranged on the cooling water tank (25), and a cooler (39) is arranged on one side of the cooling water tank (35).

2. The production equipment of the anti-corrosion cable applied to the new energy automobile according to claim 1, wherein the cooler (39) is a plate cooler (39).

3. The cable manufactured by the production equipment of the anti-corrosion cable applied to the new energy automobile according to any one of claims 1-2, comprising a cable inner core (40) and a cable outer skin (41), wherein the cable outer skin (41) is wrapped on the cable inner core (40), a filling layer (42) is arranged between the cable inner core (40) and the cable outer skin (41), a hard plastic winding layer (43) is wrapped outside the filling layer (42), the hard plastic winding layer (43) is spirally wound outside the filling layer (42), and the cable outer skin (41) is of a double-layer structure.

4. A corrosion protection cable for a new energy vehicle according to claim 3, wherein the cable sheath (41) has a double layer structure in which the outer layer is a rubber corrosion protection layer and the inner layer is a woven mesh wire layer.

5. The anti-corrosion cable for new energy vehicles according to claim 4, wherein an inner lining anti-corrosion layer (44) is provided between the filler layer (42) and the hard plastic winding layer (43).