CN116705420A - Triaxial shielded cable manufacture equipment - Google Patents

Abstract

The invention discloses a triaxial shielded cable manufacturing device, which relates to the field of cable manufacturing and comprises a cleaning cabin, wherein a first wire inlet is arranged on the side wall of the cleaning cabin, and two groups of mounting plates are arranged on the side wall of one end of the cleaning cabin, which is far away from the first wire inlet. According to the invention, the cleaning mechanism is arranged, and the plurality of groups of spray heads in the cleaning mechanism are mutually matched, so that when a cable inner core enters the cleaning cabin through the first wire inlet, water flows through the first water inlet pipe and then is sprayed out at high pressure through the spray heads, the cable inner core is cleaned, meanwhile, when the water flows through the turbofan, the turbofan can be driven to rotate, so that the spray heads are driven to rotate, namely, the spray heads spray water, so that the water can flush the cable inner core in all directions, and then the cable inner core is brushed through the cable brush, the cleaning effect is further improved, the cleaned water can be used for a second time through the filtering layer, and the tight fit between the insulating layer wrapped outside the cable and the cable is ensured.

Description

Triaxial shielded cable manufacture equipment

Technical Field

The invention relates to the field of cable manufacturing, in particular to a triaxial shielding cable manufacturing device.

Background

The coaxial cable is a communication cable, the cable structure is to take solid copper body as core to wrap a layer of insulating material, this insulating material is surrounded by the net conductor of the dense weave, cover a layer of protective material again outside the net, there are two kinds of coaxial cables that are widely used one by one for the digital transmission, because it is used for baseband transmission to use for the most, also called baseband coaxial cable; the other is a 75 ohm cable for analog transmission.

The triaxial cable is composed of an inner core (main), an inner skin signal layer and an outer skin shielding layer. The inner core mainly transmits video signals and supplies power for the machine head, the inner core and the inner core form a loop, the outer layer is a shielding layer and a stratum, and the three-coaxial cable has the specification and characteristics that: the thickness specification of the triaxial cable has phi=8mm, 11mm and 14mm, and the diameter is thicker, so that the transmission distance is longer because of small transmission loss, and compared with a multi-core cable, the triaxial cable has simple structure and high reliability.

In the production process of the cable, plastic coating and insulation treatment are required to be carried out on the cable, so that the cable has good insulation performance, safety and reliability are realized, the outer insulation layer wrapping device for the existing cable processing cannot clean the outer surface of the cable, dust or sundries can be left outside the cable, and tight fit between the insulation layer wrapped outside the cable and the cable cannot be guaranteed.

Disclosure of Invention

Based on this, it is an object of the present invention to provide a triaxial shielded cable manufacturing apparatus to solve the technical problems set forth in the background above.

In order to achieve the above purpose, the present invention provides the following technical solutions: the manufacturing equipment of the triaxial shielded cable comprises a cleaning cabin, wherein a first wire inlet is arranged on the side wall of the cleaning cabin, two groups of mounting plates are arranged on the side wall of one end, far away from the first wire inlet, of the cleaning cabin, a shell is arranged at the end part of each of the two groups of mounting plates, and a cleaning mechanism is arranged on the inner wall of the cleaning cabin;

the cleaning mechanism comprises a first shunt tube, two groups of first shunt tubes are arranged on the outer wall of the cleaning cabin, a first water inlet pipe is communicated with the outer wall of the first shunt tube, two groups of first shunt tubes are respectively connected with the two ends of the first shunt tubes to the inside of the cleaning cabin, two groups of first shunt tubes are respectively connected with a spray head through rotation at one end of the inner part of the cleaning cabin, a filter layer is arranged below the plurality of groups of spray heads in the cleaning cabin, a water pump is arranged at the bottom end of the inner wall of the cleaning cabin, a second shunt tube is communicated with the bottom end of the first water pump, one end of the second shunt tube is respectively connected with the two groups of first shunt tubes, a cable brush is arranged on the inner wall of the cleaning cabin, and the inner diameter of the cable brush is smaller than that of a first wire inlet.

As a preferable technical scheme of the manufacturing equipment of the triaxial shielded cable, one end of each of the two groups of first shunt pipes extending to the inside of the cleaning cabin is provided with an annular groove, the end parts of the plurality of groups of spray heads are provided with annular slide rails, the outer walls of the annular slide rails are in sliding connection with the inner walls of the annular grooves, and the inner walls of the plurality of groups of spray heads are provided with turbofans.

As an optimal technical scheme of the triaxial shielded cable manufacturing equipment, the inner wall of the cleaning cabin is provided with the water removing mechanism, the water removing mechanism comprises a rack, one group of outer walls of the mounting plates are provided with a rack, the outer walls of the rack are provided with motors, the output ends of the motors penetrate through the outer walls of the rack and extend to the other side of the rack, the inner walls of the two groups of mounting plates are rotationally connected with two groups of rotating shafts, the end parts of one group of rotating shafts are fixedly connected with the output ends of the motors, the outer walls of the two groups of rotating shafts are fixedly sleeved with two groups of driving gears and two groups of driven gears respectively, the two groups of driven gears are meshed with the two groups of driving gears respectively, the outer walls of the two groups of driven gears are provided with a first transmission disc, the outer walls of the cleaning cabin are rotationally connected with two groups of second transmission discs, the outer walls of the two groups of second transmission discs are provided with transmission belts, the other ends of the transmission belts are connected to the outer walls of the first transmission discs, one ends of the two groups of the second transmission discs extend to the interior of the cleaning cabin, and one ends of the second transmission discs extend to the interior of the cleaning cabin are provided with a first bevel gear.

As an optimal technical scheme of the triaxial shielded cable manufacturing equipment, two groups of brackets are arranged on two sides of the inner wall of the cleaning cabin, the inner walls of the two groups of brackets are rotatably connected with a reciprocating screw rod, one end of the reciprocating screw rod extends to the outside of one group of brackets, one end of the reciprocating screw rod extending to the outside of one group of brackets is provided with a second bevel gear which is meshed with a first bevel gear, the outer walls of the two groups of reciprocating screw rods are in threaded connection with sliding rods, water absorbing sponge is arranged on the outer walls of the two groups of sliding rods, water squeezing plates are arranged on the outer walls of the two groups of brackets, and two groups of air guns are arranged on the inner wall of the cleaning cabin.

As an optimal technical scheme of the triaxial shielded cable manufacturing equipment, the outer walls of the two groups of rotating shafts are respectively fixedly sleeved with a driving disc and a driven disc.

As an optimal technical scheme of the triaxial shielded cable manufacturing equipment, the top end of the shell is provided with the insulating and wrapping mechanism, the insulating and wrapping mechanism comprises a glue melting machine, the outer wall of the glue melting machine is provided with a discharge pipe, one end of the discharge pipe is communicated with a third shunt pipe, two ends of the third shunt pipe extend into the shell respectively, the outer wall of the shell is provided with a second inlet pipe, the inner wall of the shell is provided with a wire passing pipe, the wire passing pipe is communicated with the second inlet pipe, the outer wall of the wire passing pipe is fixedly sleeved with a rubber wrapping pipe, the wire passing pipe is communicated with the rubber wrapping pipe, the end parts of the third shunt pipes are communicated with the rubber wrapping pipe, and the end parts of the wire passing pipes are communicated with conical pipes.

As an optimal technical scheme of the triaxial shielded cable manufacturing equipment, the end part of the conical tube is provided with the cooling shaping mechanism, the cooling shaping mechanism comprises the cooling tube, the end part of the conical tube is communicated with the cooling tube, one end of the cooling tube extends to the outside of the shell, the outer wall of the shell is provided with the water tank, and the water tank is positioned below the cooling tube.

As an optimal technical scheme of the triaxial shielded cable manufacturing equipment, the outer wall of the water tank is provided with the water row, and the outer wall of the water row is provided with the cooling fan.

As an optimal technical scheme of the triaxial shielded cable manufacturing equipment, a partition plate is arranged on the inner wall of the shell, a second water inlet pipe is communicated with the bottom end of the water tank, a second water pump is communicated with the end part of the second water inlet pipe, the second water pump is communicated with the shell, a water outlet pipe is communicated with the side wall of the shell, a third water pump is arranged on the side wall of the water row, the water outlet pipe is communicated with the third water pump, and a water outlet pipe is communicated with the side wall of the water row.

In summary, the invention has the following advantages:

1. according to the invention, the cleaning mechanism is arranged, and a plurality of groups of spray heads in the cleaning mechanism are mutually matched, so that when a cable inner core enters the cleaning cabin through a first wire inlet, water flows through the first water inlet pipe and then is sprayed out at high pressure through the spray heads, the cable inner core is cleaned, meanwhile, when the water flows through the turbofan, the turbofan can be driven to rotate, so that the spray heads are driven to rotate, namely, the water sprayed out of the spray heads can rotate, the cable inner core can be washed in all directions by the water flow, the cable inner core is brushed by the cable brush, the cleaning effect is further improved, the cleaned water can be used for a second time through the filtering layer, and the tight fit between the insulating layer wrapped outside the cable and the cable is ensured;

2. according to the invention, the water removing mechanism is arranged, and the water absorbing sponge, the water squeezing plate and the air gun are matched in the water removing mechanism, so that the water absorbing sponge can absorb water on the cable inner core, the air gun can blow the water on the cable inner core dry, and meanwhile, the driven wheel rotates to drive the water absorbing sponge to reciprocate left and right to squeeze the water on the water absorbing sponge through the water squeezing plate, so that the water absorbing sponge can absorb water continuously;

3. according to the invention, by arranging the insulating and wrapping mechanism and utilizing the mutual matching of the wire passing pipe, the rubber wrapping pipe and the conical pipe in the insulating and wrapping mechanism, when the cable inner core passes through the wire passing pipe, insulating rubber fluid in the rubber wrapping pipe can be attached to the cable inner core, and then the insulating layer colloid covered on the surface of the cable inner core is extruded through the gradually reduced conical groove, so that the compactness and uniformity of the insulating rubber fluid are improved;

4. according to the invention, by arranging the cooling shaping mechanism and utilizing the mutual matching of the partition plate, the water tank and the water row in the cooling shaping mechanism, when the cable inner core is arranged in the cooling pipe, the cooling water in the shell can carry out preliminary cooling shaping on the insulating glue fluid, so that the situation that the insulating layer is subjected to flowing deviation when not being cooled and solidified is prevented, and finally, the insulating layer enters the water tank to carry out final cooling shaping.

Drawings

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

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

FIG. 3 is a schematic view showing the internal structure of the cleaning cabin according to the present invention;

FIG. 4 is a schematic cross-sectional view of a cleaning chamber of the present invention;

FIG. 5 is an exploded view of the sprinkler of the present invention;

FIG. 6 is a schematic top view of the housing of the present invention;

fig. 7 is a schematic cross-sectional view of a housing of the present invention.

In the figure: 100. cleaning the cabin; 200. a cleaning mechanism; 300. a water removal mechanism; 400. an insulation wrapping mechanism; 500. cooling shaping mechanism

101. A first wire inlet; 102. a mounting plate; 103. a housing;

201. a first water inlet pipe; 202. a first shunt tube; 203. a spray head; 204. an annular groove; 205. an annular slide rail; 206. a turbofan; 207. a cable brush; 208. a filter layer; 209. a first water pump; 210. a second shunt tube;

301. a frame; 302. a motor; 303. a rotating shaft; 304. a driving disk; 305. a driven plate; 306. a drive gear; 307. a driven gear; 308. a first transmission disc; 309. a second transmission disc; 310. a transmission belt; 311. a first bevel gear; 312. a bracket; 313. a reciprocating screw rod; 314. a two-size bevel gear; 315. a slide bar; 316. a water absorbing sponge; 317. a wringing plate; 318. an air gun;

401. a glue melting machine; 402. a discharge pipe; 403. a third shunt tube; 404. a second wire inlet pipe; 405. a wire passing tube; 406. wrapping a rubber tube; 407. a conical tube;

501. a cooling tube; 502. a water tank; 503. a partition plate; 504. a second water inlet pipe; 505. a second water pump; 506. a water outlet pipe; 507. a third water pump; 508. a water drain; 509. a heat radiation fan; 510. and (5) a water drain pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the invention.

Hereinafter, an embodiment of the present invention will be described in accordance with its entire structure.

1-5, the manufacturing equipment of the triaxial shielded cable comprises a cleaning cabin 100, wherein a first wire inlet 101 is arranged on the side wall of the cleaning cabin 100, two groups of mounting plates 102 are arranged on the side wall of one end, far away from the first wire inlet 101, of the cleaning cabin 100, a shell 103 is arranged at the end part of each of the two groups of mounting plates 102, and a cleaning mechanism 200 is arranged on the inner wall of the cleaning cabin 100;

the cleaning mechanism 200 comprises a first shunt tube 202, two groups of first shunt tubes 202 are arranged on the outer wall of the cleaning cabin 100, a first water inlet pipe 201 is communicated with the outer wall of the first shunt tube 202, two ends of the first shunt tubes 202 extend to the inside of the cleaning cabin 100, one ends of the first shunt tubes 202 extending to the inside of the cleaning cabin 100 are rotationally connected with spray heads 203, a filter layer 208 is arranged below the spray heads 203 in the cleaning cabin 100, a first water pump 209 is arranged at the bottom end of the inner wall of the cleaning cabin 100, a second shunt tube 210 is communicated with the bottom end of the first water pump 209, one ends of the second shunt tubes 210 extend to the lower side of the cleaning cabin 100, two ends of the second shunt tubes 210 are respectively communicated with the first shunt tubes 202, a cable brush 207 is arranged on the inner wall of the cleaning cabin 100, the inner diameter of the cable brush 207 is smaller than the inner diameter of the first wire inlet 101, annular grooves 204 are formed in one ends of the first shunt tubes 202 extending to the inside of the cleaning cabin 100, annular slide rails 205 are arranged at the end parts of the spray heads 203, the outer walls of the annular slide rails 205 are in sliding connection with the inner walls of the annular slide rails 204, and the inner walls of the annular slide rails 205 are provided with the annular grooves 206.

When the cable inner core enters the cleaning cabin 100 through the first inlet port 101, water flows into the first shunt pipe 202 through the first inlet pipe 201, the first shunt pipe 202 enters the spray head 203, the spray head 203 sprays water at high pressure, thereby cleaning the cable inner core, meanwhile, when water flows through the vortex fan 206, the vortex fan 206 can be driven to rotate, thereby driving the spray head 203 to rotate, the annular groove 204 and the annular sliding rail 205 enable the spray head 203 to rotate at the end part of the first shunt pipe 202, namely, the water flow sprayed out by the spray head 203 rotates, so that the water flow can flush the cable inner core in all directions, the cable inner core can be scrubbed through the cable brush 207, the cleaning effect is further improved, the cable brush 207 can be flushed again by the spray head 203 after scrubbing, the cleaned water is filtered through the filter layer 208, and then the water is pumped through the first water pump 209 to enter the first shunt pipe 202 again, thereby realizing secondary utilization of water resources and saving the water resources.

Referring to fig. 1-4, the inner wall of the cleaning cabin 100 is provided with a water removing mechanism 300, the water removing mechanism 300 comprises a frame 301, the outer wall of one set of mounting plates 102 is provided with a frame 301, the outer wall of the frame 301 is provided with a motor 302, the output end of the motor 302 extends to the other side of the frame 301 through the outer wall of the frame 301, the inner walls of two sets of mounting plates 102 are rotatably connected with two sets of rotating shafts 303, the end part of one set of rotating shafts 303 is fixedly connected with the output end of the motor 302, the outer walls of the two sets of rotating shafts 303 are fixedly sleeved with two sets of driving gears 306 and two sets of driven gears 307 respectively, the two sets of driven gears 307 are meshed with the two sets of driving gears 306 respectively, the outer walls of the two sets of driven gears 307 are provided with a first driving disk 308, the outer wall of the cleaning cabin 100 is rotatably connected with two sets of second driving disks 309, the outer walls of the two sets of second driving disks 309 are provided with driving belts 310, the other end of the transmission belt 310 is connected with the outer wall of a first transmission disc 308, one end of two groups of second transmission discs 309 extend to the inside of the cleaning cabin 100, one end of the two groups of second transmission discs 309 extending to the inside of the cleaning cabin 100 is provided with a first bevel gear 311, two groups of brackets 312 are arranged on two sides of the inner wall of the cleaning cabin 100, the inner wall of the two groups of brackets 312 is rotationally connected with a reciprocating screw 313, one end of the reciprocating screw 313 extends to the outside of one group of brackets 312, one end of the reciprocating screw 313 extending to the outside of one group of brackets 312 is provided with a second bevel gear 314, the second bevel gear 314 is meshed with the first bevel gear 311, the outer walls of the two groups of reciprocating screw 313 are in threaded connection with sliding bars 315, the outer walls of the two groups of sliding bars 315 are provided with water absorbing sponges 316, the outer walls of the two groups of brackets 312 are provided with water squeezing plates 317, the inner wall of the cleaning cabin 100 is provided with two groups of air guns 318, the outer walls of the two sets of rotating shafts 303 are respectively fixedly sleeved with a driving disc 304 and a driven disc 305.

When the cleaned cable core moves between the two groups, the water absorbing sponge 316 can absorb the water on the cable core, when the cable core passes through the air gun 318, the air gun 318 can dry the water on the cable core, the motor 302 can drive one group of rotating shafts 303 to rotate, one group of rotating shafts 303 can be meshed with the driven gear 307 through the driving gear 306, the other group of rotating shafts 303 can be driven to reversely rotate, namely, the driving disc 304 and the driven disc 305 are meshed with the outer wall of the cable core, the cable core can be driven to move through friction force, meanwhile, the driven gear 307 can drive the first driving disc 308 to rotate, the first driving disc 308 drives the second driving disc 309 to rotate through the driving belt 310, the second driving disc 309 drives the first bevel gear 311 to rotate, the first bevel gear 311 drives the reciprocating screw 313 to rotate through the second bevel gear 314, the reciprocating screw 313 can drive the sliding rod 315 to transversely reciprocate, the 315 can drive the water absorbing sponge 316 to transversely reciprocate, and when the water absorbing sponge 316 is contacted with the water squeezing plate 317, the water absorbing sponge 316 can be squeezed by the water absorbing sponge 316 continuously.

Referring to fig. 1-7, an insulation wrapping mechanism 400 is arranged at the top end of a shell 103, the insulation wrapping mechanism 400 comprises a glue melting machine 401, a discharge pipe 402 is arranged on the outer wall of the glue melting machine 401, one end of the discharge pipe 402 is communicated with a third shunt pipe 403, two ends of the third shunt pipe 403 extend to the inside of the shell 103 respectively, a second inlet pipe 404 is arranged on the outer wall of the shell 103, a wire passing pipe 405 is arranged on the inner wall of the shell 103 and is communicated with the second inlet pipe 404, a rubber wrapping pipe 406 is fixedly sleeved on the outer wall of the wire passing pipe 405, the wire passing pipe 405 is communicated with the rubber wrapping pipe 406, the end portions of the third shunt pipe 403 are communicated with the rubber wrapping pipe 406, and a conical pipe 407 is communicated with the end portions of the wire passing pipe 405.

It should be noted that, the glue melting machine 401 is in the prior art, and will not be described in detail here, the glue melting machine 401 can melt the cable insulation glue particles into fluid through high temperature, when the cable inner core is driven by the driving disc 304 and the driven disc 305 to enter the wire passing tube 405, the insulation glue fluid in the rubber wrapping tube 406 can be attached to the cable inner core, and then the insulation layer colloid covered on the surface of the cable inner core is extruded through the tapered groove, so as to improve the compactness and uniformity of the insulation glue fluid.

Referring to fig. 1-7, the end of the conical tube 407 is provided with a cooling shaping mechanism 500, the cooling shaping mechanism 500 includes a cooling tube 501, the end of the conical tube 407 is communicated with the cooling tube 501, one end of the cooling tube 501 extends to the outside of the housing 103, the outer wall of the housing 103 is provided with a water tank 502, the water tank 502 is located below the cooling tube 501, the outer wall of the water tank 502 is provided with a water drain 508, the outer wall of the water drain 508 is provided with a cooling fan 509, the inner wall of the housing 103 is provided with a partition 503, the bottom end of the water tank 502 is communicated with a second water inlet pipe 504, the end of the second water inlet pipe 504 is communicated with a second water pump 505, the second water pump 505 is communicated with the housing 103, the side wall of the housing 103 is communicated with a water outlet pipe 506, the side wall of the water drain 508 is provided with a third water pump 507, and the side wall of the water drain 508 is communicated with a drain pipe 510.

When the cable inner core is in the cooling pipe 501, the cooling water in the shell 103 can perform preliminary cooling shaping on the insulating glue fluid, when the insulating layer is in an uncooled and solidified state, the situation of flowing deviation is prevented, finally, the insulating layer enters the water tank 502 for final cooling shaping, the second water pump 505 can drive water flow in the water tank 502 to enter the shell 103 through the water inlet pipe, the third water pump 507 can pump heated water flow in the shell 103 into the water row 508 through the water outlet pipe 506, the water row 508 is of an existing structure, the heated water flow is not excessively repeated, the contact area with air is increased when the heated water flow enters the water row 508, the heat is radiated through blowing of the cooling fan 509, the heated water flow can be cooled down, the water flow enters the water tank 502 through the water outlet pipe 510, the temperature rise of the water flow in the shell 103 and the water tank 502 can be prevented, the cooling shaping effect is affected, and the water flow is separated from the insulating packaging mechanism 400 through the arrangement of the partition plate 503.

When in use, when a cable inner core enters the cleaning cabin 100 through the first water inlet 101, water flows through the first water inlet 201 and then is sprayed out at high pressure through the spray head 203, so that the cable inner core is cleaned, meanwhile, when the water flows through the turbofan 206, the turbofan 206 can be driven to rotate, so that the spray head 203 is driven to rotate, the spray head 203 sprays out water, so that the water can flush the cable inner core in all directions, the cable inner core is scrubbed by the cable brush 207, the cleaning effect is further improved, the cleaned water can be filtered by the filter layer 208 and used for a second time, the tight fit between an insulating layer wrapped outside the cable and the cable is ensured, the water on the cable inner core can be adsorbed by the water absorbing sponge 316, the water on the cable inner core can be dried by the air gun 318, meanwhile, the driven wheel rotates to drive the water absorbing sponge 316 to reciprocate left and right to squeeze water on the water absorbing sponge 316 through the squeezing plate 317, so that the water absorbing sponge 316 can absorb water continuously, when the cable inner core passes through the wire passing pipe 405, insulating rubber fluid in the rubber wrapping pipe 406 can be attached to the cable inner core, insulating layer colloid covered on the surface of the cable inner core is squeezed through the tapered groove which is gradually reduced, compactness and uniformity of the insulating rubber fluid are improved, when the cable inner core is arranged in the cooling pipe 501, cooling water in the shell 103 can cool and shape the insulating rubber fluid preliminarily, flowing deviation of the insulating layer is prevented when the insulating layer is in an uncooled and solidified state, and finally the insulating layer colloid enters the water tank 502 to cool and shape finally.

Although embodiments of the invention have been shown and described, the detailed description is to be construed as exemplary only and is not limiting of the invention as the particular features, structures, materials, or characteristics may be combined in any suitable manner in any one or more embodiments or examples, and modifications, substitutions, variations, etc. may be made in the embodiments as desired by those skilled in the art without departing from the principles and spirit of the invention, provided that such modifications are within the scope of the appended claims.

Claims (9)

1. A triaxial shielded cable manufacturing apparatus including a cleaning chamber (100), characterized in that: the side wall of the cleaning cabin (100) is provided with a first wire inlet (101), one end side wall of the cleaning cabin (100) far away from the first wire inlet (101) is provided with two groups of mounting plates (102), the end parts of the two groups of mounting plates (102) are provided with shells (103), and the inner wall of the cleaning cabin (100) is provided with a cleaning mechanism (200);

the utility model provides a wiper mechanism (200) includes shunt tubes (202), the outer wall of wasing cabin (100) is equipped with shunt tubes (202) of two sets of No. one, two sets of the outer wall intercommunication of shunt tubes (202) has inlet tube (201) of No. one, two sets of the both ends of shunt tubes (202) all extend to the inside of wasing cabin (100), two sets of shunt tubes (202) extend to the inside one end rotation of wasing cabin (100) and are connected with shower nozzle (203), the inside of wasing cabin (100) is located the below of multiunit shower nozzle (203) and is equipped with filter layer (208), the inner wall bottom of wasing cabin (100) is equipped with water pump (209), the bottom intercommunication of water pump (209) has shunt tubes (210) of No. two, and the one end of shunt tubes (210) extends to the below of wasing cabin (100), the both ends of shunt tubes (210) are linked together with shunt tubes (202) of No. two sets of respectively, the inner diameter of wasing cabin (100) is equipped with cable brush (207), and cable brush (207) inner diameter is less than inlet wire (101).

2. A triaxial shielded cable manufacturing apparatus according to claim 1, characterized in that: two groups of first shunt tubes (202) extend to one end inside the cleaning cabin (100) and are provided with annular grooves (204), the ends of the spray heads (203) are provided with annular sliding rails (205), the outer walls of the annular sliding rails (205) are in sliding connection with the inner walls of the annular grooves (204), and the inner walls of the spray heads (203) are provided with turbofans (206).

3. A triaxial shielded cable manufacturing apparatus according to claim 1, characterized in that: the inner wall of the cleaning cabin (100) is provided with a water removing mechanism (300), the water removing mechanism (300) comprises a rack (301), a group of outer walls of the mounting plates (102) are provided with a rack (301), the outer walls of the rack (301) are provided with motors (302), the output ends of the motors (302) penetrate through the outer walls of the rack (301) and extend to the other side of the rack (301), the inner walls of the two groups of mounting plates (102) are rotatably connected with two groups of rotating shafts (303), the end part of one group of rotating shafts (303) is fixedly connected with the output end of the motor (302), the outer walls of the two groups of rotating shafts (303) are fixedly sleeved with two groups of driving gears (306) and two groups of driven gears (307) respectively, the two groups of driven gears (307) are meshed with the two groups of driving gears (306) respectively, the outer walls of the two groups of driven gears (307) are provided with a first transmission disc (308), the outer walls of the cleaning cabin (100) are rotatably connected with two groups of second transmission discs (309), the outer walls of the two groups of second transmission discs (309) are provided with transmission belts (310), the other ends of the transmission belts (310) are fixedly connected with the outer walls of the first transmission discs (308) and extend to one end of the second transmission discs (309) of the inner part of the cabin (100), and one end of the two groups of second transmission discs (309) extending to the inside of the cleaning cabin (100) is provided with a first bevel gear (311).

4. A triaxial shielded cable manufacturing apparatus according to claim 3, characterized in that: the inner wall both sides of wasing cabin (100) all are equipped with two sets of supports (312), two sets of the inner wall rotation of support (312) is connected with reciprocating screw (313), and the one end of reciprocating screw (313) extends to the outside of one of them set of support (312), the one end that reciprocating screw (313) extends to the outside of one of them set of support (312) is equipped with two bevel gears (314), and two bevel gears (314) and one bevel gear (311) meshing, two sets of the outer wall threaded connection of reciprocating screw (313) has slide bar (315), two sets of the outer wall of slide bar (315) is equipped with absorbs water sponge (316), two sets of the outer wall of support (312) is equipped with squeeze board (317), the inner wall of wasing cabin (100) is equipped with two sets of air guns (318).

5. A triaxial shielded cable manufacturing apparatus according to claim 3, characterized in that: the outer walls of the two groups of rotating shafts (303) are respectively fixedly sleeved with a driving disc (304) and a driven disc (305).

6. A triaxial shielded cable manufacturing apparatus according to claim 1, characterized in that: the top of casing (103) is equipped with insulating parcel mechanism (400), insulating parcel mechanism (400) include glue melting machine (401), the outer wall of glue melting machine (401) is equipped with discharging pipe (402), the one end intercommunication of discharging pipe (402) has No. three shunt tubes (403), and the both ends of No. three shunt tubes (403) extend to the inside of casing (103) respectively, the outer wall of casing (103) is equipped with No. two inlet tube (404), the inner wall of casing (103) is equipped with wire tube (405), and wire tube (405) and No. two inlet tube (404) intercommunication, the fixed cover of outer wall of wire tube (405) is equipped with wraps up in glue tube (406), and wire tube (405) and wraps up glue tube (406) intercommunication, the tip of No. three shunt tubes (403) all communicates with glue tube (406), the tip intercommunication of wire tube (405) has conical tube (407).

7. A triaxial shielded cable manufacturing apparatus according to claim 6, characterized in that: the end of conical tube (407) is equipped with cooling design mechanism (500), cooling design mechanism (500) are including cooling tube (501), the tip intercommunication of conical tube (407) has cooling tube (501), and the one end of cooling tube (501) extends to the outside of casing (103), the outer wall of casing (103) is equipped with basin (502), and basin (502) are located the below of cooling tube (501).

8. A triaxial shielded cable manufacturing apparatus according to claim 7, characterized in that: the outer wall of the water tank (502) is provided with a water row (508), and the outer wall of the water row (508) is provided with a cooling fan (509).

9. A triaxial shielded cable manufacturing apparatus according to claim 8, characterized in that: the inner wall of casing (103) is equipped with baffle (503), the bottom intercommunication of basin (502) has No. two inlet tube (504), the tip intercommunication of No. two inlet tube (504) has No. two water pumps (505), and No. two water pumps (505) and casing (103) intercommunication, the lateral wall intercommunication of casing (103) has outlet pipe (506), the lateral wall of water row (508) is equipped with No. three water pumps (507), and outlet pipe (506) and No. three water pumps (507) intercommunication, the lateral wall intercommunication of water row (508) has drain pipe (510).