CN116728742A - CPVC cable pipe inner and outer wall except that water cooling device - Google Patents

Abstract

The invention provides a CPVC cable pipe inner and outer wall water cooling device, which relates to the field of cable pipe cooling and comprises a support frame, wherein an air pump is fixedly connected to the front side of the top of the support frame, a telescopic pipe is fixedly connected to the rear end of the air pump, an electromagnetic valve is connected to the front end flange of the telescopic pipe, a jacking pipe is fixedly connected to the top of the air pump, a reciprocating screw rod is fixedly connected to the top of the support frame, high-pressure air enters a conical pipe and is guided by a conical sleeve, the high-pressure air can blow the inner wall of the cable pipe, the inner wall of the cable pipe can flow backwards through translation of a turnover pipe, the inner wall of the cable pipe can be stably dehydrated, the high-pressure air can enter an inclined pipe through opening a jacking pipe valve, the inclined pipe can blow the curved side of the cable pipe, the cable pipe can rotate inside a top cover and a bottom cover, and liquid drops at the outer wall of the cable pipe can be blown outwards, and the problem that the traditional cooling device is inconvenient to stably and rapidly dehydrate the inner wall of the cable pipe is solved.

Description

CPVC cable pipe inner and outer wall except that water cooling device

Technical Field

The invention relates to the technical field of cable tube cooling, in particular to a CPVC cable tube inner and outer wall water cooling device.

Background

When the CPVC cable tube extruder is used for cable tube processing, a specific device is required to cool and cool the produced high-temperature cable tube, as disclosed in the patent CN113669998A, the quick cooling device comprises a water tank, brackets are fixedly arranged on the left side and the right side of the top of the water tank, a cylinder is fixedly arranged between the two brackets, the quick cooling device for the power tube production is characterized in that a pipeline frame and a water pipe are arranged, when the whole cooling device works, water in the water pump extraction water tank is conveyed into a water tank and sprayed out by a spray head, a pipeline can be placed between two rubber rollers at the moment, a servo motor is started to drive a rotating shaft to rotate, the power tube is clamped by the two rubber rollers to move leftwards, the pipeline frame can hold the power tube to prevent the power tube from bending, the power tube can be cooled through the spray head in the moving process of the power tube, the quick cooling device is compact and reasonable in integral structure, the operation is simple, the use is convenient, water resources are saved, the bending of the power tube is prevented, and the effect of strong practicability is achieved.

However, when the cooling device uses the spray head to spray water to cool down the cable pipe, when the low-temperature water flow contacts the high-temperature cable pipe, the surface of the high-temperature cable pipe which is firstly subjected to regional cooling is easy to generate cracks in the process of chain segment rigidification, the whole inner side and the whole outer side of the cable pipe are not convenient to be rapidly cooled down and cooled and shaped by the existing cooling device, the inner wall and the outer wall of the cable pipe are not convenient to be stably and rapidly dehydrated, and the quick automatic feeding and discharging of the cable pipe are not convenient to be performed by the existing cooling device.

Disclosure of Invention

In view of the above, the invention provides a CPVC cable pipe inner and outer wall water cooling device, which enables high-pressure air to enter a conical pipe, enables the high-pressure air to blow the inner wall of the cable pipe through the diversion of the conical sleeve, enables the water on the inner wall of the cable pipe to flow backwards through the translation of a turnover pipe, enables the inner wall of the cable pipe to remove water stably, enables the high-pressure air to enter an inclined pipe through opening a pipe jacking valve, enables the inclined pipe to blow the curved side surface of the cable pipe, enables the cable pipe to rotate on the inner sides of a top cover and a bottom cover, and enables liquid drops on the outer wall of the cable pipe to blow outwards.

The invention provides a purpose and an effect of a water cooling device for the inner and outer walls of a CPVC cable pipe, which particularly comprises a supporting frame; the front side of the top of the support frame is fixedly connected with an air pump, the rear end of the air pump is fixedly connected with a telescopic pipe, the front end flange of the telescopic pipe is connected with an electromagnetic valve, the top of the air pump is fixedly connected with a jacking pipe, and a valve is arranged in the jacking pipe; the device comprises a support frame, a reciprocating screw, a sliding seat, a bearing seat, a stepping motor, a worm gear reducer, a sleeve frame, a reversing tube, a conical tube, an inner support and a conical sleeve, wherein the reciprocating screw is fixedly connected to the top of the support frame; the outer side of the overturning pipe is fixedly connected with a transmission frame, and the outer side of the transmission frame is rotationally connected with a cam.

Optionally, the support frame rear side fixedly connected with cooling liquid case, both sides fixedly connected with water conservancy diversion screw around the cooling liquid incasement portion.

Optionally, both sides fixedly connected with curb plate around the cooling liquid case top, curb plate quantity sets up to two sets of, curb plate top fixedly connected with feed frame.

Optionally, the feeding frame is bent side fixedly connected with chain case in, and the chain case left side rotates to be connected with concave wheel A, and through the chain looks transmission between the concave wheel A, the inside motor that is provided with of chain case, motor shaft and chain looks transmission.

Optionally, the inside bottom fixedly connected with of coolant tank cuts fork mechanism, and inside rear side fixedly connected with spacing of coolant tank.

Optionally, the cooling liquid tank top left and right sides fixedly connected with top support, top support top fixedly connected with spring rod, spring rod bottom fixedly connected with top cap.

Optionally, the inboard top fixedly connected with hang down pipe of top cap, hang down pipe top and push pipe fixed connection, spring bar bottom fixedly connected with end cover, end cover intraductal curved side rotates and is connected with concave wheel B, and concave wheel B passes through the belt and drives mutually, end cover bottom fixedly connected with drain chute, the inboard sliding connection of drain chute has the screen cloth.

Optionally, the curved side of bottom cover runs through and has the groove that runs through, runs through the inboard rotation of groove and is connected with electric telescopic handle, and the curved side of bottom cover is rotated and is connected with the deflection frame, and electric telescopic handle expansion portion top is rotated with deflection frame bottom and is connected, and deflection frame side rotates and is connected with the riding wheel.

Advantageous effects

According to the cooling device disclosed by the embodiment of the invention, the bottom cover can be driven to move downwards by controlling the operation of the shearing fork mechanism, the spring rod can move downwards and elastically, the spring rod can move downwards against the top cover, the top cover can be attached to the bottom cover, the cable pipe can be prevented from floating upwards, the cable pipe can be driven to integrally drop below the liquid level of the cooling liquid tank, the cooling liquid can cool the inner side and the outer side of the whole cable pipe, the cooling liquid can longitudinally flow in the cooling liquid tank by controlling the synchronous operation of the guide propellers at the front side and the rear side of the inside of the cooling liquid tank, the rear end vertical surface of the cable pipe can be limited by the limiting strips, the cable pipe can be prevented from moving backwards inside the top cover and the bottom cover, the cooling liquid can be prevented from flowing fast in the front-rear direction of the cable pipe, the cooling liquid around the cable pipe can be accelerated, and the inner side and the outer side of the cable pipe can be rapidly cooled and shaped evenly.

In addition, after the cable tube is cooled, the bottom cover can lift the cable tube upwards by controlling the operation of the shearing fork mechanism, the cable tube can be translated upwards again to be aligned with the feeding frame, the telescopic part of the cable tube can drive the deflection frame to deflect upwards by controlling the operation of the electric telescopic rod, the longitudinal supporting wheels at the left side and the right side can lift the cable tube, the sliding seat can be driven to translate forwards and backwards by controlling the reciprocating screw rod, the sliding seat can drive the overturning tube to horizontally move into the cable tube backwards, the cam can be prevented from driving the cable tube to translate longitudinally at the inner sides of the top cover and the bottom cover, high-pressure air can enter the overturning tube through the telescopic tube by controlling the operation of the air pump, high-pressure air can enter the conical tube, the high-pressure air can blast the inner wall of the cable tube through the diversion of the conical sleeve, the inner wall of the cable tube can flow backwards through the translation of the overturning tube, and the inner wall of the cable tube can be stably dehydrated.

In addition, the pipe jacking valve is opened to enable high-pressure air to enter the inclined pipe, the inclined pipe can blast air on the curved side face of the cable pipe, the cable pipe can rotate on the inner sides of the top cover and the bottom cover, liquid drops at the outer wall of the cable pipe can be blown off outwards, the liquid drops can flow downwards into the drainage groove, and the liquid drops can flow back to the cooling liquid tank again downwards.

In addition, after the inner wall and the outer wall of the cable tube are dehydrated, the reciprocating screw rod drives the overturning tube to reset, the stepping motor is controlled to drive the worm gear reducer to operate, the worm gear reducer can drive the sleeve frame to overturn upwards, the overturning tube and the conical tube can be driven to deflect upwards, the concave wheel is controlled to operate to longitudinally move out the treated cable tube, the cable tube and the conical tube can be prevented from being in contact and limited, and the cable tube can be conveniently and rapidly fed and discharged.

In addition, after the feeding frame is in butt joint with the cable pipe extruder, the motor at the position of the chain box is controlled to run, so that the feeding frame can drive each group of concave wheels A to synchronously rotate, the concave wheels A can drive CPVC cable pipes to be transported to the inner sides of the top cover and the bottom cover, the concave wheels B are driven to rotate by the control motor, and the cable pipes can be longitudinally moved on the inner sides of the top cover and the bottom cover.

Drawings

In order to more clearly illustrate the technical solution of the embodiments of the present invention, the drawings of the embodiments will be briefly described below.

The drawings described below are only for illustration of some embodiments of the invention and are not intended to limit the invention.

In the drawings:

fig. 1 is a right-side structural schematic diagram of the entire cooling apparatus of the embodiment of the present invention.

Fig. 2 is an enlarged partial schematic view of the invention of fig. 1 a.

Fig. 3 is an enlarged partial schematic view of B of fig. 1 in accordance with the present invention.

Fig. 4 is a schematic top view of the entire cooling apparatus according to the embodiment of the present invention.

Fig. 5 is a schematic side sectional perspective view of a conical tube of a cooling device according to an embodiment of the present invention.

Fig. 6 is a schematic view of the structure of the cooling device bottom cover according to the embodiment of the present invention.

Fig. 7 is a schematic side sectional perspective view of a cooling liquid tank of a cooling device of an embodiment of the present invention.

Fig. 8 is a schematic side sectional structure of a cooling device bottom cover of an embodiment of the present invention.

List of reference numerals

1. A support frame;

2. an air pump;

201. a telescopic tube; 202. jacking pipes;

3. a reciprocating screw;

301. a slide; 302. a bearing seat; 303. a stepping motor; 304. a worm gear reducer; 305. a cannula housing; 306. a turnover pipe; 307. a conical tube; 308. an inner bracket; 309. a conical sleeve;

4. a transmission rack;

401. a cam;

5. a cooling liquid tank;

501. a deflector screw; 502. a side plate; 503. a scissors mechanism; 504. a limit bar; 505. a top bracket; 506. a spring rod; 507. a top cover; 508. an inclined tube;

6. a feeding frame;

601. a chain case; 602. a concave wheel A;

7. a bottom cover;

701. a concave wheel B; 702. a drainage groove; 703. a screen; 704. a through groove; 705. an electric telescopic rod; 706. a deflection frame; 707. and (3) a riding wheel.

Detailed Description

Embodiments of the present invention are described in further detail below with reference to the accompanying drawings and examples.

Examples: please refer to fig. 1 to 8:

the invention provides a CPVC cable pipe inner and outer wall water cooling device, which comprises a support frame 1; the front side of the top of the support frame 1 is fixedly connected with an air pump 2, the rear end of the air pump 2 is fixedly connected with a telescopic pipe 201, the front end flange of the telescopic pipe 201 is connected with an electromagnetic valve, the top of the air pump 2 is fixedly connected with a jacking pipe 202, and a valve is arranged in the jacking pipe 202; the top of the supporting frame 1 is fixedly connected with a reciprocating screw 3, the top of a ball nut seat of the reciprocating screw 3 is fixedly connected with a sliding seat 301, the top of the sliding seat 301 is fixedly connected with a bearing seat 302, the top of the sliding seat 301 is fixedly connected with a stepping motor 303, the left side of the stepping motor 303 is fixedly connected with a worm and gear reducer 304, the left end of an output shaft of the worm and gear reducer 304 is fixedly connected with a sleeve frame 305, the inner side of the bearing seat 302 is rotationally connected with a turnover pipe 306, the front end of the turnover pipe 306 is rotationally connected with a telescopic pipe 201, the sleeve frame 305 is sleeved on the outer side of the turnover pipe 306, the rear end of the turnover pipe 306 is fixedly connected with a conical pipe 307, the inner curved side surface of the conical pipe 307 is fixedly connected with an inner support 308, and the rear side of the inner support 308 is fixedly connected with a conical sleeve 309; the turnover pipe 306 outside fixedly connected with transmission frame 4, transmission frame 4 outside rotates and is connected with cam 401, the fixedly connected with cooling liquid tank 5 of support frame 1 rear side, both sides fixedly connected with water conservancy diversion screw 501 around the inside of cooling liquid tank 5, both sides fixedly connected with curb plate 502 around cooling liquid tank 5 top, curb plate 502 quantity sets up to two sets of, curb plate 502 top fixedly connected with feed frame 6, feed frame 6 indent side fixedly connected with chain case 601, chain case 601 left side rotates and is connected with concave wheel A602, pass through the chain phase transmission between concave wheel A602, be provided with the motor inside chain case 601, the motor pivot is transmitted with the chain phase, dock the feed frame 6 with the cable pipe extruder back, through the motor operation of control chain case 601 department, can make it drive each group concave wheel A602 and rotate in step, can make concave wheel A602 drive CPVC cable pipe transportation to top cover 507 and bottom cover 7 inboard, drive concave wheel B through the control motor and rotate, can carry out longitudinal movement at top cover 507 and bottom cover 7 inboard.

As shown in fig. 1 to 7, the bottom of the inner side of the cooling liquid tank 5 is fixedly connected with a shearing fork mechanism 503, the rear side of the inner side of the cooling liquid tank 5 is fixedly connected with a limiting strip 504, the left side and the right side of the top of the cooling liquid tank 5 are fixedly connected with a top support 505, the top of the top support 505 is fixedly connected with a spring rod 506, the bottom of the spring rod 506 is fixedly connected with a top cover 507, the spring rod 506 is controlled to operate so as to drive a bottom cover 7 to translate downwards, the spring rod 506 can translate downwards the top cover 507 through the spring rod 506, the top cover 507 can be attached to the bottom cover 7, the cable pipe can be prevented from floating upwards, the cable pipe can be driven to wholly fall below the liquid level of the cooling liquid tank 5, the cooling liquid can be cooled to the inner side and the outer side of the cable pipe, the cooling liquid can flow longitudinally inside the cooling liquid tank 5 through controlling a guide screw 501 at the front side and the rear side of the cooling liquid tank 5, the rear end of the cable pipe can be limited through the limiting strip 504, the cable pipe can be prevented from being moved downwards at the inner side cover 507 and the bottom cover 7, the cable pipe can be cooled down in a uniform direction, and the cooling liquid can be cooled down evenly.

As shown in fig. 2 to 8, the inner top of the top cover 507 is fixedly connected with an inclined tube 508, the top of the inclined tube 508 is fixedly connected with the top tube 202, the bottom of the spring rod 506 is fixedly connected with a bottom cover 7, the inner curved side of the bottom cover 7 is rotationally connected with a concave wheel B701, the concave wheel B701 is driven by a belt, the bottom of the bottom cover 7 is fixedly connected with a drainage groove 702, the inner side of the drainage groove 702 is slidingly connected with a screen 703, the curved side of the bottom cover 7 is penetrated with a penetrating groove 704, the inner side of the penetrating groove 704 is rotationally connected with an electric telescopic rod 705, the inner curved side of the bottom cover 7 is rotationally connected with a deflection frame 706, the top of the telescopic part of the electric telescopic rod 705 is rotationally connected with the bottom of the deflection frame 706, the side end of the deflection frame 706 is rotationally connected with a supporting wheel 707, after the cable tube is cooled, the cable tube is lifted upwards by controlling the operation of the shearing and forking mechanism 503, the cable tube can be translated upwards to be aligned with the feeding frame 6 again by controlling the operation of the electric telescopic rod 705, the telescopic part of the telescopic part can drive the deflection frame 706 to deflect upwards, the longitudinal riding wheels 707 at the left side and the right side can be used for supporting a cable tube, the reciprocating screw rod 3 is controlled, the sliding seat 301 can be driven to translate forwards and backwards, the sliding seat 301 can be driven to translate the overturning tube 306 backwards and horizontally into the cable tube, the cam 401 can be prevented from driving the cable tube to translate longitudinally at the inner sides of the top cover 507 and the bottom cover 7, the high-pressure air can enter the overturning tube 306 through the telescopic pipe 201, the high-pressure air can enter the conical tube 307, the high-pressure air can be guided through the conical sleeve 309, the high-pressure air can blow the inner wall of the cable tube, the water on the inner wall of the cable tube can flow backwards through the translation of the overturning tube 306, the high-pressure air can enter the inclined tube 508 through opening the valve of the top pipe 202, the inclined tube 508 can blow the curved side of the cable tube, the cable tube can rotate on the inner sides of the top cover 507 and the bottom cover 7, liquid drops at the outer wall of the cable tube can be blown off outwards, the liquid drops can flow into the drainage groove 702 downwards, the liquid drops can flow back to the cooling liquid tank 5 again downwards, after the inner and outer walls of the cable tube are dehydrated, the reciprocating screw 3 drives the overturning tube 306 to reset, the stepping motor 303 is controlled to drive the worm and gear reducer 304 to operate, the stepping motor can drive the sleeve frame 305 to overturn upwards, the overturning tube 306 and the conical tube 307 can be driven to deflect upwards, and when the concave wheel operation is controlled to longitudinally move out the treated cable tube, the contact limit between the cable tube and the conical tube 307 can be prevented, so that the cable tube can be conveniently and rapidly and automatically fed.

Specific use and action of the embodiment: in the invention, after the feeding frame 6 is in butt joint with the cable pipe extruder, the motor at the position of the chain box 601 is controlled to operate, so that each group of concave wheels A602 can be driven to synchronously rotate, the concave wheels A602 can drive CPVC cable pipes to be transported to the inner sides of the top cover 507 and the bottom cover 7, the concave wheels B701 are driven to rotate by the control motor, the cable pipes can be longitudinally moved at the inner sides of the top cover 507 and the bottom cover 7, the shearing fork mechanism 503 is controlled to operate, the bottom cover 7 is driven to downwards translate, the spring rod 506 is driven to downwards and elastically translate, the spring rod 506 can downwards translate the top cover 507, the top cover 507 is attached to the bottom cover 7, the cable pipes can be prevented from floating upwards, the cable pipes can be driven to wholly fall below the liquid level of the cooling liquid box 5, the cooling liquid can be cooled to the inner side and the outer side of the whole cable pipes, the diversion propellers 501 at the front side and the back side of the inner side of the cooling liquid box 5 are controlled to synchronously operate, the cooling liquid can longitudinally flow in the cooling liquid tank 5, the vertical surface at the rear end of the cable pipe can be limited by the limiting strips 504, the cable pipe can be prevented from moving out backwards at the inner sides of the top cover 507 and the bottom cover 7, the cooling liquid can rapidly flow in the front-back direction of the cable pipe, the convection of the cooling liquid around the cable pipe can be accelerated, the inner side and the outer side of the cable pipe can be rapidly and uniformly cooled and shaped, after the cable pipe is cooled, the bottom cover 7 can lift the cable pipe upwards by controlling the operation of the shearing fork mechanism 503, the cable pipe can be translated upwards again to be aligned with the feeding frame 6, the telescopic part of the cable pipe can be driven to upwards deflect by controlling the operation of the electric telescopic rod 705, the cable pipe can be supported by the longitudinal supporting wheels 707 at the left side and the right side, the sliding seat 301 can be driven to translate forwards and backwards by controlling the reciprocating screw rod 3, can lead the sliding seat 301 to drive the overturning pipe 306 to move backwards and horizontally into the cable pipe, can prevent the cam 401 from driving the cable pipe to translate longitudinally on the inner sides of the top cover 507 and the bottom cover 7, can lead high-pressure air to enter the overturning pipe 306 through the telescopic pipe 201 by controlling the operation of the air pump 2, can lead high-pressure air to enter the conical pipe 307, can lead high-pressure air to blow the inner wall of the cable pipe by guiding through the conical sleeve 309, can lead the water flow on the inner wall of the cable pipe to flow backwards by translating the overturning pipe 306, can lead the high-pressure air to enter the inclined pipe 508 by opening the valve of the top pipe 202, can lead the inclined pipe 508 to blow the curved side surface of the cable pipe, the cable tube can rotate on the inner sides of the top cover 507 and the bottom cover 7, liquid drops at the outer wall of the cable tube can be blown off outwards, the liquid drops can flow into the drainage groove 702 downwards, the liquid drops can flow back to the cooling liquid tank 5 again downwards, after the inner and outer walls of the cable tube are dehydrated, the reciprocating screw 3 drives the overturning tube 306 to reset, the stepping motor 303 is controlled to drive the worm and gear reducer 304 to operate, the stepping motor can drive the sleeve frame 305 to overturn upwards, the overturning tube 306 and the conical tube 307 can be driven to deflect upwards, and when the concave wheel operation is controlled to longitudinally move out the treated cable tube, the contact limit between the cable tube and the conical tube 307 can be prevented, so that the cable tube can be conveniently and rapidly and automatically fed.

Claims (8)

1. The utility model provides a CPVC cable tube inner and outer wall dewatering cooling device which characterized in that includes: a support (1); the front side of the top of the supporting frame (1) is fixedly connected with an air pump (2), the rear end of the air pump (2) is fixedly connected with a telescopic pipe (201), the front end flange of the telescopic pipe (201) is connected with an electromagnetic valve, the top of the air pump (2) is fixedly connected with a jacking pipe (202), and a valve is arranged in the jacking pipe (202); the device is characterized in that a reciprocating screw (3) is fixedly connected to the top of the supporting frame (1), a sliding seat (301) is fixedly connected to the top of a ball nut seat of the reciprocating screw (3), a bearing seat (302) is fixedly connected to the top of the sliding seat (301), a stepping motor (303) is fixedly connected to the top of the sliding seat (301), a worm gear reducer (304) is fixedly connected to the left side of the stepping motor (303), a sleeve frame (305) is fixedly connected to the left end of an output shaft of the worm gear reducer (304), a turnover pipe (306) is rotatably connected to the inner side of the bearing seat (302), the front end of the turnover pipe (306) is rotatably connected with the telescopic pipe (201), the sleeve frame (305) is sleeved on the outer side of the turnover pipe (306), a conical pipe (307) is fixedly connected to the rear end of the turnover pipe (306), an inner curved side surface of the conical pipe (307) is fixedly connected with an inner support (308), and the rear side of the inner support (308) is fixedly connected with a conical sleeve (309); the outer side of the overturning pipe (306) is fixedly connected with a transmission frame (4), and the outer side of the transmission frame (4) is rotationally connected with a cam (401).

2. A CPVC cable pipe inner and outer wall water removal cooling apparatus as claimed in claim 1 wherein: the cooling liquid box (5) is fixedly connected to the rear side of the support frame (1), and diversion propellers (501) are fixedly connected to the front side and the rear side of the inside of the cooling liquid box (5).

3. A CPVC cable pipe inner and outer wall water removal cooling apparatus as claimed in claim 2 wherein: the cooling liquid tank (5) is characterized in that side plates (502) are fixedly connected to the front side and the rear side of the top of the cooling liquid tank, the number of the side plates (502) is two, and a feeding frame (6) is fixedly connected to the top of the side plates (502).

4. A CPVC cable pipe inner and outer wall water removal cooling apparatus as claimed in claim 3 wherein: the feeding frame is characterized in that a chain box (601) is fixedly connected to the inner curved side face of the feeding frame (6), concave wheels A (602) are rotatably connected to the left side of the chain box (601), the concave wheels A (602) are in transmission through chains, a motor is arranged in the chain box (601), and a motor rotating shaft is in transmission with the chains.

5. A CPVC cable pipe inner and outer wall water removal cooling apparatus as claimed in claim 2 wherein: the bottom of the inner side of the cooling liquid tank (5) is fixedly connected with a shearing fork mechanism (503), and the rear side of the inner side of the cooling liquid tank (5) is fixedly connected with a limiting strip (504).

6. A CPVC cable pipe inner and outer wall water removal cooling apparatus as claimed in claim 2 wherein: the cooling liquid tank (5) top left and right sides fixedly connected with top support (505), top support (505) top fixedly connected with spring rod (506), spring rod (506) bottom fixedly connected with top cap (507).

7. The CPVC cable pipe inner and outer wall water removal and cooling apparatus of claim 6 wherein: the utility model discloses a top cover, including top cover (507), top cover (7), bottom cover (7), concave wheel B (701) drive mutually through the belt, bottom cover (7) bottom fixedly connected with drain chute (702), drain chute (702) inboard sliding connection has screen cloth (703).

8. The CPVC cable pipe inner and outer wall water removal and cooling apparatus of claim 7 wherein: the curved side surface of the bottom cover (7) is penetrated with a penetrating groove (704), the inner side of the penetrating groove (704) is rotationally connected with an electric telescopic rod (705), the curved side surface of the bottom cover (7) is rotationally connected with a deflection frame (706), the top of a telescopic part of the electric telescopic rod (705) is rotationally connected with the bottom of the deflection frame (706), and the side end of the deflection frame (706) is rotationally connected with a riding wheel (707).