CN114974708A - Heating color-displaying type high-heat-conductivity composite cable - Google Patents

Abstract

The invention discloses a heating and color developing type high-heat-conductivity composite cable which comprises a rubber layer, cables, heat absorption pipes, a first heat dissipation ring and a second heat dissipation ring, wherein the heat absorption pipes are arranged inside the rubber layer, flow guide pipes are fixedly arranged on the side surfaces of the heat absorption pipes, the flow guide pipes penetrate through the side surfaces of the heat absorption pipes, 2 adjacent heat absorption pipes are not communicated, the cables are placed between the 2 flow guide pipes and the rubber layer, a water collection tank is fixedly arranged on the outer surface of the upper end of a cooling sleeve ring, an upper cover is placed inside the water collection tank, and a second pressure relief hole is formed in the outer surface of one end, far away from the rubber layer, of a suction cylinder. This generate heat high heat conduction composite cable of color rendering type, through penetrating the heat-absorbing pipe in the middle of the cable, utilize heat-conducting oil to absorb and directly conduct to first radiating ring and second radiating ring in the heat-absorbing pipe the heat of rubber inslot to the realization is derived thermal high efficiency, avoids the heat to pile up the ageing of cable with higher speed in the rubber layer.

Description

Heating color-displaying type high-heat-conductivity composite cable

Technical Field

The invention relates to the technical field of cables, in particular to a heating and color-displaying type high-heat-conductivity composite cable.

Background

Along with the increase of domestic power demand, the cable that is used for transmission power of the visible major diameter everywhere in city, the cable between the transformer substation is connected in order to guarantee that power transmission's stability more adopts the cable of bold model, and there is certain loss in electric power in transportation process, and these losses mostly change for the heat distributes away, but current cable has some defects in the course of the work, just such as:

firstly, the existing cable often dissipates heat generated by current flowing through the cable by means of passive heat dissipation, but the heat inside the cable cannot be efficiently led out due to the obstruction of the rubber on the outer layer of the cable, so that the cable is easily damaged due to overheating caused by the fact that the heat inside the cable cannot be dissipated in time;

secondly, when current cable need measure the cable temperature at the operation in-process, often need ascend a height through the maintainer and carry out the measurement of temperature, danger not only very, the temperature of same cable different sections can be because the deviation in the manufacturing process is completely different simultaneously, the mode of artifical measuring can't measure the cable temperature in the middle of the both ends mounted position, this just has certain potential safety hazard, overheated cable is not for a long time found will cause the accelerated ageing of cable.

In order to solve the problems, innovative design based on the original cable is urgently needed.

Disclosure of Invention

The invention aims to provide a heating and color-displaying type high-thermal-conductivity composite cable to solve the problems of poor thermal conduction effect and difficulty in temperature monitoring of the cable in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a heating and color-displaying high-heat-conductivity composite cable comprises a rubber layer, cables, a heat absorption pipe, a first heat dissipation ring and a second heat dissipation ring, wherein the heat absorption pipe is arranged inside the rubber layer, a guide pipe is fixedly arranged on the side surface of the heat absorption pipe and penetrates through the side surface of the heat absorption pipe, 2 adjacent heat absorption pipes are not communicated, the cables are placed between the guide pipe and the rubber layer, the outer surface of the rubber layer is fixedly provided with the first heat dissipation ring and the second heat dissipation ring, the outer surfaces of the first heat dissipation ring and the second heat dissipation ring are both provided with a heat dissipation plate and a suction cylinder, the inner part of the suction cylinder on the outer surface of the first heat dissipation ring is connected with a sliding adsorption plate, the inner part of the suction cylinder on the outer surface of the second heat dissipation ring is connected with a sliding piston plate, and the outer surface of one side, opposite to the second heat dissipation ring, of the first heat dissipation ring is provided with a rotating swivel ring in an embedded manner, the utility model discloses a cooling device, including a first heat dissipation ring, a change ring, an air chamber, an observation port, an evaporation port, a water catch bowl, a suction cylinder, a water catch bowl, a cover plate, a suction cylinder, a cover plate, a fan blade, a second heat dissipation ring, an observation port, an evaporation port, a water catch bowl, an upper cover has been placed to the inside of water catch bowl, the one end surface fixed mounting that the change ring is located the inside of first heat dissipation ring has the shielding plate, the change ring is located the outside one side surface fixed mounting of first heat dissipation ring has the flabellum, one side surface fixed mounting of second heat dissipation ring dorsad first heat dissipation ring is provided with the air chamber, first pressure release hole has been seted up to the one end of air chamber, the internal connection of air chamber has gliding slide bar, and the surface of slide bar is embedded to install the color lump, one side surface fixed mounting in opposite direction of first heat dissipation ring and second heat dissipation ring has the cooling lantern ring, the evaporation port has been seted up to the upper end surface of cooling lantern ring, the upper cover is kept away from the rubber layer to the suction cylinder.

Preferably, the honeycomb ducts are distributed in the rubber layer in a cross shape, 4 honeycomb ducts form a group, and two ends of 2 groups of honeycomb ducts respectively penetrate through the outer surfaces of the first radiating ring and the second radiating ring.

Adopt above-mentioned technical scheme, utilize 2 groups of honeycomb ducts to separate between the cable when carrying out the water conservancy diversion to the conduction oil for there is enough space to carry out thermal giving off between the cable.

Preferably, the heat dissipation plate is uniformly distributed on the outer surfaces of the first heat dissipation ring and the second heat dissipation ring, the heat dissipation plate is in a hollow design, and one end of the heat dissipation plate penetrates through the outer surfaces of the first heat dissipation ring and the second heat dissipation ring.

By adopting the technical scheme, the contact area of the first radiating ring and the second radiating ring with the outside air can be increased by the radiating plate, so that the better radiating effect of the first radiating ring and the second radiating ring is realized.

Preferably, the suction tube is in sliding friction connection with the adsorption plate and the piston plate respectively, and a spring is connected between the suction tube and the adsorption plate.

By adopting the technical scheme, the adsorption plate and the piston plate can not lead the heat conduction oil to leak through the suction cylinder in the sliding process.

Preferably, the swivel is connected with the first heat dissipation ring in a sliding friction mode, the shielding plates are uniformly distributed on the inner side surface of the swivel, and the fan blades are uniformly distributed on the outer side surface of the swivel.

By adopting the technical scheme, the fan blades can drive the rotating ring and the shielding plate to rotate under the driving of the air flow.

Preferably, the air chamber is connected with the slide bar in a sliding friction mode, the air chamber and the slide bar are both in arc-shaped design, and the outer surface of the color block is flush with the outer surface of the slide bar.

By adopting the technical scheme, the color block can not block the sliding of the sliding rod or cause the pressure relief between the sliding rod and the air chamber when the sliding rod is pushed to slide by air pressure.

Preferably, the cooling lantern ring is in a semicircular hollow design, the upper cover is in an arc plate-shaped design, and the upper cover is positioned right above the evaporation port.

By adopting the technical scheme, the cooling lantern ring can absorb heat and cool the rubber layer through the water in the cooling lantern ring.

Preferably, the water collecting tank is arranged around the evaporation port, and the inner side surface of the water collecting tank is attached to the outer side surface of the upper cover.

By adopting the technical scheme, the upper cover can be attached to the water collecting tank when the rain does not fall, and the evaporation speed of the rainwater is reduced.

Preferably, the outer surface of the cooling lantern ring on two sides of the water collecting tank is fixedly provided with a limiting frame, the sponge is placed inside the limiting frame, and the upper surface of the limiting frame is provided with a water permeable hole.

Adopt above-mentioned technical scheme for the rainwater can see through the hole of permeating water and soak the sponge and make the sponge inflation when raining.

Preferably, the upper surface of the sponge is fixedly connected with one end of a connecting rod, and the other end of the connecting rod penetrates through the upper surface of the limiting frame and is fixedly connected with the upper cover.

By adopting the technical scheme, the sponge expansion chamber can drive the upper cover to slide upwards through the connecting rod.

Compared with the prior art, the invention has the beneficial effects that: this generate heat and show look type high heat conduction composite cable:

1. the heat absorption pipe penetrates through the middle of the cable, and heat in the rubber layer is absorbed by heat conduction oil in the heat absorption pipe and directly conducted to the first heat dissipation ring and the second heat dissipation ring, so that the heat is efficiently led out, and the accelerated cable is prevented from being aged due to heat accumulated in the rubber layer;

2. the fan blades are blown by wind to drive the rotating ring and the shielding plate to rotate, so that the shielding plate can cut off the adsorption of a magnetic field generated by the current flowing in the cable to the adsorption plate more discontinuously, the adsorption plate can slide in a reciprocating manner, heat conduction oil between the heat absorption pipe and the first heat dissipation ring and the second heat dissipation ring can be forced to flow and mix, and the heat transfer speed between the heat conduction oil is increased;

3. receive the gliding mode of thermal expansion volume increase promotion slide bar through air in the air chamber for the slide bar can drive the color lump of different colours and rotate to viewing aperture department, the inside temperature of current cable can be judged through the color lump colour that exposes viewing aperture department at ground observation equipment to the maintainer, the problem of the unable monitoring in complicated flow and the cable middle section of having avoided ascending a height and detecting, the mode of air chamber and the laminating of second cooling ring makes the temperature that shows be this section cable inside average temperature and not point-to-point temperature simultaneously, can accelerate the speed that detects the cable temperature.

Drawings

FIG. 1 is a schematic overall cross-sectional elevational view of the present invention;

FIG. 2 is a cross-sectional side view of the rubber layer and the first heat dissipating ring according to the present invention;

FIG. 3 is a side sectional view of the rubber layer and the second heat dissipating ring according to the present invention;

FIG. 4 is a side cross-sectional view of a second heat sink ring and cooling collar of the present invention;

FIG. 5 is a side sectional view of a second heat dissipating ring in connection with a plenum in accordance with the present invention;

FIG. 6 is an enlarged view of the structure at A in FIG. 4 according to the present invention.

In the figure: 1. a rubber layer; 2. a cable; 3. a heat absorbing tube; 4. a flow guide pipe; 5. a first heat dissipation ring; 6. a second heat dissipation ring; 7. a heat dissipation plate; 8. a suction cylinder; 9. an adsorption plate; 10. a piston plate; 11. rotating the ring; 12. a shielding plate; 13. a fan blade; 14. an air chamber; 15. a viewing port; 16. a first pressure relief vent; 17. a slide bar; 18. color blocks; 19. cooling the collar; 20. an evaporation port; 21. a water collection tank; 22. an upper cover; 23. a limiting frame; 24. a sponge; 25. a connecting rod; 26. water permeable holes; 27. a second pressure relief vent.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-6, the present invention provides a technical solution: a heating and color-displaying high-heat-conductivity composite cable comprises a rubber layer 1, cables 2, heat absorption tubes 3, a flow guide tube 4, a first heat dissipation ring 5, a second heat dissipation ring 6, a heat dissipation plate 7, a suction cylinder 8, an adsorption plate 9, a piston plate 10, a rotary ring 11, a shielding plate 12, fan blades 13, an air chamber 14, an observation port 15, a first pressure relief hole 16, a slide rod 17, a color block 18, a cooling lantern ring 19, an evaporation port 20, a water collecting tank 21, an upper cover 22, a limiting frame 23, sponge 24, a connecting rod 25, a water permeable hole 26 and a second pressure relief hole 27, wherein the heat absorption tubes 3 are arranged inside the rubber layer 1, the flow guide tube 4 is fixedly arranged on the side surface of the heat absorption tubes 3, the flow guide tube 4 penetrates through the side surface of the heat absorption tubes 3, the adjacent 2 heat absorption tubes 3 are not communicated, the cables 2 are placed between the flow guide tubes 4 and the rubber layer 1, the first heat dissipation ring 5 and the second heat dissipation ring 6 are fixedly arranged on the outer surface of the rubber layer 1, the outer surfaces of the first radiating ring 5 and the second radiating ring 6 are both provided with a radiating plate 7 and a suction cylinder 8, the guide pipes 4 are distributed in the rubber layer 1 in a cross shape, and 4 guide pipes 4 form a group, and the two ends of the 2 groups of draft tubes 4 respectively penetrate through the outer surfaces of the first radiating ring 5 and the second radiating ring 6, the radiating plates 7 are uniformly distributed on the outer surfaces of the first radiating ring 5 and the second radiating ring 6, and the radiating plates 7 are in a hollow design, one end of the heat dissipation plate 7 penetrates through the outer surfaces of the first heat dissipation ring 5 and the second heat dissipation ring 6, heat dissipated by the cable 2 is absorbed by heat conduction oil in the heat absorption pipe 3, so that the honeycomb duct 4 can realize the rapid heat conduction through the exchange of heat conducting oil among the heat-absorbing pipe 3, the first heat-radiating ring 5 and the second heat-radiating ring 6, ensure that the aging of the cable 2 cannot be caused due to the overhigh temperature in the rubber layer 1, and reduce the service life of the cable 2.

As shown in fig. 1-3, a suction tube 8 on the outer surface of a first heat dissipation ring 5 is connected with a sliding adsorption plate 9 inside, a suction tube 8 on the outer surface of a second heat dissipation ring 6 is connected with a sliding piston plate 10 inside, a rotary swivel 11 is installed on the outer surface of one side of the first heat dissipation ring 5 opposite to the second heat dissipation ring 6 in an embedded manner, a shielding plate 12 is installed on the outer surface of one side of the swivel 11 inside the first heat dissipation ring 5, fan blades 13 are installed on the outer surface of one side of the swivel 11 outside the first heat dissipation ring 5, the suction tube 8 is respectively connected with the adsorption plate 9 and the piston plate 10 in a sliding friction manner, a spring is connected between the suction tube 8 and the adsorption plate 9, the swivel 11 is connected with the first heat dissipation ring 5 in a sliding friction manner, the shielding plate 12 is uniformly distributed on the inner side surface of the swivel 11, the fan blades 13 are uniformly distributed on the outer side surface of the swivel 11, wherein the shielding plate 12 is made of electromagnetic shielding material, the piston plate 10 is made of non-ferromagnetic material, the mode that the fan blades 13 are blown by external air flow to drive the rotating ring 11 and the shielding plate 12 to rotate is utilized, the shielding plate 12 can realize the adsorption effect of the magnetic field generated by cutting off the cable 2 on the absorbing plate 9 through blocking the absorbing plate 9 discontinuously, so that the absorbing plate 9 losing magnetic field adsorption can slide up and down under the pulling of a spring between the absorbing plate and the suction cylinder 8, the heat conduction oil fully cooled in the second heat dissipation ring 6 can be sucked into the heat absorption tube 3 through the heat absorption tube 3 by the heat absorption tube 3, meanwhile, the heat conduction oil in the heat absorption tube 3 is sucked into the first heat dissipation ring 5 through the guide tube 4 by the absorbing plate 9, the heat conduction oil with different temperatures can be fully mixed, when the gap between the 2 shielding plates 12 rotates to the suction cylinder 8, the absorbing plate 9 slides downwards under the influence of the magnetic field to press the heat conduction oil mixed in the first heat dissipation ring 5 to the heat absorption tube 3, the mixed heat-conducting oil in the heat absorption pipe 3 is pressed into the second heat dissipation ring 6, so that forced mixing and rapid heat conduction of the heat-conducting oil are realized.

As shown in fig. 1 and 5, an air chamber 14 is fixedly arranged on the outer surface of one side of the second heat dissipation ring 6, which is opposite to the first heat dissipation ring 5, the lower surface of the air chamber 14 is provided with an observation port 15, one end of the air chamber 14 is provided with a first pressure relief hole 16, a sliding slide bar 17 is connected inside the air chamber 14, and the outer surface of the sliding rod 17 is embedded with a color lump 18, the air chamber 14 is in sliding friction connection with the sliding rod 17, the air chamber 14 and the sliding rod 17 are both designed in an arc shape, the outer surface of the color block 18 is flush with the outer surface of the sliding rod 17, the air in the air chamber 14 can be heated and expanded by utilizing the heat release mode after the heat conduction oil in the second heat dissipation ring 6 absorbs the heat, so that the slide bar 17 slides under the action of the gas pressure and drives the color blocks 18 with different colors to move to the observation port 15, so that the maintainer can directly observe the color of the color block 18 exposed at the observation port 15 and judge the temperature condition inside the rubber layer 1.

As shown in fig. 1, 4 and 6, a cooling collar 19 is fixedly installed on the outer surface of one side of the first heat dissipation ring 5 opposite to the second heat dissipation ring 6, an evaporation port 20 is opened on the outer surface of the upper end of the cooling collar 19, a water collection tank 21 is fixedly installed on the outer surface of the upper end of the cooling collar 19, an upper cover 22 is placed inside the water collection tank 21, a second pressure relief hole 27 is opened on the outer surface of one end of the suction cylinder 8 away from the rubber layer 1, the cooling collar 19 is in a semicircular hollow design, the upper cover 22 is in an arc-shaped plate design, the upper cover 22 is positioned right above the evaporation port 20, the water collection tank 21 is arranged around the evaporation port 20, the inner side surface of the water collection tank 21 is attached to the outer side surface of the upper cover 22, a limiting frame 23 is fixedly installed on the outer surface of the cooling collar 19 on both sides of the water collection tank 21, a sponge 24 is placed inside the limiting frame 23, a water permeable hole 26 is opened on the upper surface of the limiting frame 23, the upper surface of the sponge 24 is fixedly connected with one end of a connecting rod 25, the other end of the connecting rod 25 penetrates through the upper surface of the limiting frame 23 and is fixedly connected with the upper cover 22, the connecting rod 25 is pushed by the sponge 24 in a water absorption expansion mode during rainfall, the connecting rod 25 drives the upper cover 22 to slide upwards, rainwater flows into the cooling lantern ring 19 through the evaporation port 20 through a gap between the upper cover 22 and the water collecting tank 21 after sliding upwards, so that the cooling lantern ring 19 can cool the surface temperature of the rubber layer 1 through contact with the rubber layer 1, the rubber layer 1 after cooling can absorb heat emitted by the cable 2 by using larger temperature difference, when the rainfall stops out of the sun, along with the evaporation of moisture in the sponge 24, the sponge 24 shrinks to enable the upper cover 22 to descend to be attached to the water collecting tank 21, the rapid evaporation of moisture in the cooling lantern ring 19 is avoided, and when the internal pressure of the cooling lantern ring 19 is increased due to the evaporation of the moisture in the cooling lantern ring 19, the steam can be discharged by pushing the upper cover 22 open, and the effect of water evaporation and heat dissipation cannot be influenced.

The working principle is as follows: when the heating and color-developing high-heat-conductivity composite cable is used, firstly, in the normal power-on working process of the cable, heat emitted by the cable 2 is absorbed by the heat absorption tube 3 and is gradually conducted to the first heat dissipation ring 5 and the second heat dissipation ring 6 through heat conduction oil and the flow guide tube 4, the first heat dissipation ring 5 and the second heat dissipation ring 6 emit heat to the outside through the heat dissipation plate 7, meanwhile, when raining, rainwater wets the sponge 24 through the water permeable holes 26 on the upper surface of the limiting frame 23, the sponge 24 expands to drive the connecting rod 25 and the upper cover 22 to slide upwards, the rainwater flows into the cooling lantern ring 19 through the gap exposed between the water collecting tank 21 and the upper cover 22 and the evaporation port 20, and the rubber layer 1 is cooled through the contact of the cooling lantern ring 19 and the rubber layer 1 so as to realize better absorption of the heat emitted by the cable 2 by the rubber layer 1;

when wind blows, the air flow drives the rotating ring 11 and the shielding plate 12 to rotate through the fan blades 13, so that the adsorption plate 9 is intermittently adsorbed by a magnetic field generated by current passing in the cable 2, the adsorption plate 9 is forced to mix heat conduction oil between the heat absorption pipe 3 and the first heat dissipation ring 5 and the second heat dissipation ring 6 in a sliding mode in the suction cylinder 8, heat conduction among the heat conduction oil is quicker, and the second pressure relief holes 27 play a role in balancing the suction cylinder 8 and the external air pressure in the sliding process of the adsorption plate 9 and the piston plate 10;

when the maintainer needs to monitor the temperature in the cable, observe the 18 colours of the colour lump on the surface of the slide bar 17 exposing the observation port 15 through the observation equipment, the slide bar 17 driven by the gas in the air chamber 14 slides to the inside temperature condition of the cable in the current section through the mode of driving the colour lumps 18 with different colours to slide to the observation port 15, and the first pressure relief hole 16 plays a role in balancing the air pressure in the air chamber 14 in the sliding process of the slide bar 17 so that the slide bar 17 can smoothly slide in the air chamber 14 without being influenced by pressure.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. The utility model provides a high heat conduction composite cable of color rendering type generates heat, includes rubber layer (1), cable (2), heat-absorbing pipe (3), first radiating ring (5) and second radiating ring (6), its characterized in that: the heat absorption device is characterized in that a heat absorption pipe (3) is arranged inside the rubber layer (1), a guide pipe (4) is fixedly arranged on the side surface of the heat absorption pipe (3), the guide pipe (4) penetrates through the side surface of the heat absorption pipe (3), the heat absorption pipe (3) is not communicated with the adjacent heat absorption pipe (2), a cable (2) is placed between the guide pipe (4) and the rubber layer (1), a first radiating ring (5) and a second radiating ring (6) are fixedly arranged on the outer surface of the rubber layer (1), a radiating plate (7) and a suction cylinder (8) are arranged on the outer surfaces of the first radiating ring (5) and the second radiating ring (6), a sliding adsorption plate (9) is connected inside the suction cylinder (8) on the outer surface of the first radiating ring (5), a sliding embedded piston plate (10) is connected inside the suction cylinder (8) on the outer surface of the second radiating ring (6), and a rotary embedded piston plate (10) is arranged on the outer surface of one side, facing away from the first radiating ring (5) to the second radiating ring (6) A movable rotating ring (11), a shielding plate (12) is fixedly arranged on the outer surface of one side of the rotating ring (11) which is positioned inside the first radiating ring (5), a fan blade (13) is fixedly arranged on the outer surface of one side of the rotating ring (11) which is positioned outside the first radiating ring (5), an air chamber (14) is fixedly arranged on the outer surface of one side of the second radiating ring (6) which is back to the first radiating ring (5), an observation port (15) is formed in the lower surface of the air chamber (14), a first pressure relief hole (16) is formed in one end of the air chamber (14), a sliding slide rod (17) is connected inside the air chamber (14), a color block (18) is embedded in the outer surface of the slide rod (17), a cooling sleeve ring (19) is fixedly arranged on the outer surface of one side of the first radiating ring (5) which is opposite to the second radiating ring (6), and an evaporation port (20) is formed in the outer surface of the upper end of the cooling sleeve ring (19), the outer fixed surface in the upper end of cooling lantern ring (19) is provided with water catch bowl (21), and upper cover (22) have been placed to the inside of water catch bowl (21), second pressure release hole (27) have been seted up to the one end surface of keeping away from rubber layer (1) in suction section of thick bamboo (8).

2. The heating and color developing type high-thermal-conductivity composite cable according to claim 1, characterized in that: honeycomb duct (4) are the cross and distribute in the inside of rubber layer (1), and 4 honeycomb ducts (4) are a set of to the surface of first cooling ring (5) and second cooling ring (6) is run through respectively at the both ends of 2 honeycomb ducts (4) of group.

3. The heating and color developing type high-thermal-conductivity composite cable according to claim 1, characterized in that: heating panel (7) evenly distributed is at the surface of first cooling ring (5) and second cooling ring (6), and heating panel (7) are the cavity design to the surface of first cooling ring (5) and second cooling ring (6) is run through to the one end of heating panel (7).

4. The heating and color developing type high-thermal-conductivity composite cable according to claim 1, characterized in that: the suction tube (8) is respectively connected with the adsorption plate (9) and the piston plate (10) in a sliding friction mode, and a spring is connected between the suction tube (8) and the adsorption plate (9).

5. The heating and color developing type high-thermal-conductivity composite cable according to claim 1, characterized in that: the rotating ring (11) is connected with the first heat dissipation ring (5) in a sliding friction mode, the shielding plates (12) are evenly distributed on the inner side surface of the rotating ring (11), and the fan blades (13) are evenly distributed on the outer side surface of the rotating ring (11).

6. The heating and color developing type high-thermal-conductivity composite cable according to claim 1, characterized in that: air chamber (14) and slide bar (17) are sliding friction connection, and air chamber (14) and slide bar (17) are the arc design, the surface of colour block (18) and the surface parallel and level of slide bar (17).

7. The heating color development type high-thermal-conductivity composite cable according to claim 1, characterized in that: the cooling lantern ring (19) is in a semicircular hollow design, the upper cover (22) is in an arc plate-shaped design, and the upper cover (22) is located right above the evaporation port (20).

8. The heating and color developing type high-thermal-conductivity composite cable according to claim 1, characterized in that: the water collecting tank (21) is arranged around the evaporation opening (20), and the inner side surface of the water collecting tank (21) is attached to the outer side surface of the upper cover (22).

9. The heating and color developing type high-thermal-conductivity composite cable according to claim 1, characterized in that: the outer fixed surface of the cooling lantern ring (19) of water catch bowl (21) both sides is provided with spacing frame (23), sponge (24) have been placed to the inside of spacing frame (23), the upper surface of spacing frame (23) has been seted up and has been permeated water hole (26).

10. The heating color development type high-thermal-conductivity composite cable according to claim 9, characterized in that: the upper surface of the sponge (24) is fixedly connected with one end of a connecting rod (25), and the other end of the connecting rod (25) penetrates through the upper surface of the limiting frame (23) and is fixedly connected with the upper cover (22).

Images