CN113276567A

CN113276567A - Precision heating device based on high-efficiency heat conduction wave fiber

Info

Publication number: CN113276567A
Application number: CN202110429415.0A
Authority: CN
Inventors: 孙晓宁
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-04-21
Filing date: 2021-04-21
Publication date: 2021-08-20

Abstract

The invention discloses a precision heating device based on high-efficiency heat conduction wave fiber, which comprises a spraying device, the spraying device comprises a spraying box, a fixed station is arranged at the lower side in the spraying box, a moving station is arranged at the upper side in the spraying box, the lower end of the mobile station is provided with a spray head, the mobile station is internally provided with a heating device, the lower side of the fixed station is provided with a testing device, a cooling device is arranged in the fixed table, the heating device comprises a transmission assembly, the transmission assembly comprises a transmission roller and a transmission groove, the heating device also comprises a rotating shaft, the rotating shaft is arranged in the mobile station, a rotating sleeve is sleeved outside the rotating shaft, the transmission roller and the transmission groove are respectively arranged on the surface of the rotating shaft and the inner wall of the rotating sleeve.

Description

Precision heating device based on high-efficiency heat conduction wave fiber

Technical Field

The invention relates to the technical field of clothes painting, in particular to a precise heating device based on high-efficiency heat conduction wave fibers.

Background

The dyeing of the clothes is to add color to the clothes, also called coloring, and means that the fabric is colored by influencing the fabric by a chemical dyeing agent or other methods. The dyeing method is ancient and continuously developed, the garment dyeing technology established on fabric components can restore and change colors again, the color and luster of clothes are increased, and the clothes and the like are not subjectively satisfactory in color and can be changed into more colors for the clothes through the dyeing technology after being worn or used for a period of time.

When dyeing clothes, because the pigment that dilutes can be like the diffusion all around, so the pigment that the heating keeps liquid state commonly uses is scribbled the look, and because the difference of clothing material, sometimes even batch difference can lead to the heat resistance of clothes different, and the kind of pigment is different, required heating temperature also is different, the whole heat dissipation of commonly using though can adapt to the quick application when the low temperature, and when high temperature spraying, scribble the look speed and be slower, when whole heat dissipation can lead to the rear side cooling, the cooling water temperature is not enough, can not in time cool down and lead to the clothing to damage. Therefore, it is necessary to design a precise heating device based on high-efficiency thermal conduction wave fiber, which can be adapted to different clothes and pigments and can locally and rapidly cool high-temperature pigments.

Disclosure of Invention

The invention aims to provide a precision heating device based on high-efficiency thermal conduction wave fibers, and the precision heating device is used for solving the problems in the background technology.

In order to solve the technical problems, the invention provides the following technical scheme: the utility model provides a precision heating device based on high-efficient heat-conduction wave fibre, includes the spraying device, the spraying device includes the spraying case, spraying incasement downside is provided with the fixed station, spraying incasement upside is provided with the mobile station, the mobile station lower extreme is provided with the shower nozzle, be provided with heating device in the mobile station, the fixed station downside is provided with testing arrangement, be provided with cooling device in the fixed station.

According to the technical scheme, the heating device comprises a transmission assembly, the transmission assembly comprises a transmission roller and a transmission groove, a plurality of transmission elastic blocks are arranged in the transmission groove, the transmission elastic blocks are of hollow structures, and the transmission roller is clamped between the transmission elastic blocks;

heating device still includes the rotation axis, the rotation axis sets up inside the mobile station, and one end is provided with motor one, the rotation axis overcoat is equipped with the swivel sleeve, the swivel sleeve surface is provided with a plurality of blades, the blade overcoat is equipped with the heating pipe, the inside heating piston that is provided with of heating pipe, the heating pipe is provided with the combustion gas groove outward, transmission roller and transmission groove set up respectively in rotation axis surface and swivel sleeve inner wall, are located a motor direction of rotation one end and swivel sleeve surface pipe connection in the transmission elastic block, and the pipeline mouth is provided with the filter screen, the other end and blade surface pipe connection in the transmission elastic block.

According to the technical scheme, the heating piston comprises a piston groove, a piston rod is arranged in the piston groove, one end, away from the rotating shaft, of the piston rod is provided with a piston plate, a spring is arranged between the piston plate and the outer wall of the heating pipe, the other end of the piston rod is provided with a piston sleeve, the piston sleeve is close to one side of the rotating shaft and is of a matched structure with the inner wall of the piston groove, the spring is arranged between the other side of the piston sleeve and the piston plate, the piston rod is close to one end of the rotating shaft and a blade, the rotating shaft is fixedly mounted with a magnet, the magnetism of the magnet is opposite, one side, away from the rotating shaft, of the inner wall of the piston groove is provided with a spark plug, and one side of the piston rod is provided with an ignition extrusion block.

According to the technical scheme, the testing device comprises a plurality of air suction ports which are uniformly arranged on the inner side wall of the spraying box and the surface of the fixed table, the air suction pipeline is connected with an air suction pipeline, the inner wall of the air suction pipeline is provided with threads, a spline shaft is arranged in the air suction pipeline, one end of the spline shaft is provided with a motor II, a friction rotating block is sleeved on the spline shaft in a sliding manner, the outer wall of the friction rotating block and the inner wall of the air suction pipeline are made of materials which are easy to generate heat by friction, the friction force between the friction rotating block and the spline shaft is large, the tail end of the friction rotating block is provided with an extrusion block in a sliding way, a metal filter screen is arranged in the air suction pipeline at the rear side of the friction rotating block, the extrusion block and the metal filter screen are respectively electrically connected to an external power supply and the first motor, and the inner wall of the air suction pipeline positioned in front of the metal filter screen is electrically connected with the second motor.

According to the technical scheme, the metal filter screen edge the pipeline outer wall of breathing in is provided with the temperature sensing groove, the temperature sensing inslot intussuseption is filled with the aqueous ammonia, temperature sensing groove pipe connection has the adjustment piston, the piston board downside is provided with the adjusting plate, rotation axis one side is kept away from with the piston bush to the adjusting plate inboard is the cooperation structure, be provided with the elasticity tunic between piston board and the adjusting plate edge, the welding has the piston bush fixture block on being located the piston bush of elasticity tunic, the extrusion piece that ignites welds in adjusting plate one side, the elasticity tunic is inside to be connected through reverse check valve and adjustment piston extension direction one end pipeline, the elasticity is divided the inside one end pipe connection that still extends through forward check valve and adjustment piston extension direction of diaphragm, and the pipeline mouth is provided with the inflation piece, the inflation piece is made by thermal energy material.

According to the technical scheme, the cooling device comprises a gear pump, the gear pump is fixedly arranged at one end of a rotary sleeve, an inlet pipeline of the gear pump is connected with a cooling water tank, an outlet pipeline of the gear pump is connected with a flow valve, the flow valve comprises a flow valve inlet, a pipeline port of the flow valve inlet is provided with a flow valve elastic bag, the bottom of the flow valve is provided with a high flow water outlet and a low flow water outlet, the pipeline ports of the high flow water outlet and the low flow water outlet are respectively provided with a high flow ball and a low flow ball, the high flow ball and the low flow ball are respectively internally provided with a high flow elastic ball and a low flow elastic ball, the inner part of the flow valve elastic bag is connected with an inner pipeline of the high flow ball and is filled with low-density liquid, the inner part of the high flow elastic ball, the low-flow elastic ball is filled with easily compressible gas;

the cooling device further comprises a water storage tank, the water storage tank is arranged inside the fixed table and connected with the low-flow water outlet pipeline, a cooling pipe is arranged on the lower side of the water storage tank and connected with the high-flow water outlet pipeline, a plurality of cooling assemblies are arranged on the upper side of the water storage tank and connected with the inner pipeline of the cooling pipe.

According to the technical scheme, the cooling assembly comprises the cooling grooves, the cooling grooves are evenly distributed on the upper sides of the cooling pipes, the lower ends of the cooling grooves penetrate through the water storage tank and extend into the cooling pipes, the cooling sliding blocks are arranged inside the cooling grooves in a sliding mode, the cooling diaphragms are arranged between the upper sides of the cooling sliding blocks and the top ends of the cooling grooves, and the cooling diaphragms are filled with expansion gas.

According to the technical scheme, the cooling groove top is thin, the cooling groove top and the cooling slide block side wall are of a matched structure, friction force between the cooling groove top and the cooling slide block is large, the lower side of the cooling slide block and the lower end of the cooling groove are of a matched structure, a cooling through hole is formed in the upper position of the cooling slide block, the bottom of the cooling pipe is provided with the slide block groove, the slide block groove and the cooling slide block bottom are of a matched structure, a first extrusion film and a second extrusion film are arranged between the first extrusion film and the second extrusion film, the two extrusion films are located inside the first extrusion film, four separation films are arranged between the first extrusion film and the first extrusion film, the first extrusion film is divided into four parts, and the first extrusion film is connected with two inner pipelines of the extrusion films close to other cooling assemblies respectively, and friction force between the cooling groove top and the cooling slide block is large.

According to the technical scheme, the top of the cooling tank is connected with the surface of the fixed platform through the high-efficiency heat conduction wave fibers.

According to the technical scheme, the heating pipe is connected with a plurality of paint boxes through electromagnetic valve pipelines.

Compared with the prior art, the invention has the following beneficial effects: according to the invention, clothes are put into the spraying box for painting, the mobile station drives the spray head to draw patterns, the testing device can recover and test fluff adhered to the clothes during production of the clothes before spraying is started, the heat resistance degree of the clothes is tested, the heating device is driven to adjust the heating mode of the heating device to adapt to different pigments, and the cooling device automatically adjusts the cooling mode according to different heating modes to protect the clothes.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

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

FIG. 2 is a schematic view of the heating apparatus of the present invention;

FIG. 3 is a schematic view of the heated piston configuration of the present invention;

FIG. 4 is a schematic structural diagram of a testing apparatus according to the present invention;

FIG. 5 is a schematic view of the flow valve construction of the present invention;

FIG. 6 is a schematic view of the cooling assembly of the present invention;

in the figure: 1. a spraying device; 11. a spraying box; 12. a fixed table; 13. a mobile station; 14. a spray head; 2. a heating device; 21. a transmission assembly; 211. a drive roller; 212. a transmission groove; 213. a transmission elastic block; 214. filtering with a screen; 22. a rotating shaft; 23. a first motor; 24. a rotating sleeve; 25. a blade; 26. heating a tube; 27. heating the piston; 271. a piston groove; 272. a piston rod; 273. a piston plate; 274. a piston sleeve; 275. a spark plug; 276. igniting the extrusion block; 277. an adjustment plate; 278. an elastic separation film; 279. a piston sleeve clamping block; 28. a combustion gas tank; 3. a testing device; 31. an air suction port; 32. an air intake duct; 33. a spline shaft; 34. a second motor; 35. a friction rotation block; 36. extruding the block; 37. a metal screen; 38. a temperature sensing groove; 4. a cooling device; 41. a gear pump; 42. a flow valve; 421. a flow valve inlet; 422. a flow valve elastic bladder; 423. a high flow outlet; 424. a low flow outlet; 425. a high flow ball; 426. a low flow ball; 427. a high flow elastic ball; 428. a low flow elastomeric ball; 43. a water storage tank; 44. a cooling tube; 45. a cooling assembly; 451. a cooling tank; 452. cooling the slide block; 453. cooling the diaphragm; 454. cooling the through hole; 455. a slider slot; 456. extruding the first film; 457. and extruding the second film.

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 the following technical solutions: a precision heating device based on high-efficiency heat conduction wave fibers comprises a spraying device 1, wherein the spraying device 1 comprises a spraying box 11, a fixed table 12 is arranged at the lower side in the spraying box 11, a movable table 13 is arranged at the upper side in the spraying box 11, a spray head 14 is arranged at the lower end of the movable table 13, a heating device 2 is arranged in the movable table 13, a testing device 3 is arranged at the lower side of the fixed table 12, a cooling device 4 is arranged in the fixed table 12, clothes are put into the spraying box 11 for painting, the movable table 13 drives the spray head 14 to paint patterns, the testing device 3 can recover and test fluff adhered to the clothes during clothes production before spraying, the heat resistance degree of the clothes is tested, the heating device 2 is driven to adjust the heating mode of the heating device 2 to adapt to different pigments, the cooling device 4 automatically adjusts the cooling mode according to different heating modes to protect the clothes;

the heating device 2 comprises a transmission assembly 21, the transmission assembly 21 comprises a transmission roller 211 and a transmission groove 212, a plurality of transmission elastic blocks 213 are arranged in the transmission groove 212, the transmission elastic blocks 213 are of hollow structures, and the transmission roller 211 is clamped between the transmission elastic blocks 213;

the heating device 2 further comprises a rotating shaft 22, the rotating shaft 22 is arranged inside the moving table 13, a motor 23 is arranged at one end of the rotating shaft 22, a rotating sleeve 24 is sleeved outside the rotating shaft 22, a plurality of blades 25 are arranged on the surface of the rotating sleeve 24, heating pipes 26 are sleeved outside the blades 25, heating pistons 27 are arranged inside the heating pipes 26, a combustion gas groove 28 is arranged outside the heating pipes 26, transmission rollers 211 and transmission grooves 212 are respectively arranged on the surface of the rotating shaft 22 and the inner wall of the rotating sleeve 24, one end of a transmission elastic block 213 located in the rotating direction of the motor 23 is connected with a pipeline on the surface of the rotating sleeve 24, a filter screen 214 is arranged at the opening of the pipeline, the other end of the transmission elastic block 213 is connected with a pipeline on the surface of the blade 25, when the transmission rollers 211 roll in the transmission grooves 212, the transmission elastic block 213 is transmitted, if the strength of the transmission elastic block 213 is low, the transmission rollers 211 can easily press down the transmission elastic block 213, so that the transmission rollers 211 and the transmission grooves 212 are easy to idle rotation, the transmission ratio of the transmission assembly 21 is reduced, when the strength of the transmission elastic block 213 is high, the transmission elastic block 213 is difficult to press down by the transmission roller 211, the transmission elastic block 213 is easy to clamp the transmission roller 211, so that idle rotation is not easy to occur between the transmission roller 211 and the transmission groove 212, the transmission ratio of the transmission assembly 21 is increased, when the transmission assembly 21 issues idle rotation, the transmission elastic block 213 is repeatedly squeezed and bounced, when bounced, the other side is blocked by the transmission roller 211, when bounced, the side transmission elastic block 213 sucks the pigment in the heating pipe 26 through the pipeline without the filter screen 214, when next time is squeezed, the pigment in the transmission elastic block 213 is squeezed into the pipeline with the filter screen 214 to be discharged due to rolling of the transmission roller 211, if the heating temperature of the pigment is too low, the pigment becomes sticky, the pigment is difficult to pass through the filter screen 214 and only can flow out slowly, and simultaneously the filter screen 214 can filter out the coagulated matters in the pigment, the pigment and the coagulants support the transmission elastic block 213, the strength of the transmission elastic block 213 is improved, the transmission ratio of the transmission assembly 21 is increased, the rotating speed of the blade 25 is increased, the stirring is accelerated, the heating piston 27 is adjusted to avoid the pigment coagulation, meanwhile, the coagulants are crushed by utilizing the extrusion of the transmission roller 211 and the filter screen 214, the generation of inferior products caused by spraying the coagulants on clothes is avoided, when the pigment temperature is overhigh, the viscosity of the pigment is reduced and the pigment directly flows out of the transmission elastic block 213, the strength of the transmission elastic block 213 is reduced, the transmission ratio of the transmission assembly 21 is reduced, the rotating speed of the blade 25 is reduced, the heating piston 27 is adjusted, the flow rate of the pigment is reduced, the generation of inferior products caused by excessive pigment spraying is avoided, the effects of automatic control detection in real time and matching with the heating piston 27 according to the viscosity of the pigment are achieved, when the pigment temperature is overlow, the stirring is accelerated, the phenomenon that the pigment flow rate is too slow and the local spraying is too little is avoided, simultaneously, the coagulations in the pigment are eliminated, when the pigment temperature is too high, the stirring is decelerated, the phenomenon that the pigment flow rate is too fast and the local spraying is too much is avoided, and the uniform spraying of clothes is ensured;

the heating piston 27 includes a piston groove 271, a piston rod 272 is disposed in the piston groove 271, one end of the piston rod 272 away from the rotating shaft 22 is provided with a piston plate 273, a spring is disposed between the piston plate 273 and the outer wall of the heating pipe 26, the other end of the piston rod 272 is provided with a piston sleeve 274, one side of the piston sleeve 274 close to the rotating shaft 22 is in a matching structure with the inner wall of the piston groove 271, and a spring is disposed between the other side of the piston sleeve and the piston plate 273, one end of the piston rod 272 close to the rotating shaft 22 and one end of the vane 25 away from the rotating shaft 22 are fixedly provided with magnets, and the magnets have opposite magnetism, one side of the inner wall of the piston groove 271 away from the rotating shaft 22 is provided with a spark plug 275, one side of the piston rod 272 is provided with an ignition extrusion block 276, when the piston rod 272 and the vane 25 are aligned, the piston rod 272 can be extended into the piston groove 271 by the magnetic force at this time, and a part of the gas in the combustion gas groove 28 is sealed in the piston groove 311, the spark plug 275 is pressed down by the ignition extrusion block 276, small explosion occurs in the piston groove 311, the pigment is heated by the heat of the explosion, the piston sleeve 274 can transmit the impact of the explosion to the pigment while transmitting the heat of the explosion, extends out, shakes and disperses the part of the locally accumulated pigment, pushes the condensate accumulated at the tail end of the piston groove 27 to the middle of the heating pipe 26, facilitates the transmission component 21 to crush the pigment, and due to the influence of the transmission component 21, the blade 25 can adjust the rotating speed along with the pigment condition, so that the heating piston 27 can achieve the effect of automatically accelerating the heating rate when the pigment temperature is too low in real time according to the pigment condition, simultaneously prevents the accumulation of the pigment by the explosion in the heating piston 27, and assists the transmission component 21 to eliminate the condensate in the pigment, ensures the flowability of the pigment, enables the clothes to be sprayed uniformly, and avoids the pigment residue, the color can be conveniently changed at any time;

the testing device 3 comprises a plurality of air suction ports 31, the air suction ports 31 are uniformly arranged on the inner side wall of the spraying box 11 and the surface of the fixed table 12, the air suction ports 31 are connected with an air suction pipeline 32 through pipelines, threads are arranged on the inner wall of the air suction pipeline 32, a spline shaft 33 is arranged in the air suction pipeline 32, a second motor 34 is arranged at one end of the spline shaft 33, a friction rotating block 35 is sleeved on the spline shaft 33 in a sliding mode, the outer wall of the friction rotating block 35 and the inner wall of the air suction pipeline 32 are made of materials which easily generate heat through friction, the friction force between the friction rotating block 35 and the spline shaft 33 is large, an extruding block 36 is arranged at the tail end of the friction rotating block 35 in a sliding mode, a metal filter screen 37 is arranged in the air suction pipeline 32 at the rear side of the friction rotating block 35, the extruding block 36 and the metal filter screen 37 are electrically connected to an external power supply and the first motor 23 respectively, the inner wall of the air suction pipeline 32 in front of the metal filter screen 37 is electrically connected with the second motor 34, the spline shaft 33 ensures that the second motor 34 can drive the friction rotating block 35 to rotate, and meanwhile the friction rotating block 35 can rotate 33, when spraying is started, the friction rotating block 35 is far away from the metal filter screen 37, the motor second 34 is powered on, the friction rotating block 35 and the air suction pipeline 32 form a thread pump through threads on the inner wall of the air suction pipeline 32, fluff on the surface of clothes is sucked away through the air suction port 31 to avoid defective products caused by spraying, meanwhile, the friction rotating block 35 can slowly approach to one side of the metal filter screen 37 through the threads, because the friction force between the friction rotating block 35 and the spline shaft 33 is large, the moving speed of the friction rotating block 35 is slow, the fluff can be fully recovered and accumulated on the metal filter screen 37 before the extrusion block 36 is contacted with the metal filter screen 37, when the extrusion block 36 is contacted with the metal filter screen 37, the extrusion block 36 can extrude the fluff, and heat is generated through friction between the outer wall of the friction rotating block 35 and the inner wall of the air suction pipeline 32, continuously increasing the temperature, when reaching the temperature which can damage the clothes, the fluff strength is reduced, the fluff is extruded and broken, the extrusion block 36 is contacted with the metal filter screen 37, the motor II 34 is closed, the temperature test is stopped, the motor I23 is started, the spraying is started, the effect of automatically collecting the fluff is achieved before the spraying is started, the fluff is prevented from floating to other positions to cause defective products at the spraying position, meanwhile, the collected fluff is utilized, the heat-resistant temperature of the clothes can be automatically detected under the condition of not damaging the clothes, so that the cooling mode can be adjusted according to the self property of the clothes to adapt to different types and different batches of clothes;

the outer wall of the air suction pipeline 32 at the edge of the metal filter screen 37 is provided with a temperature sensing groove 38, the temperature sensing groove 38 is filled with ammonia water, the pipeline of the temperature sensing groove 38 is connected with an adjusting piston, the lower side of a piston plate 273 is provided with an adjusting plate 277, the inner side of the adjusting plate 277 and the side of the piston sleeve 277, which is far away from the rotating shaft 22, are of a matching structure, an elastic separation membrane 278 is arranged between the piston plate 273 and the edge of the adjusting plate 277, a piston sleeve clamping block 279 is welded on the piston sleeve 277 positioned on the elastic separation membrane 278, an ignition extrusion block 276 is welded on one side of the adjusting plate 277, the interior of the elastic separation membrane 278 is connected with one end pipeline in the extension direction of the adjusting piston through a reverse one-way valve, the interior of the elastic separation membrane 278 is also connected with one end pipeline in the extension direction of the adjusting piston through, the ammonia water in the temperature sensing groove 38 is heated at the same time, so that ammonia gas is decomposed by the ammonia water, the adjusting piston is driven to contract through the pipeline, hydraulic oil in the elastic separation membrane 278 is extracted, the distance between the piston plate 273 and the adjusting plate 277 is reduced, the ignition extrusion block 276 and the adjusting plate 277 move together, the higher the fire resistance of clothes is, the larger the retraction distance of the adjusting plate 277 is, heat generated in temperature test and spraying explosion can expand the expansion block to block the pipeline to prevent the hydraulic oil from flowing back before spraying is finished, after the distance between the piston plate 273 and the adjusting plate 277 is reduced, the amount of gas brought into the piston groove 271 by the piston rod 272 is increased, so that heat generated by explosion is increased, at the moment, the internal overheating of the heating device 2 can slow down the rotation of the blades 25, the explosion frequency is reduced, a piston sleeve 279 fixture block is used for avoiding the phenomenon that the piston sleeve 274 extends out too long to cause ammonia gas leakage, and the effect that the rotating speed of the rotating shaft 22 is influenced by the heat resistance degree of clothes and the melting point of pigments is achieved at the same time, for clothes with high heat resistance, the melting point of the pigment is not too high all the time, the rotating speed of the rotating shaft 22 is low all the time, for clothes with poor heat resistance, the melting point of the pigment is too high all the time, the rotating speed of the rotating shaft 22 is high all the time, for clothes with medium heat resistance, the pigment with low melting point is used, the rotating speed of the rotating shaft 22 is low, the pigment with high melting point is used, the rotating speed of the rotating shaft 22 is also low, the pigment which is automatically detected to keep fluidity according to the heat resistance degree of the clothes and has the temperature exceeding the heat resistance critical point of the clothes is reflected on the ship speed of the rotating shaft 22, different cooling modes are conveniently adopted for safe pigment and unsafe pigment, and the quality of the painted clothes is ensured;

the cooling device 4 comprises a gear pump 41, the gear pump 41 is fixedly arranged at one end of the rotary sleeve 24, an inlet pipeline of the gear pump 41 is connected with a cooling water tank, an outlet pipeline of the gear pump 41 is connected with a flow valve 42, the flow valve 42 comprises a flow valve inlet 421, a pipeline port of the flow valve inlet 421 is provided with a flow valve elastic bag 422, the bottom of the flow valve 42 is provided with a high flow water outlet 423 and a low flow water outlet 424, the pipeline ports of the high flow water outlet 423 and the low flow water outlet 424 are respectively provided with a high flow ball 425 and a low flow ball 426, a high flow elastic ball 427 and a low flow elastic ball 428 are respectively arranged in the high flow ball 425 and the low flow ball 426, the inside of the flow valve elastic bag 422 is connected with the inside pipeline of the high flow ball 425, and are filled with low-density liquid, the interior of the high-flow elastic ball 427 is connected with the interior of the low-flow ball 426 through a pipeline, high-density liquid is filled in the low-flow elastic ball 428, and easily compressible gas is filled in the low-flow elastic ball;

the cooling device 4 further comprises a water storage tank 43, the water storage tank 43 is arranged inside the fixed table 12 and is connected with a low-flow water outlet 424 through a pipeline, a cooling pipe 44 is arranged on the lower side of the water storage tank 43, the cooling pipe 44 is connected with a high-flow water outlet 423 through a pipeline, a plurality of cooling assemblies 45 are arranged on the upper side of the water storage tank 43, the cooling assemblies 45 are connected with the internal pipeline of the cooling pipe 44, when water enters the flow valve 42, the flow valve elastic bag 422 is impacted at the inlet 421 of the flow valve, low-density liquid in the flow valve elastic bag 422 enters the high-flow ball 425, the density of the high-flow ball 425 is reduced, the high-flow elastic ball 427 is extruded, high-density liquid in the high-flow elastic ball 427 is extruded into the low-flow ball 426, the density of the low-flow ball 426 is increased, the low-flow elastic ball 428 is extruded, when the pigment temperature is safe, the rotating speed of the rotating sleeve 24 is low, the water output by the gear pump 41 is small, at the moment, the density change of the high-flow ball 425 and the low-flow ball 426 is low, the high-flow ball 425 keeps sinking, the low-flow ball 426 keeps floating, water directly flows into the water storage tank 43 to integrally cool clothes to adapt to quick spraying, the quick cooling after spraying is ensured, when the temperature of the pigment is overhigh, the rotating speed of the rotary sleeve 24 is high, the output water quantity of the gear pump 41 is large, the density change of the high-flow ball 425 and the low-flow ball 426 is large, the high-flow ball 425 floats, the low-flow ball 426 sinks, water flows into the cooling pipe 44 to be away from the clothes, the water can keep low temperature, the heat can be quickly absorbed when spraying, the effect of automatically adjusting the cooling mode according to the situation is achieved, the integral slow cooling is carried out on safe pigment to adapt to quick spraying, the coating can be uniformly sprayed, and for the pigment with overhigh temperature, the cooling water is kept away from the clothes, the spraying speed is matched with the lower spraying speed so as to keep lower temperature and cool the sprayed part in time;

the cooling assemblies 45 all comprise cooling grooves 451, the cooling grooves 451 are uniformly distributed on the upper side of the cooling pipe 43, the lower end of the cooling groove 451 penetrates through the water storage tank 43 and extends into the cooling pipe 44, a cooling slide block 452 is arranged in the cooling groove 451 in a sliding mode, a cooling diaphragm 453 is arranged between the upper side of the cooling slide block 452 and the top end of the cooling groove 451, expansion gas is filled in the cooling diaphragm 453, the upper side of the cooling slide block 452 outside the cooling diaphragm 453 is connected with the side wall of the lower end of the cooling slide block 452 through a pipeline, when paint with too high temperature is sprayed, the expansion gas in the cooling slide block 453 is thermally expanded due to the temperature, the cooling slide block 452 is pushed downwards, the lower end of the cooling slide block 452 enters into the cooling pipe 43, the two sides of the cooling pipe 43 are blocked, cooling water can only flow through the two sides of the cooling slide block 453, the expansion gas shrinks when the cooling water is cooled, the cooling slide block 452 is sucked back to be reset, the pipeline is closed after the cooling is completed, the effect that when paint with too high temperature is sprayed, the sprayed part is only cooled locally is achieved, so that the sprayed part is cooled rapidly, the problems that when the paint is cooled integrally, the temperature of rear cooling water is insufficient due to the fact that the cooling water absorbs more heat, the temperature of the paint is difficult to reduce rapidly, and clothes are damaged are solved, and the quality of the clothes is improved;

cooling groove 451 has a thin top portion and a fitting structure with the side wall of cooling slider 452, the friction between the top portion of cooling groove 451 and cooling slider 452 is large, the lower side of cooling slider 452 and the lower end of cooling groove 451 are fitting structures, and a cooling through hole 454 is provided at an upper position inside, a slider groove 455 is provided at the bottom of cooling pipe 44, a fitting structure is provided at the bottom of slider groove 455 and cooling slider 452, and a first squeeze film 456 and a second squeeze film 457 are provided therebetween, second squeeze film 457 is located inside first squeeze film 456 and four separation films are provided therebetween, the separation films divide the interior of first squeeze film 456 into four parts, first squeeze film 456 of each part is respectively connected to the internal pipes of second squeeze films 457 adjacent to other cooling elements 45, because the friction between the top portion of cooling groove 451 and cooling slider 452 is large, a large pressure is required to be generated in cooling diaphragm 453, and because only the upper end of slider groove 455 has a large friction with cooling slider 452, after cooling slide block 452 moves a certain distance, cooling slide block 452 loses resistance, cooling slide block 452 is quickly pressed down by large air pressure, cooling slide block 452 is clamped in slide block groove 455 to block a cooling pipeline, water directly flows through cooling through hole 454 without cooling temporarily, hydraulic oil in extrusion film two 457 is uniformly extruded into a part of extrusion film one 456 of other cooling component 45, when next cooling slide block 452 is pressed down, part of hydraulic oil is pressed back into extrusion film two 457 to slightly lift cooling slide block 452, cooling through hole 454 is blocked by the bottom of cooling groove 451 at the moment, the cooling pipeline is opened to start local cooling, when cooling slide block 452 is reset, the rest of hydraulic oil is sucked back, cooling component 45 can be reset integrally, and when paint with too high temperature is sprayed, the effect of delaying cooling of the sprayed part is achieved, after spraying, the paint is cooled after being uniformly dispersed, so that the phenomenon that the paint is cooled before being uniformly dispersed due to too fast cooling, and the paint is excessively sprayed or is excessively sprayed, and has uneven color or blocks is avoided;

the top of the cooling groove 451 is connected with the surface of the fixed table 12 through high-efficiency heat conduction wave fibers, and the high-efficiency heat conduction wave fibers can quickly transfer heat, so that the quick response of the invention is ensured, and the operation delay is avoided;

the heating pipe 26 is linked with a plurality of paint boxes through electromagnetic valve pipelines, and the paint boxes are switched through the electromagnetic valves, so that the paint can be automatically switched, and the effect of one-time complete spraying is achieved.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. The utility model provides a precision heating device based on high-efficient heat conduction wave fibre, includes spraying device (1), its characterized in that: the spraying device (1) comprises a spraying box (11), a fixing table (12) is arranged on the inner lower side of the spraying box (11), a mobile table (13) is arranged on the inner upper side of the spraying box (11), a sprayer (14) is arranged at the lower end of the mobile table (13), a heating device (2) is arranged in the mobile table (13), a testing device (3) is arranged on the lower side of the fixing table (12), and a cooling device (4) is arranged in the fixing table (12).

2. The precision heating device based on the high-efficiency thermal conduction wave fiber as claimed in claim 1, wherein: the heating device (2) comprises a transmission assembly (21), the transmission assembly (21) comprises a transmission roller (211) and a transmission groove (212), a plurality of transmission elastic blocks (213) are arranged in the transmission groove (212), the transmission elastic blocks (213) are of a hollow structure, and the transmission roller (211) is clamped between the transmission elastic blocks (213);

the heating device (2) further comprises a rotating shaft (22), the rotating shaft (22) is arranged inside the mobile station (13), one end of the rotating shaft is provided with a first motor (23), a rotating sleeve (24) is sleeved outside the rotating shaft (22), a plurality of blades (25) are arranged on the surface of the rotary sleeve (24), a heating pipe (26) is sleeved outside the blades (25), a heating piston (27) is arranged in the heating pipe (26), a combustion gas groove (28) is arranged outside the heating pipe (26), the transmission roller (211) and the transmission groove (212) are respectively arranged on the surface of the rotating shaft (22) and the inner wall of the rotating sleeve (24), one end of the transmission elastic block (213) positioned in the rotating direction of the motor I (23) is connected with a pipeline on the surface of the rotating sleeve (24), and the pipeline opening is provided with a filter screen (214), and the other end in the transmission elastic block (213) is connected with the surface pipeline of the blade (25).

3. The precision heating device based on the high-efficiency thermal conduction wave fiber as claimed in claim 2, wherein: the heating piston (27) comprises a piston groove (271), a piston rod (272) is arranged in the piston groove (271), one end of the piston rod (272) far away from the rotating shaft (22) is provided with a piston plate (273), a spring is arranged between the piston plate (273) and the outer wall of the heating pipe (26), a piston sleeve (274) is arranged at the other end of the piston rod (272), one side of the piston sleeve (274) close to the rotating shaft (22) and the inner wall of the piston groove (271) are in a matching structure, and a spring is arranged between the other side of the piston rod and the piston plate (273), magnets are fixedly arranged at one end of the piston rod (272) close to the rotating shaft (22) and one end of the blade (25) far away from the rotating shaft (22), and the magnetism of the magnets is opposite, a spark plug (275) is arranged on one side of the inner wall of the piston groove (271), which is far away from the rotating shaft (22), and an ignition extrusion block (276) is arranged on one side of the piston rod (272).

4. A precision heating apparatus based on high efficiency thermal conduction wave fiber according to claim 3, characterized in that: testing arrangement (3) includes a plurality of induction ports (31), induction port (31) evenly set up in spraying case (11) inside lateral wall and fixed station (12) surface, induction port (31) pipe connection has suction pipe (32), suction pipe (32) inner wall is provided with the screw thread, be provided with integral key shaft (33) in suction pipe (32), integral key shaft (33) one end is provided with motor two (34), sliding sleeve is equipped with friction rotating block (35) on integral key shaft (33), friction rotating block (35) outer wall and suction pipe (32) inner wall are made by easy friction heat generation material, frictional force is great between friction rotating block (35) and integral key shaft (33), friction rotating block (35) end slides and is provided with extrusion block (36), be provided with metal filter screen (37) in suction pipe (32) of friction rotating block (35) rear side, the squeezing block (36) and the metal filter screen (37) are respectively electrically connected to an external power supply and the first motor (23), and the inner wall of the air suction pipeline (32) positioned in front of the metal filter screen (37) is electrically connected with the second motor (34).

5. The precision heating device based on the high-efficiency thermal conduction wave fiber as claimed in claim 4, wherein: the outer wall of the air suction pipeline (32) at the edge of the metal filter screen (37) is provided with a temperature sensing groove (38), ammonia water is filled in the temperature sensing groove (38), a pipeline of the temperature sensing groove (38) is connected with an adjusting piston, an adjusting plate (277) is arranged on the lower side of the piston plate (273), one side, far away from the rotating shaft (22), of the inner side of the adjusting plate (277) and the piston sleeve (277) is of a matched structure, an elastic separation membrane (278) is arranged between the edges of the piston plate (273) and the adjusting plate (277), a piston sleeve clamping block (279) is welded on the piston sleeve (277) located on the elastic separation membrane (278), an ignition extrusion block (276) is welded on one side of the adjusting plate (277), the inner part of the elastic separation membrane (278) is connected with one end pipeline of the extending direction of the adjusting piston through a reverse one-way valve, the inner part of the elastic separation membrane (278) is connected with one end pipeline of the extending direction of the adjusting piston through a forward one-way valve, and the pipeline port is provided with an expansion block which is made of a thermal expansion material.

6. The precision heating device based on the high-efficiency thermal conduction wave fiber as claimed in claim 5, wherein: the cooling device (4) comprises a gear pump (41), the gear pump (41) is fixedly arranged at one end of a rotary sleeve (24), an inlet pipeline of the gear pump (41) is connected with a cooling water tank, an outlet pipeline of the gear pump (41) is connected with a flow valve (42), the flow valve (42) comprises a flow valve inlet (421), a pipeline port of the flow valve inlet (421) is provided with a flow valve elastic bag (422), the bottom of the flow valve (42) is provided with a high flow water outlet (423) and a low flow water outlet (424), the pipeline ports of the high flow water outlet (423) and the low flow water outlet (424) are respectively provided with a high flow ball (425) and a low flow ball (426), the high flow ball (427) and the low flow ball (428) are respectively arranged in the high flow ball (425) and the low flow ball (426), and the inside of the flow valve elastic bag (422) is connected with an internal pipeline of the high flow ball (425), the high-flow elastic ball (427) is internally connected with the low-flow ball (426) through a pipeline and is filled with high-density liquid, the low-flow elastic ball (428) is internally filled with easily compressible gas, and the low-flow elastic ball (428);

cooling device (4) still include aqua storage tank (43), aqua storage tank (43) set up inside fixed station (12), and with low flow delivery port (424) pipe connection, aqua storage tank (43) downside is provided with cooling tube (44), cooling tube (44) and high flow delivery port (423) pipe connection, aqua storage tank (43) upside sets up a plurality of cooling module (45), cooling module (45) and cooling tube (44) internal piping connection.

7. The precision heating device based on the high-efficiency thermal conduction wave fiber as claimed in claim 6, wherein: the cooling assembly (45) comprises cooling grooves (451), the cooling grooves (451) are uniformly distributed on the upper side of the cooling pipe (43), the lower end of the cooling groove (451) penetrates through the water storage groove (43) and extends into the cooling pipe (44), a cooling sliding block (452) is arranged inside the cooling groove (451) in a sliding mode, a cooling diaphragm (453) is arranged between the upper side of the cooling sliding block (452) and the top end of the cooling groove (451) in a snake mode, expansion gas is filled in the cooling diaphragm (453), and the upper side of the cooling sliding block (452) outside the cooling diaphragm (453) is connected with a side wall pipeline at the lower end of the cooling sliding block (452).

8. The precision heating device based on the high-efficiency thermal conduction wave fiber as claimed in claim 7, wherein: the top of the cooling groove (451) is thin, and the cooling groove and the side wall of the cooling slide block (452) are in a matching structure, the friction force between the top of the cooling groove (451) and the cooling slide block (452) is large, the lower side of the cooling slide block (452) and the lower end of the cooling groove (451) are in a matching structure, a cooling through hole (454) is arranged at the upper position in the cooling pipe, a sliding block groove (455) is arranged at the bottom of the cooling pipe (44), the bottom of the slider groove (455) and the bottom of the cooling slider (452) are in a matching structure, a first extrusion film (456) and a second extrusion film (457) are arranged between the first extrusion film (456), and four separation membranes are arranged between the first extrusion membrane and the second extrusion membrane, the first extrusion membrane (456) is divided into four parts, and the first extrusion membrane (456) of each part is respectively connected with an internal pipeline of a second extrusion membrane (457) adjacent to other cooling assemblies (45).

9. The precision heating device based on the high-efficiency thermal conduction wave fiber as claimed in claim 8, wherein: the top of the cooling groove (451) is connected with the surface of the fixed platform (12) through high-efficiency heat conduction wave fibers.

10. The precision heating device based on the high-efficiency thermal conduction wave fiber as claimed in claim 9, wherein: the heating pipe (26) is connected with a plurality of paint boxes through electromagnetic valve pipelines.