CN101666516A - Multifunctional domestic superconducting heat tube heater without electricity and light emitting diodes (LED) - Google Patents

Abstract

The invention relates to a multifunctional domestic superconducting heat tube heater without electricity and light emitting diodes (LED). The multifunctional domestic superconducting heat tube heaterwhich is heated by electromagnetic eddy-current and hot water without electricity comprises an evaporation box body, a gravity superconducting heat tube with a radiator, a hot air diffusion cover, a superconducting liquid hot air diffusion cover, a quartz infrared tube, a carbon fiber infrared tube, an infrared lamp, an electrothermal film, LEDs and a photoelectric cell board. The multifunctionaldomestic superconducting heat tube heater is particularly suitable for areas having no electricity, various electrothermal elements such as far infrared elements, the electrothermal films, electromagnetic induction elements, and the like can be used, and electricity can be saved by more than 60 percent. The invention is characterized in that the heater has good heat transfer effect, light weight,simple structure, uniform temperature distribution, large heat transmission quantity, long heat transmission distance, no electricity consumption and no heat transfer direction limit; an evaporation end and a condensation end can be exchanged, are easy to process and have long service life, reliability, low price and convenient popularization and application; and the heater has the social and economic benefit of energy saving and emission reduction, is a necessary trend of the current and future development and has great significance.

Description

The multifunctional domestic superconducting heat tube heating device of a kind of not electricity consumption and LED

Technical field

" the domestic heating apparatus " of building field.

Background technology

Current, the energy consumption of building trade accounts for 40% of national total energy consumption, and shared energy consumption accounts for 20% of total energy consumption in the warming in northern city, is continuing to use requisite coal combusting boiler or oil burning boiler or electric boiler in urban heating always, and this all is the non-renewable energy.And the loss of these methods energy is; The loss of boiler combustion coal is 55%～85%; Trunking loss is 30%.How to reduce winter heating energy consumption, be the task of top priority, extremely urgent.The present invention will provide " the multifunctional domestic superconducting heat tube heating device of a kind of not electricity consumption and LED "

Summary of the invention

The technical solution adopted for the present invention to solve the technical problems:

What is a super heat-conductive pipe heating device: heat-conducting medium (as superconducting fluid etc.) is filled with in radiator the inside, and heating medium (as water heater, electric heater, infrared electric heater, the electromagnetic induction heater heater etc. of powering with solar panel) is installed in radiator again.

Utilize burning in boiler to go out steam or hot water, be transported in the radiator (being commonly called as radiator) in the building by pipeline, the heat that sheds increases room temperature, and ducted steam or hot water are " heating installation ".

At present the kind of domestic heating system and selected radiator is a lot, and in development and changing, improvement along with people's life, progressively raising to the interior decoration requirement, the improvement of heating system and heat sink format, having proposed new requirement to the designer, below is several heating systems commonly used at present:

(1) common hot water system:

The heating system that adopts is generally vertical single-main distribution, two-pipe system or single two-pipe system at present, and a bright dress standpipe is established in each room or two rooms, and standpipe is positioned at the corner, room, and radiator is located in the middle of the exterior window.Common bright dress radiator can influence the attractive in appearance of whole room, and along with the raising of people to the building decoration standard, major part is done a heater cover with bright dress radiator at present.The usable floor area in room but heater cover can account for, and make its heat dissipation capacity reduce about 20%.

At present, Chang Yong radiator has following several:

(1) plain cast iron radiator: (2) modified form cast-iron radiator: (3) steel radiator system.

(2) radiant floor heating system

Adopt floor panel heating can effectively improve the comfort level in room.And this system can deduct indoor surface pipeline and radiator, is a kind of comparatively ideal heating form.Begun starting at present at home, estimated to have bigger development from now on.

The floor surface mean temperature of floor panel heating should be 26 ℃ of long-term dwell regions of personnel, the short stay zone is 30 ℃, the pipeline that is embedded in the floor can adopt the commissure high density polyethylene pipe, supply water temperature should adopt≤and 60 ℃, the supply and return water temperature difference should adopt 10 ℃, should lay thermal insulation layer under the heating tube of floor.Adopt floor panel heating, higher to construction requirement, difficulty is bigger, must do in strict accordance with program, just can reach high-quality, high standard.

(3) hot air heating system

Hot-air heating is delivered to bedroom, living room through the airduct that is located within the walls after being to use the warm-air drier that is located in the basement that outdoor cold air is heated, and this part air drains into outdoor respectively again through kitchen, toilet.It is organized ventilating system.General bedroom, living room rate of ventilation are per hour 2 times, to guarantee that people have enough fresh airs in the winter time.Air through the bedroom, the living room is discharged to kitchen, toilet again, do not cause the air of pollution to be back to bedroom, living room.This form first cost height, operating cost also is higher than other form heating systems, and nothing to be surprised at is still rare in China in America and Europe's villa buildings, believes in the near future and can grow up gradually.

(4) picture moulding or skirt panel radiator

Special cast-iron radiator.In 2.5 meters eminences of room picture moulding, be high about 8cm, the mirror line radiator of wide about 3cm, or be positioned at the skirting board place, be high about 8cm, the skirting board radiator of wide about 3cm, look similarly to be common picture moulding or skirting board, also can't see common radiator at the indoor pipeline of can't see.Do like this and can increase indoor effective usable floor area.Heating system adopts horizontal train.

(5) heating cable and Electric radiant Heating Film heating system

A kind of heating system that had just risen in recent years.The heat supply principle of heating cable is similar to floor panel heating, and Electric radiant Heating Film arranges in conjunction with the furred ceiling in room usually that then owing to adopted advanced Electric radiant Heating Film heating technology heating room air to reach the heating purpose, its thermal efficiency is far above common electrical heating installation kind equipment.Electric radiant Heating Film does not take the interior space, and safe and reliable, therefore has certain advantage in novel heating equipment.

Adopted existing gravity super heat-conductive pipe technology among the present invention: heat conduction of the present invention and thermal diffusion mainly are to adopt " heat pipe " or " gravity super heat-conductive pipe " element.China's comprehensive utilization of energy level is lower always, and " heat pipe " or " super heat-conductive pipe " element, has characteristics such as be easy to apply in industry simple in structure, cheap, easily manufactured.Thereby the research of heat pipe be applied in China and constantly expand, spread all over electronic component, computer, chemical industry, fields such as power and metallurgy.At present, the developmental research of hot pipe technique has become one of most active sphere of learning in industrial applications aspect.

After World War II, because engineering science and technology rapid development, the needs of power are rolled up.Nearly all electrical equipment (comprising transistor even) electric current by the time can produce heat, these heats must effectively be directed to the suitable place of holding and just be unlikely electrical equipment is damaged to some extent, can produce the new energy on the contrary.Therefore heat is delivered in and has become a very important problem in the engineering science in modern age.Nowadays heat transmission has all become one of main department in the department of mechanical engineering of the many universities of the U.S..

The source of heat pipe: heat pipe is invented at the Ge Lufoshi by my Mo Si research institute of Lars of California, USA university in 1963.As the term suggests it is a kind of pipe with high duty heat transfer performance, it is constantly to study and seek product under the high efficient heat device heat transmission scholar.Is heat pipe how to conduct heat actually? before the principle of not knowing heat pipe, preferably can understand the principle that common general heat is transmitted earlier.

The principle that heat is transmitted: heat transmission is heat energy is passed to the low temperature place by the high temperature place a phenomenon.It can be divided into conduction usually, three kinds of radiation and convection current.Conduction be two objects when contacting heat pass to the phenomenon of cryogenic object by high temp objects.The size of conduction heat mainly is to rely on the heat transfer coefficient of the temperature difference and object and decide.Usually the thermal conductivity factor of object for the highest, secondly is liquid with solid, and worst is gas, however in solid with metal for the highest.Radiation be two objects under not contacted situation, the phenomenon that heat is propagated by electromagnetic wave (or photon).Convection current is solid and fluid or out of phase fluid when contacting, the phenomenon that flows and conduct heat owing to fluid.

Two kinds of hot transport phenomenons are arranged in addition, are exactly that boiling heat is transmitted and the condensation heat transmission.They are included among the convection current usually, because recent two decades comes heat to transmit the research that the scholar makes earnest efforts, they are from wherein independently going out.

Boiling and to be condensate in heat the most outstanding in transmitting a bit be exactly that they are relevant with metamorphosis, wherein modal for evaporating and condensation.Evaporation and during condensation between liquid state and the steam state change required thermal energy be referred to as latent heat.

Lift a concrete instance, when a container that fills liquid was heated gradually, the temperature of liquid in containers raise gradually.If container continues to be heated, when surpassing boiling point to the fluid temperature near vessel surface, the liquid of vessel surface begins vaporization and has steam bubble to produce, and this phenomenon is referred to as boiling.Absorb a large amount of heat owing to vaporizing liquid from vessel surface this moment, and this hot transport phenomenon is referred to as boiling and transmits.Opposite, when gas touched colder solid, near the gas the surface of solids began to be condensed into liquid and emits its latent heat.In other words, colder solid has absorbed the latent heat of gas and made it to coagulate is liquid, and this heat transfer phenomenon is referred to as the condensation heat transmission.

As for the Heat Transfer of Heat Pipe on Heat Pipe phenomenon, do not belong to any in transmitting of above heat, it is conduction, evaporation, the combination of phenomenons such as convection current and condensation.The size of its heat conduction amount can than with any metal bar of volume up to more than thousand times, therefore heat pipe has caused that the U.S. and Europe is engaged in hot transfer study person's very big interest between the short several years.

The structure of heat pipe: heat pipe is the metal pipe of elongated a, hollow, two sealings in general.It has 15 centimeters long, also there are 15 meters long, its outer shape is regardless of, in theory almost the design of Any shape all is fine, tube inner wall is adhered to one deck capillary object (not having the capillary object in the gravity assisted heat pipe), soaking liquid in the capillary object, this liquid is referred to as the working solution of heat pipe, has been common heat pipe so.Yet so not simple when manufacturing actually, its structure is different according to the difference of heat conduction amount and temperature.The useful brass of present Manufactured heat pipe, nickel, stainless steel, tungsten and other alloy are done shell.

The kind of heat pipe working solution is more, and it comprises potassium, sodium, indium, caesium, lithium, bismuth, mercury, water, wood alcohol, acetone, the liquid nitrogen of refrigerant, liquid oxygen and some other inorganic salts etc.In fact, the selection of the shell of heat pipe and working solution thereof is all decided on the applicable cases of heat pipe.For example when the above high temperature of 1,000 degree Celsius, inside heat pipe is used liquid metals such as potassium, sodium more, but heat pipe is used for subzero 190 when spending, then inner more than with liquid nitrogen etc.

The basic functional principle of heat pipe: when an end of heat pipe places the higher temperatures place and when allowing the other end at the lower temperature place, the heat transfer phenomenon just begins to produce.Heat is at first passed metal pipe-wall by the high temperature place and is entered in the capillary object, the start vaporizer that is heated of the working solution in the capillary object.The part of heat pipe at the high temperature place just is referred to as evaporation partly.Gas after the evaporation accumulates in the evaporation hollow tube partly, and the other end to heat pipe flows simultaneously.Because the other end of heat pipe touches the lower temperature place, when arriving the colder other end, gas just begins condensation, and heat just passes the capillary object by gas at this moment, working solution and metal pipe-wall and import the lower temperature part into.Therefore heat pipe just is referred to as condensation partly in the part of lower temperature.The gas that was originally partly evaporated by evaporation in condensation has partly condensed into liquid again, these condensed liquid have partly flowed back to evaporation again partly because of the effect autocondensation of capillarity, so fluid moves in endless cycles, and heat has just passed to the low temperature place by the high temperature place, and this is the Heat Transfer of Heat Pipe on Heat Pipe principle.Because evaporation and condensation carry out under vapour pressure much at one, the temperature difference in the pipe is very little.As for the temperature difference of heat pipe two end housings, then mainly due to heat conduction by the tube wall outer rim through the capillary object, working solution is due to the gas.Referring to (Figure 18-1).

As placing under the same temperature difference heat pipe with two ends of volume metal bar, the heat conduction amount of heat pipe can reach more than thousand times of metal bar.In other words, when same heat during by heat pipe with the metal bar of volume, the temperature difference of heat pipe two ends is little more a lot of than metal bar.Because this specific character, heat pipe often are called as " near isothermal heat conduction " device.System, heat pipe is the most outstanding on structure and principle a bit to be the application of capillary object and capillarity.

" general heat pipe " is because the effect of capillarity, can not need the effect of external force and flow back to evaporation partly at condensation liquid partly, this makes heat pipe become a heat-transfer device that does not fully independently have movable members, acting on of capillarity simultaneously also make heat pipe become the unique apparatus of conducting heat in the space, because still can make fluid flow under the weightlessness of space state.Referring to (Figure 18-1).

It also is to utilize the evaporation of working medium and condensation to transmit heat for " gravity assisted heat pipe ", and being does not need additionaling power and working medium circulates voluntarily.The difference of it and general heat pipe (capillarity) is there is not the imbibition core in the pipe (capillary object and capillarity), and it is not the capillary force that is produced by the imbibition core that condensate liquid returns evaporator section from cold doubtful section, but by self and gravity of condensate liquid.Therefore gravity assisted heat pipe is that directionality is arranged, and evaporator section must place the below of condensation segment.Because gravity assisted heat pipe does not have the imbibition core, thus not only simple in structure, with low cost, and also heat transfer property is good, reliable operation.Referring to (Figure 18-2).

The advantage of heat pipe and application thereof: the advantage of heat pipe is a lot, mainly is because due to the special performance that it is had on structure and principle; Structurally, it is the pipe of a hollow, and is light with the metal bar of volume.Its appearance is simple, can save the trouble on many apparatus structures when it and Other Instruments logotype.It is again the pipe of sealing, need not add working solution, and it does not have movable members, can not worn and not torn, this make heat pipe can be durable reliable and noiselessness.On principle, the evaporation of inside heat pipe and condensation make it have the heat-conductive characteristic of high efficiency and nearly isothermal.In addition, the application of the capillarity not mat external force effect and under the weightlessness of space state, moving in endless cycles of fluid that makes inside heat pipe.These advantages almost can make heat pipe replace all heat conducting devices.Wherein its nearly isothermal thermal conductivity and the adaptive faculty under state of weightlessness are especially paid attention to by space engineering circle, for example in autumn nineteen sixty-five, used heat pipe as heat transfer unit (HTU) on 30 No. six geodetic satellites of explorer of American Space General Administration's radiation, the effect of heat pipe keeps constant in two months satellite transit, and this proof heat pipe application on space is successful fully.

Because the advantage of heat pipe is so many, its range of application is very extensive; It can be used for also can be used in the liquid reactant metal stove up to 1,500 degree Celsius in the cryogenic equipment of subzero 230 degree Celsius.It not only is used for the general device on ground, also is used among the space.Except heat pipe as in the previous paragraph can be used as the heat transfer unit (HTU), its application scenarios branch is outlined in down:

(1) power conversion: when the thermion that contains kinetic energy struck an end of heat pipe, thermionic kinetic energy had become heat energy and has reached the other end of heat pipe, and this is called thermionic converter.In addition, among heat pipe on the space can place the isotope thermoelectric generator, make atomic energy be transformed into heat energy, become electric energy again, to supply with the usefulness of artificial satellite and big clean ship.

(2) thermal switch: when adopting extraordinary capillary object and working solution, the sphere of action of heat pipe can be in control.For example heat pipe can't act on when temperature is lower than the freezing point of working solution or heat conduction amount above the heat conduction limit of heat pipe.In other words, when extraneous variations in temperature was very big, heat pipe only acted within certain temperature range, and heat pipe stops its effect outside this scope.This situation is general just like automatic switch.This performance of heat pipe is used among control automatically and the cryogenic equipment more.

(3) " thermal diode ": when heat pipe adopted different wicks, it had the different heat conduction limit, and the wicks of thick pine has the lower heat conduction limit usually.As will thick pine and fine and closely woven wicks place two ends of a heat pipe simultaneously, then the heat conduction amount of heat pipe is very big when calorifying an end of fine and closely woven wicks.Otherwise when calorifying an end of thick loose wicks, heat pipe is because of being subjected to the restriction of the heat conduction limit, and its heat conduction amount can be little a lot of than the former.Explain that from another point of view as containing an end of fine and closely woven wicks with first end representative, and the representative of second end contains an end of thick loose wicks.Under the situation that the heat pipe ambient temperature alters a great deal, in high temperature and second end in low temperature the time, heat can reach the second end from the first end effectively as the first end.Otherwise, when the second end in high temperature and first end in low temperature the time, the second end since the restriction of the heat conduction limit can't conduct heat effectively to the first end.Comprehensive, it is easy that heat reaches the second end by the first end, and reach first end difficulty by the second end.This phenomenon is general just like the effect of two-electrode vacuum tube.This of heat pipe kind of function is used among space and the cryogenic equipment more.

(4) temperature control: when the heat pipe ambient temperature alters a great deal, its heat conduction amount also changes thereupon, yet the inside heat pipe variation of temperature is but very little, and the nearly isothermal heat conductivility of imperial hot property of this kind and heat pipe can be used on the adjustment and control of space flight clothes, spaceship and artificial satellite.If when adopting two kinds of different working solutions in a heat pipe, heat pipe will produce two humidity provinces, this situation also is fit to some special temperature control.

(5) heat radiation: heat pipe is extended outside electro-heat equipment, to increase the area of dissipation of electro-heat equipment.Because the heat conduction amount of heat pipe is greater than the metal bar with volume, it can replace the sheet metal of general heat radiating fin and increase its heat dissipation capacity.This of heat pipe kind of function is used for the heat abstractor of electronic instrument and the radiation fin on the artificial satellite etc. more.In addition: heat pipe also can be loaded between engine in the automobile and the car chamber usefulness as heating element and vehicle interior temperature adjusting.From the application of above heat pipe, as can be known, from the heat pipe invention so far, within the short several years, adopted widely.Yet heat pipe is in the potentiality of application facet, and the research of going back the dependency theory aspect could its effect of more effective performance.

The characteristics of hot pipe technique: 1, high-speed thermal conduction effect; 2, in light weight and simple structure; 3, Temperature Distribution is average, can do the action of samming or isothermal; 4, big, the hot transmitting range of hot transmission quantity is long; 5, there is not driving component, not power consumption itself; 6, can under the environment in the agravic field of force, use; 7, do not have heat to pass the restriction of direction, evaporation ends and condenser can be exchanged; 8, process easily to change hot transmission direction; 9, durable, life-span length, reliable, keeping easy to store; 10, cheap.

" heat pipe " has bigger heat-transfer capability, and heat pipe has been organized the less boiling of thermal resistance and the two kinds of phase transition process that condense cleverly, the thermal conductivity factor that makes it up to the several times of red copper thermal conductivity factor so that thousands of times." heat pipe " do not need delivery pump and seal lubrication, movement-less part simple in structure and noise.As: a heavy 0.34kg of long 0.6m diameter 13mm " heat pipe " carries the 200W energy under 100 ℃ of operating temperatures, 0.5 ℃ of its temperature drop is 22.7kg and carry with the same long solid copper bar weight of homenergic, and the temperature difference is up to 70 ℃.The cold and hot fluid of " heat exchange of heat pipe " fully separately flows, and can be relatively easy to realize the complete countercurrent flow of cold and hot fluid; Simultaneously cold fluid and hot fluid all flows in that pipe is outer, because the outer coefficient of heat transfer that flows of pipe is far above the coefficient of heat transfer mobile in the pipe, and the both sides heating surface all can adopt extended surface, and the recovery that is used for the lower heat energy of grade is very economical.

" heat pipe " claims " super heat-conductive pipe " or " medium heat conduction pipe " again, is a kind of novel heat-conduction component that developed recently gets up.It has broken traditional is the heat transfer type of medium with water, a large amount of heats can be realized that by minimum sectional area remote transmission fast need not additionaling power, thereby realize purpose efficient, energy-conservation, low consumption.After tested, its heat transfer rate can reach 80～100 cels, is thousands of times of good conductors such as silver, copper, aluminium; Transmission course almost is an isothermal heat transfer, and thermal losses can be ignored substantially; And service life was up to extremely tens thousand of hours up to ten thousand.Its purposes extensively make us sidelong glance especially, industry, agricultural, daily vast market arranged all.

Adopted existing anhydrous super conducting heat transfer medium heat absorption and heat dissipation technology among the present invention:

Anhydrous super conducting heat transfer medium heat absorption and heat dissipation technology are a kind of superconduction heat transfer and high efficient heat exchanging new technology.Nontoxic, tasteless, burn into does not explode, the operation principle of utilizing the circulation of sealing superconducting fluid to conduct heat has overcome vapour lock, corrosion water pipe, transmission and the low Three Difficult Issues of radiating efficiency of traditional heating installation bag.Anhydrous super conducting heat transfer medium heat absorption and heat dissipation technology can be saved energy 50%-70%.Conducted heat about 5 minutes, and can make heating system increase to 100 degree, the thermal efficiency is the one preferred technique of exploitation efficient heat energy conduction up to 95%.

Principal character: the latent heat of vaporization is big, thermal capacitance is high, thermal resistance is little, loss is few, heat transfer is fast, boiling point is low, operating temperature is high, nontoxic, tasteless, no burn into is non-volatile, do not burn, do not explode.

1, its cranking temperature is extremely low: need only can begin to pass temperature by 30 degree.And the transmission temperature of water must surpass or reach 100 degree, and water heats up very slow, transmits slower.The starting of general hot-water heating heats up must just can reach room temperature through 1 to 2 hour.Anhydrous super conducting heat transfer medium heat absorption and heat dissipation technology, its transmission speed is tens times of hot-water heating, per minute can transmit 20 meters.

2,40 degrees below zero can not freeze: do not ice the hidden danger of knot, can normally move.And hot-water heating equipment is in the north of cold, will bursting by freezing water pipe or fin as long as stop heating in a day.

3, need not keep in repair throughout one's life: hot-water heating equipment all will keep in repair maintenance every year, and leaks, emits water, dripping phenomenon in addition, maintenance good again, and the life-span of hot-water heating equipment also has only six to seven years.But anhydrous super conducting heat transfer medium heat absorption and heat dissipation technology after once dressing up, just can need not be keeped in repair all the life so long as not artificial destruction, reach 50 years service life.

4, simple in structure, easy for installation.

5, save the energy: economize on coal 50% than hot-water heating equipment, save oil, vapour more than 40%, can reduce comprehensive usage charges 50%, but the thermal efficiency improve the spreader surface temperature can be reached in 30%, 5 to 8 minute 70 ℃～more than 90 ℃.

6, water saving 100%: superconduction heating is to replace water with superconducting fluid, and every 50m2 only uses in the room 1.5 kilograms of superconducting fluid, and expendable uses all the life, and winter, room temperature can reach more than 20 degree, but free adjustment.

Adopted existing far-infrared tube to adopt the energy-efficient heat transfer technology of superconducting fluid among the present invention:

In general, passage of heat has three kinds of methods: i.e. convection current, conduction and the width of cloth are penetrated: and the mode of borrowing the width of cloth to penetrate, energy can be transmitted and pass a certain space, does not but have too big loss.Radiant energy is energy can be sent to from thermal source (emitter) with electromagnetic type to receive thing (absorber), during with this load mode, should call it and be radiant energy, but not can carry out with the shape of " heat "." heat " is that object has absorbed the result who is produced after the radiant energy, and for jobbie or material, if radiant energy passes it or reflects away from its surface, then this object or material are inoperative fully; Otherwise if it has absorbed radiant energy, then work, change radiant energy the shape energy of heat into, thereby make material improve temperature.Therefore, radiant energy has the characteristic that thing is heated up and need not make intensifications around this object, so and the mode of convection current or conduction different greatly, because of the latter must borrow dielectric object, could be such as solid, liquid or gas etc. with energy conduction to object.

Itself does not heat infrared ray to air, though it can be absorbed by dust contained in the air, aqueous vapor, carbon dioxide, the intensification of air is to fasten to state the result that each material absorption causes on the historical facts or anecdotes matter.

Some radiant heat source of daily the easiest See such as the sun, aflame flame, flint etc.; Infrared wave is harmless fully for human body, and necessarily can not mix with ultraviolet ray or atomic radiation is a pool, because of the latter cuts and can damage human body.So infrared radiation can be a kind of safe and useful energy, the most representative certainly has been exactly the sun.

Far-infrared tube adopts the energy-efficient heat transfer technology of superconducting fluid, it is an environmental protection and energy saving technology with international most advanced level, this technology has broken traditional Yi Shui and oil is the conduction mode of heat transfer carrier, under vacuum state, produce phase transformation, evaporation heat release in the heating zone by superconduction steam, the spreader surface temperature is reached more than 90 degree, the air of heating in the space heat-flash to flowing down to reach the heating effect of the best.

Utilize the far-infrared electric heat-generating pipe to carry out system heat sources configuration, make the characteristics of the strong bi-directional energy-saving of his big, high temperature resistant, the high heat energy power of electric conversion efficiency surplus, the more effective product that makes is energy-efficient.Far infrared superconducting heat transfer technology characteristics are remarkable, because the speed that it conducts heat is fast, can heat up about 5～10 minutes 100 ℃, and the thermal efficiency reaches 95%, save the energy 50%, save cost 40%, are the first-selected products of the energy-efficient product of exploitation.Easy for installation, conduct heat quick, multiple functional, once debug successfully, the main body radiator can need not keep in repair all the life, water under the sealed vacuum state, does not have " run, drip, leak " phenomenon.Subzero 40 ℃ can directly start.Superconducting fluid is nonpoisonous and tasteless, do not burn, do not explode, safe in utilization, health, reliable.

1, adopts the carbon fiber filament body, can arbitrarily the combination of carbon fiber filament body be twined.The making power bracket is big, and glass tube length range of choice is wide, and power error is little.

2, carbon fiber wire winding-type type: be divided into two kinds of inner core and centreless are arranged, can select type according to the use of varying environment.

2-1, have and scatter and disappear about 15-20 of heating-up time second (connecting power supply, just have heat to produce, is the luminous centreless electrothermal tube that is slower than) of inner core, self heat to about 150-180 second cool time; Be usually used in relatively poor or not totally enclosed plant equipment of thermal environment and drying tunnel.

About 5-8 of the heating-up time of 2-2, no inner core second, self heat is scattered and disappeared to cooling and is scattered and disappeared about 30-40 of time second;

Simply in centreless carbon filament winding pipe, result of use is identical for manufacture craft and cost.

3, no moment impact electric current, effective holding circuit prolongs circuit service life.

4, long service life, the burning-point time is more than 6000 hours.

5, photochromic even, heating evenly;

6, electric conversion efficiency height, energy-saving effect is remarkable;

7, heat radiation directive property height can improve the radiation of design directional heat.

8, light source is provided with direction does not have related request, and various directions such as vertical, level all can be installed and used.

9, IR wavelength is 2.3～13.5 microns;

Main feature is 1. energy-saving and cost-reducing: fuel consumption has only about 60～70% of conventional boiler; 2. safe and reliable: negative pressure or minute-pressure operation, the accident of can not blasting; 3. thermal efficiency height: with composite evacuated phase transformation heat pipe heat transfer technology, the heat exchange efficiency that makes the heating installation bag is up to more than 86%; 4. immersion heater: efficient composite heat-conducting medium (superconducting fluid), vapourizing temperature is low, so the speed isothermal heat transfer that whole system can 20m/min; 5. easy to operate: as can not freeze the hidden danger of not freezing more than-20～-45 ℃; The CY speed antifreeze efficient composite heat-conducting medium of heat (superconducting fluid) is to the metal non-corrosiveness, and after the normal operation of system, so long as not artificial destruction, the system maintenance amount is almost nil.

The present invention is not only as a kind of radiator of heating system efficiently, and only need add a heating, and radiator has just become " high-efficiency superconducting electric heater " immediately.Energy-conservation more than 60%, subzero 50 degree do not freeze, and adapt to various environment needs.Quietly silent running, noiselessness.

Adopted the prior art of high-frequency electromagnetic kitchen range among the present invention: the high-frequency electromagnetic kitchen range generally adopts the frequency conversion scheme of " industrial frequency AC-direct current-high-frequency ac ", convert 50HZ simple alternating current electric energy the high-frequency ac electric energy of 20KHZ～50KHZ to, as the required high frequency electric source of load coil.Electromagnetic oven is to adopt the electromagnetic induction principle heating, has reduced the intermediate link that heat transmits.Therefore, the thermal efficiency of electromagnetic stove is more than 80%, even up to 93% (general steam is 15%, the efficient of coal gas heating is 40%, and resistance-type is heated to be 52%).The advantage of this uniqueness of high-frequency electromagnetic kitchen range is well suited for being used to manufacture the heating radiator of substitutional resistance heated type.Under the basic identical condition of environment temperature, cooling water inlet temperature and input electric power, the drain system thermal efficiency is 43.75% than the high water circulation system thermal efficiency of water circulation system, and the drain system thermal efficiency is 87.68%, and relatively hot efficient improves 100%.

The thermal conductivity of high-frequency induction heating liquid is all higher than coal stove, fuel oil, coal gas and heating wire.Be most effective in present all heating energy source.Its energy-saving efficiency also is the highest, adds the high-efficiency heat pipe technology and merges application, and the thermal efficiency can reach 100%.It is the most energy-efficient mode of the China and city household warming transformation from now on.High-frequency induction heating can realize improving the purpose of power load curve, sees the following form:

The thermal conductivity situation of various mode of heatings

Mode of heating	Coal stove	Coal gas	Heating wire	Electromagnetic induction
					The thermal efficiency	??30％	??55％	??55％	??90％～95％

The fouling meeting of heating back reduces heating rate	??15％	??20％	??30％	The frequency electromagnetic waves non flouling behaviour
					Additional heat efficient			Add after the far infrared 63%	Can reach 100% after adding efficient heat pipe

Adopted the LED prior art of solar photocell power supply among the present invention:

Utilize rechargeable solar battery to come to be used for heating to the super heat-conductive pipe efficient converting to hot air in back of heating for light emitting diode (LED) heat production.

Innovative point of the present invention is:

Technology path one: the present invention has selected " super heat-conductive pipe heat transfer element efficiently " its characteristics for use: 1, high-speed thermal conduction effect; 2, in light weight and simple structure; 3, Temperature Distribution is average, can do the action of samming or isothermal; 4, big, the hot transmitting range of hot transmission quantity is long; 5, there is not driving component, not power consumption itself; 6, can under the environment in the agravic field of force, use; 7, do not have heat to pass the restriction of direction, evaporation ends and condenser can be exchanged; 8, process easily to change hot transmission direction; 9, durable, life-span length, reliable, keeping easy to store; 10, cheap; 11, being convenient to penetration and promotion uses.

Technology path two: the present invention has made " multi-functional superconducting heat pipe household heating apparatus " with " super heat-conductive pipe heat transfer element efficiently ", can select various heatings for use, as; Far infrared, Electric radiant Heating Film, electromagnetic induction etc. are made multi-form " family expenses superconducting heat pipe household heating device ", and economize on electricity is more than 60%.

Technology path three: the present invention has made not electricity consumption with " super heat-conductive pipe heat transfer element efficiently ", with " the family expenses superconducting heat pipe household heating device " of hot water heating, is selected to the area of not having electricity especially, economize on electricity 100%.

Technology path four: the present invention uses " super heat-conductive pipe heat transfer element efficiently " to make " the family expenses superconducting heat pipe household heating device " of " solar energy-photocell-LED " of regenerative resource, economize on electricity 100%.

Beneficial effect of the present invention:

The present invention one is can not electricity consumption; The 2nd, electricity consumption can save energy more than 60%; The 3rd, can utilize the solar energy regenerative resource.Has society and economy benefit energy-conservation, that reduce discharging.Be the inexorable trend that develops at present and in the future, it is significant.

Description of drawings

Fig. 1: the gravity super heat-conductive pipe profile schematic diagram of band radiator (is called for short: the AB pipe);

Fig. 2～Fig. 3: " a kind of multi-functional superconducting heat pipe household heating apparatus " of the present invention schematic diagram (is called for short: the ABC device);

Fig. 4: " Y shape infrared coating heat sink " of the present invention (is called for short: the ABCD device) with " blower fan heat diffuser " schematic diagram;

Fig. 5: " thermal current diffusion shell " of the present invention and " super liquid thermal current diffusion shell " schematic diagram (being called for short: ABCDEH device and ABCDF device);

Fig. 6: " hot-water heating-thermal current diffusion shell " of the present invention schematic diagram (is called for short: the ABCDEH device);

Fig. 7: " hot-water heating-super liquid thermal current diffusion shell " of the present invention schematic diagram (is called for short: the ABCDFH device);

Fig. 8: " hot-water heating-super liquid-hot-air " of the present invention heating device schematic diagram (is called for short: the ABCDEHJ system and device);

Fig. 9: " hot-water heating-two super liquid " of the present invention heating device schematic diagram (is called for short: the ABCDFHJ system and device);

Figure 10: " quartzy infrared tube-blower fan-air " of the present invention heating device schematic diagram (is called for short: the ABCDL2-2/01 system and device);

Figure 11: " quartzy infrared tube-two air " of the present invention heating device schematic diagram (is called for short: the ABCDEL-2/01 system and device);

Figure 12: " quartzy infrared tube-two super liquid " of the present invention heating device schematic diagram (is called for short: the ABCDFL-2/03 system and device);

Figure 13: " carbon fiber infrared tube-two super liquid " of the present invention heating device schematic diagram (is called for short: the ABCDFM-2/03 system and device);

Figure 14: " infrared lamp-two super liquid " of the present invention heating device schematic diagram (is called for short: the ABCDFN-2/03 system and device);

Figure 15: " Electric radiant Heating Film cover-two super liquid " of the present invention heating device schematic diagram (is called for short: the ABCDFP-2/03 system and device);

Figure 16: " the electromagnetic induction warmer-super liquid of list " of the present invention heating device schematic diagram (is called for short: the ABCDFQ-03 system and device);

Figure 17: " photocell-light emitting diode " of the present invention heating device schematic diagram (is called for short: the ABCDFSRT-2/03 system and device).

Figure 18: heat pipe structure principal diagram.

Among the figure: a evaporator section, b span line, c condensation segment, d heat insulation, e imbibition core, the f vapor space, g shell, h end cap, j gravity direction/liquid pass direction; (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (A) gravity super heat-conductive pipe, (A-1) condensation segment, (A-2) connect that outer bolt, (A-3) evaporator section, (B) gravity super heat-conductive pipe are heat radiator dedicated, the gravity super heat-conductive pipe of (AB) band radiator; (C) the evaporation casing comprises by (C1) duplex seat, (C2) evaporation tank and forming: (C1) the duplex seat comprises and goes up clamping ring, (C1-2) by (C1-1) top cover face, (C1-0) clamping ring, (C1-3) connect inner nut, (C1-4) superconducting fluid cup and connect rim of a cup, (C1-5) water inlet connection mouth of pipe, (C1-6) two-purpose frame, (C1-6-0) and connect base down; (C2) evaporation tank comprise go up interface, (C2-3) U molding box by (C2-1) U molding box, (C2-2) at the bottom of, (C2-4) adiabator layer, (C2-5) infrared coating layer, (C2-6) draining mouth of pipe, (C2-7) universal wheel; (D) Y shape infrared coating heat sink comprises that (D1) natural heat dissipation plate comprises (D1-1) erect plate, (D1-2) V-shaped groove, (D1-3) bedplate, (D1-4) connecting hole, (D1-5) U type reflector; (D2) the blower fan heat diffuser comprises the air-flow that (D2-1) bedplate, (D2-2) riser, (D2-3) V-shaped groove louvre, (D2-4) exhaust blower, (D2-5) exhaust duct, (D2-6) wind exhausting outlet, (D2-7) discharge; (E) the thermal current diffusion shell comprises (E1-0) outer cover, (E1-1) top cover, (E1-2) diffusion hole, (E1-3) base clamping ring, (E1-4) connecting hole; (F) superconducting fluid thermal current diffusion shell comprises (F1-0) outer cover, (F1-1) top mouth, (F1-2) fin lower end, (F1-3) top cover, (F1-4) liquid feeding mouth, (F1-5) lower end, (F1-6) lower end clamping ring, (F1-7) connecting hole; (G) O-ring seal, (G0) connecting hole; (H) hot-water heating system comprises (H0) hyponome lid, (H1) pour water funnel, (H2) filler tube, (H3) water out, (H4) two water pipes, (H5) water pipe folder; (K) switch comprises (K1) temperature controller, (K2) Temperature probe, (K3) power line, (K4) battery case; (J) superconducting fluid cup; (L) quartzy infrared tube comprises the quartzy infrared tube of (L1) 250W, (L1-1) power line, the quartzy infrared tube of (L2) 100W, (L2-1) power line; (M) the carbon fiber infrared tube comprises (M1) 250W carbon fiber infrared tube, (M2) 100W carbon fiber infrared tube; (N) 250W infrared lamp; (P) 5～10 on 25W Electric radiant Heating Film cover, (P1) Electric radiant Heating Film connect electric wire; (Q) the electromagnetic induction warmer comprises (Q1) electromagnetic eddy heater, (Q1-1) metal square frame, (Q1-2) solenoid, (Q1-3) eddy current high temperature pipe, (Q2) electromagnetic circuit; (R) light emitting diode, (R0) LED heat radiating sheet; (S) photo-cell assembly comprises that (S-0) photovoltaic cell module, (S-1) connection electric wire, (S-2) battery, (S-3) photocell power supply interface, (S-4) two-way switch, (S-5) commercial power interface, (T) direct current transducer, (T1) connect civil power.

The specific embodiment

Embodiment one: in Fig. 1: (A) gravity super heat-conductive pipe, (A-1) condensation segment, (A-2) connect that outer bolt, (A-3) evaporator section, (B) gravity super heat-conductive pipe are heat radiator dedicated, the gravity super heat-conductive pipe of (AB) band radiator (hereinafter to be referred as: the AB pipe).

In the drawings: (A) the gravity super heat-conductive pipe comprises that (A-1) condensation segment by the upper end is connected outer bolt and lower end with (A-2) of middle-end (A-3) evaporator section forms; Outside (A-1) of upper end condensation segment, be inserted in the heat radiator dedicated gravity super heat-conductive pipe that constitutes (AB) band radiator of connection (B) gravity super heat-conductive pipe.

Embodiment two: in Fig. 2～Fig. 3: (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (C) evaporation casing, (C1) duplex seat, (C2) evaporation tank, (C1) duplex seat, (C1-1) top cover face, (C1-0) go up clamping ring, (C1-2) clamping ring under, (C1-3) connect inner nut, (C1-4) the superconducting fluid cup connects rim of a cup, (C1-5) water inlet connects the mouth of pipe, (C1-6) two-purpose frame, (C1-6-0) connect base, (C2) evaporation tank, (C2-1) U molding box, (C2-2) go up interface, (C2-3) at the bottom of the U molding box, (C2-4) adiabator layer, (C2-5) infrared coating layer, (C2-6) the draining mouth of pipe, (C2-7) universal wheel.

In the drawings: (C) the evaporation casing comprises by (C1) duplex seat, (C2) evaporation tank and forming: (C1) the duplex seat comprises and (C1-0) that connected by (C1-1) top cover face goes up clamping ring, (C1-2) clamping ring, (C1-3) connect inner nut, (C1-4) superconducting fluid cup and connect rim of a cup, (C1-5) water inlet and connect the mouth of pipe, (C1-6) two-purpose frame, (C1-6-0) connection base and form down; In (C1-3) of (C1) duplex seat connection inner nut, insert (A-3) evaporator section of the gravity super heat-conductive pipe that connects (AB) band radiator and be connected outer bolt and be connected with (A-2), (A-1) condensation segment is on (C1) duplex seat (C1-1) top cover face, and (A-3) evaporator section is below (C1-1) top cover face; (C2) evaporation tank comprise by (C2-2) of (C2-1) U molding box go up interface and (C2-4) adiabator layer that is being connected in turn with (C2-1) U molding box internal layer at the bottom of (C2-3) U molding box and (C2-6) draining mouth of pipe of (C2-5) rustproof lacquer layer and bottom and (C2-1) (C2-7) universal wheel of the outer bottom of U molding box constituted (C) of the present invention evaporation tank body device.

Embodiment three: in Fig. 4: (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (D) Y shape infrared coating heat sink, (D1) natural heat dissipation plate comprise (D1-1) erect plate, (D1-2) V-shaped groove, (D1-3) bedplate, (D1-4) connecting hole, (D1-5) U type reflector; (D2) air-flow of blower fan heat diffuser (D2-1) bedplate, (D2-2) riser, (D2-3) V-shaped groove louvre, (D2-4) exhaust blower, (D2-5) exhaust duct, (D2-6) wind exhausting outlet, (D2-7) discharge.

In the drawings: (D) Y shape infrared coating heat sink comprises that (D1-3) bedplate that (D1-2) V-shaped groove that (D1-1) erect plate of being connected by (D1) natural heat dissipation plate is connected with the top is connected with the bottom reaches (D1-5) U type reflector formation that is connected with (D1-4) connecting hole on (D1-1) erect plate;

(D2) the blower fan heat diffuser comprises (D2-3) V-shaped groove louvre and upper end (D2-4) exhaust blower that connects and (D2-5) exhaust duct that is connected and (D2-6) wind exhausting outlet and (D2-7) the air-flow formation of discharge that (D2-2) riser of being connected by (D2-1) bedplate upper end is connected with the upper end.

Embodiment four: in Fig. 5: (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (E) thermal current diffusion shell, (E1-0) outer cover, (E1-1) top cover, (E1-2) diffusion hole, (E1-3) base clamping ring, (E1-4) connecting hole; (F) superconducting fluid thermal current diffusion shell, (F1-0) outer cover, (F1-1) top mouth, (F1-2) fin lower end, (F1-3) top cover, (F1-4) liquid feeding mouth, (F1-5) lower end, (F1-6) lower end clamping ring, (F1-7) connecting hole; (G) O-ring seal, (G0) connecting hole.

In Fig. 5: (E) the thermal current diffusion shell comprise around (E1-1) top cover of connecting by (E1-0) outer cover upper end and (E1-0) outer cover (E1-2) diffusion hole and (E1-0) the outer cover lower end (E1-3) base clamping ring and (E1-4) connecting hole (G0) connecting hole on (G) O-ring seal (C1-0) of inserting (C1) duplex seat upper end go up clamping ring and connect and compose;

(F) superconducting fluid thermal current diffusion shell comprise (F1-3) top cover of being connected by (F1-0) outer cover and (F1-1) top mouth and (F1-4) (F1-5) lower end of being connected with (F1-2) fin lower end of liquid feeding mouth and (F1-6) lower end clamping ring and (F1-7) (C1-0) of connecting hole on the insertion of (G0) connecting hole on (G) O-ring seal (C1) duplex seat upward clamping ring connect and compose.

Embodiment five: in Fig. 6: (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (E) thermal current diffusion shell, (E1-0) outer cover, (E1-1) top cover, (E1-2) diffusion hole, (E1-3) base clamping ring, (E1-4) connecting hole; (C2) at the bottom of evaporation tank, (C2-1) U molding box, (C2-3) U molding box, (C2-6) draining mouth of pipe; (H) hot-water heating system comprises (H0) hyponome lid, (H1) pour water funnel, (H2) filler tube, (H3) water out, (H4) two water pipes, (H5) water pipe folder; (K) switch comprises (K1) temperature controller, (K2) Temperature probe, (K3) power line, (K4) battery case.

In the drawings: (E) thermal current diffusion shell insertion connection (C1) duplex seat is connected with (C2) evaporation tank again; (H) hot-water heating system comprises that (E1-1) top cover of pouring water (H1) that connected in turn by (H0) hyponome lid funnel inserting (E) thermal current diffusion shell upper end is connected mouth of pipe insertion connection through (H2) filler tube, (H3) water out with (C1-5) water inlet above (C1) duplex seat; (H4) two water pipes, (H5) water pipe folder with (C2-3) U molding box bottom constitutes drainage system again; Outside (C2-1) U molding box, then connect (K) switch and comprising (K1) low temperature alarm and (K2) Temperature probe that is connected and (K3) power line and (K4) battery case formation.

Embodiment six: in Fig. 7: (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (F) superconducting fluid thermal current diffusion shell, (F1-0) outer cover, (F1-1) top mouth, (F1-2) fin lower end, (F1-3) top cover, (F1-4) liquid feeding mouth, (F1-5) lower end, (F1-6) lower end clamping ring, (F1-7) connecting hole; (G) O-ring seal, (G0) connecting hole; (H) hot-water heating system comprises (H0) hyponome lid, (H1) pour water funnel, (H2) filler tube, (H3) water out, (H4) two water pipes, (H5) water pipe folder; (K) switch comprises (K1) temperature controller, (K2) Temperature probe, (K3) power line, (K4) battery case.

In the drawings: (F) superconducting fluid thermal current diffusion shell insertion connection (C1) duplex seat is connected with (C2) evaporation tank again; (H) hot-water heating system comprises that (F1-3) top cover of pouring water (H1) that connected in turn by (H0) hyponome lid funnel inserting (F) superconducting fluid thermal current diffusion shell upper end is connected mouth of pipe insertion connection through (H2) filler tube, (H3) water out with (C1-5) water inlet above (C1) duplex seat; (H4) two water pipes, (H5) water pipe folder with (C2-3) U molding box bottom constitutes drainage system again; Outside (C2-1) U molding box, then connect (K) switch and comprising (K1) low temperature alarm and (K2) Temperature probe that is connected and (K3) power line and (K4) battery case formation.

Embodiment seven: in Fig. 8: (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (E) thermal current diffusion shell, (E1-0) outer cover, (E1-1) top cover, (E1-2) diffusion hole, (E1-3) base clamping ring, (E1-4) connecting hole; (C2) at the bottom of evaporation tank, (C2-1) U molding box, (C2-3) U molding box, (C2-6) draining mouth of pipe; (H) hot-water heating system comprises (H0) hyponome lid, (H1) pour water funnel, (H2) filler tube, (H3) water out, (H4) two water pipes, (H5) water pipe folder; (K) switch comprises that (K1) temperature controller, (K2) Temperature probe, (K3) power line, (K4) battery case, (J) superconducting fluid cup, (C1) duplex seat, (C1-4) superconducting fluid cup connect rim of a cup.

In the drawings: (E) (J) superconducting fluid cup of (C1-4) superconducting fluid cup connection rim of a cup connection in thermal current diffusion shell insertion (C1) duplex seat is connected with (C2) evaporation tank again; (H) hot-water heating system comprises that (E1-1) top cover of pouring water (H1) that connected in turn by (H0) hyponome lid funnel inserting (E) thermal current diffusion shell upper end is connected mouth of pipe insertion connection through (H2) filler tube, (H3) water out with (C1-5) water inlet above (C1) duplex seat; (H4) two water pipes, (H5) water pipe folder with (C2-3) U molding box bottom constitutes drainage system again; Outside (C2-1) U molding box, then connect (K) switch and comprising (K1) low temperature alarm and (K2) Temperature probe that is connected and (K3) power line and (K4) battery case formation.

Embodiment eight: in Fig. 9: (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (F) superconducting fluid thermal current diffusion shell, (F1-0) outer cover, (F1-1) top mouth, (F1-2) fin lower end, (F1-3) top cover, (F1-4) liquid feeding mouth, (F1-5) lower end, (F1-6) lower end clamping ring, (F1-7) connecting hole; (G) O-ring seal, (G0) connecting hole; (H) hot-water heating system comprises (H0) hyponome lid, (H1) pour water funnel, (H2) filler tube, (H3) water out, (H4) two water pipes, (H5) water pipe folder; (K) switch comprises that (K1) temperature controller, (K2) Temperature probe, (K3) power line, (K4) battery case, (J) superconducting fluid cup, (C1) duplex seat, (C1-4) superconducting fluid cup connect rim of a cup.

In the drawings: (F) (J) superconducting fluid cup of (C1-4) superconducting fluid cup connection rim of a cup connection in superconducting fluid thermal current diffusion shell insertion connection (C1) duplex seat is connected with (C2) evaporation tank again; (H) hot-water heating system comprises that (F1-3) top cover of pouring water (H1) that connected in turn by (H0) hyponome lid funnel inserting (F) superconducting fluid thermal current diffusion shell upper end is connected mouth of pipe insertion connection through (H2) filler tube, (H3) water out with (C1-5) water inlet above (C1) duplex seat; (H4) two water pipes, (H5) water pipe folder with (C2-3) U molding box bottom constitutes drainage system again; Connect (K) switch in (C2-1) U molding box outside and comprising (K1) low temperature alarm and (K2) Temperature probe that is connected and (K3) power line and (K4) battery case formation.

Embodiment nine: in Figure 10: (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (E) thermal current diffusion shell, (D2) blower fan heat diffuser, (C) evaporation casing, (C2-3) U molding box bottom, (K) switch, (K1) temperature controller, (K2) Temperature probe, (K3) power line, (L) quartzy infrared tube comprise the quartzy infrared tube of (L1) 250W, (L1-1) power line, the quartzy infrared tube of (L2) 100W, (L2-1) power line.

In the drawings: the upper end at (C) evaporation casing is connecting (E) thermal current diffusion shell that has (D2) blower fan heat diffuser; Connecting the quartzy infrared tube of (L1) 250W and (L2) the quartzy infrared tube of 100W and (L1-1) (L2-1) power line above in (C2-3) U molding box bottom of (C) evaporation casing lower end; Connecting (K2) Temperature probe that (K1) temperature controller connects and (K3) power line in (C2-3) U molding box outside.

Embodiment ten: in Figure 11: (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (E) thermal current diffusion shell, (D) Y shape infrared coating heat sink, (C) evaporation casing, (C2-3) U molding box bottom, (K) switch, (K1) temperature controller, (K2) Temperature probe, (K3) power line, (L) quartzy infrared tube comprise the quartzy infrared tube of (L1) 250W, (L1-1) power line, the quartzy infrared tube of (L2) 100W, (L2-1) power line.

In the drawings: on (C) evaporation casing, connecting (E) thermal current diffusion shell that has (D) Y shape infrared coating heat sink; Connecting the quartzy infrared tube of (L1) 250W and (L2) the quartzy infrared tube of 100W and (L1-1) (L2-1) power line above in (C2-3) U molding box bottom of (C) evaporation casing lower end; Connecting (K2) Temperature probe that (K1) temperature controller connects and (K3) power line in (C2-3) U molding box outside.

Embodiment 11: in Figure 12: (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (C) evaporation casing, (D) Y shape infrared coating heat sink, (F) superconducting fluid thermal current diffusion shell; (C1) at the bottom of duplex seat (C1-4) superconducting fluid cup connects rim of a cup, (J) superconducting fluid cup, (C2-3) U molding box, (L2-1) power line of the quartzy infrared tube of (L1) 250W, the quartzy infrared tube of (L2) 100W, (L1-1); (K1) temperature controller, (K2) Temperature probe, (K3) power line.

In the drawings: on (C) evaporation casing, connecting (F) superconducting fluid thermal current diffusion shell that has (D) Y shape infrared coating heat sink; (J) superconducting fluid cup that is connected with (C1-4) superconducting fluid cup connection rim of a cup connection in (C1) duplex seat on (C) evaporation casing is connected with (C2) evaporation tank again; (AB) upper end (A-1) condensation segment of the gravity super heat-conductive pipe of band radiator is placed in (F) superconducting fluid thermal current diffusion shell; (AB) lower end (A-3) evaporator section of the gravity super heat-conductive pipe of band radiator inserts the upper end that is connected in (J) superconducting fluid cup in (C) evaporation casing; Connecting the quartzy infrared tube of (L1) 250W and (L2) the quartzy infrared tube of 100W and (L1-1) (L2-1) power line above in (C2-3) U molding box bottom of (C) evaporation casing lower end; Connecting (K2) Temperature probe that (K1) temperature controller connects and (K3) power line in (C2-3) U molding box outside.

Embodiment 12: in Figure 13: (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (C) evaporation casing, (D) Y shape infrared coating heat sink, (F) superconducting fluid thermal current diffusion shell, (F1-3) top cover, (F1-4) liquid feeding mouth; (C1) at the bottom of duplex seat (C1-4) superconducting fluid cup connects rim of a cup, (J) superconducting fluid cup, (C2-3) U molding box, (M) carbon fiber infrared tube comprises (M1) 250W carbon fiber infrared tube, (M2) 100W carbon fiber infrared tube; (K1) temperature controller, (K2) Temperature probe, (K3) power line.

In the drawings: on (C) evaporation casing, connecting and having (F1-3) connects (F1-4) liquid feeding mouth above the top cover (F) superconducting fluid thermal current diffusion shell; (J) superconducting fluid cup that is connected with (C1-4) superconducting fluid cup connection rim of a cup connection in (C1) duplex seat on (C) evaporation casing is connected with (C2) evaporation tank again; (AB) (A-1) condensation segment of the upper end of the gravity super heat-conductive pipe of band radiator is placed in (F) superconducting fluid thermal current diffusion shell; (AB) lower end (A-3) evaporator section of the gravity super heat-conductive pipe of band radiator inserts the upper end that is connected in (J) superconducting fluid cup in (C) evaporation casing; Connect (M) carbon fiber infrared tube above in (C2-3) U molding box bottom of (C) evaporation casing lower end and comprising (M1) 250W carbon fiber infrared tube, (M2) 100W carbon fiber infrared tube; Connecting (K2) Temperature probe that (K1) temperature controller connects and (K3) power line in (C2-3) U molding box outside.

Embodiment 13: in Figure 14: (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (C) evaporation casing, (D) Y shape infrared coating heat sink, (F) superconducting fluid thermal current diffusion shell, (F1-3) top cover, (F1-4) liquid feeding mouth; (C1) at the bottom of duplex seat (C1-4) superconducting fluid cup connects rim of a cup, (J) superconducting fluid cup, (C2-3) U molding box, (N) 250W infrared lamp; (K1) temperature controller, (K2) Temperature probe, (K3) power line.

In the drawings: on (C) evaporation casing, connecting and having (F1-3) connects (F1-4) liquid feeding mouth above the top cover (F) superconducting fluid thermal current diffusion shell; (J) superconducting fluid cup that is connected with (C1-4) superconducting fluid cup connection rim of a cup connection in (C1) duplex seat on (C) evaporation casing is connected with (C2) evaporation tank again; (AB) (A-1) condensation segment of the upper end of the gravity super heat-conductive pipe of band radiator is placed in (F) superconducting fluid thermal current diffusion shell; (AB) lower end (A-3) evaporator section of the gravity super heat-conductive pipe of band radiator inserts the upper end that is connected in (J) superconducting fluid cup in (C) evaporation casing; Connecting lamp outside (N) 250W above in (C2-3) U molding box bottom of (C) evaporation casing lower end; Connecting (K2) Temperature probe that (K1) temperature controller connects and (K3) power line in (C2-3) U molding box outside.

Embodiment 14: in Figure 15: in Figure 14: (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (C) evaporation casing, (D) Y shape infrared coating heat sink, (F) superconducting fluid thermal current diffusion shell, (F1-3) top cover, (F1-4) liquid feeding mouth; (C1) at the bottom of duplex seat (C1-4) superconducting fluid cup connects rim of a cup, (J) superconducting fluid cup, (C2-3) U molding box, 5～10 on (P) 25W Electric radiant Heating Film cover, (P1) Electric radiant Heating Film connect electric wire; (K1) temperature controller, (K2) Temperature probe, (K3) power line.

In the drawings: on (C) evaporation casing, connecting and having (F1-3) connects (F1-4) liquid feeding mouth above the top cover (F) superconducting fluid thermal current diffusion shell; (J) superconducting fluid cup that is connected with (C1-4) superconducting fluid cup connection rim of a cup connection in (C1) duplex seat on (C) evaporation casing is connected with (C2) evaporation tank again; (AB) (A-1) condensation segment of the upper end of the gravity super heat-conductive pipe of band radiator is placed in (F) superconducting fluid thermal current diffusion shell; (AB) lower end (A-3) evaporator section of the gravity super heat-conductive pipe of band radiator inserts the upper end that is connected in (J) superconducting fluid cup in (C) evaporation casing; Connecting 5～10 on (P) 25W Electric radiant Heating Film cover of connecting by (P1) Electric radiant Heating Film connection electric wire above in (C2-3) U molding box bottom of (C) evaporation casing lower end; Connecting (K2) Temperature probe that (K1) temperature controller connects and (K3) power line in (C2-3) U molding box outside.

Embodiment 15: in Figure 16: in Figure 14: (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (C) evaporation casing, (D) Y shape infrared coating heat sink, (F) superconducting fluid thermal current diffusion shell, (F1-3) top cover, (F1-4) liquid feeding mouth; (C1) at the bottom of duplex seat (C1-4) superconducting fluid cup connects rim of a cup, (J) superconducting fluid cup, (C2-3) U molding box, (Q) electromagnetic induction warmer comprises (Q1) electromagnetic eddy heater, (Q1-1) metal square frame, (Q1-2) solenoid, (Q1-3) eddy current high temperature pipe, (Q2) electromagnetic circuit; (K1) temperature controller, (K2) Temperature probe, (K3) power line.

In the drawings: on (C) evaporation casing, connecting and having (F1-3) connects (F1-4) liquid feeding mouth above the top cover (F) superconducting fluid thermal current diffusion shell; (J) superconducting fluid cup that is connected with (C1-4) superconducting fluid cup connection rim of a cup connection in (C1) duplex seat on (C) evaporation casing is connected with (C2) evaporation tank again; (AB) (A-1) condensation segment of the upper end of the gravity super heat-conductive pipe of band radiator is placed in (F) superconducting fluid thermal current diffusion shell; (AB) lower end (A-3) evaporator section of the gravity super heat-conductive pipe of band radiator inserts the upper end that is connected in (J) superconducting fluid cup in (C) evaporation casing; Connecting above in (C2-3) U molding box bottom of (C) evaporation casing lower end and comprising (Q1) electromagnetic eddy heater that connects by (Q2) electromagnetic circuit; (Q1) the electromagnetic eddy heater is included in (Q1-1) metal square frame and is connecting (Q1-2) solenoid; Connecting (Q) electromagnetic induction warmer that (Q1-3) eddy current high temperature pipe is formed in (Q1-1) metal square frame outer ring; Connecting (K2) Temperature probe that (K1) temperature controller connects and (K3) power line in (C2-3) U molding box outside.

Embodiment 16: in Figure 17: in Figure 14: (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (C) evaporation casing, (D) Y shape infrared coating heat sink, (F) superconducting fluid thermal current diffusion shell, (F1-3) top cover, (F1-4) liquid feeding mouth; (C1) at the bottom of duplex seat (C1-4) superconducting fluid cup connects rim of a cup, (J) superconducting fluid cup, (C2-3) U molding box, (R) light emitting diode, (R0) LED heat radiating sheet; (S) photo-cell assembly comprises that (S-0) photovoltaic cell module, (S-1) connection electric wire, (S-2) battery, (S-3) photocell power supply interface, (S-4) two-way switch, (S-5) commercial power interface, (T) direct current transducer, (T1) connect civil power; (K1) temperature controller, (K2) Temperature probe, (K3) power line.

In the drawings: on (C) evaporation casing, connecting and having (F1-3) connects (F1-4) liquid feeding mouth above the top cover (F) superconducting fluid thermal current diffusion shell; (J) superconducting fluid cup that is connected with (C1-4) superconducting fluid cup connection rim of a cup connection in (C1) duplex seat on (C) evaporation casing is connected with (C2) evaporation tank again; (AB) (A-1) condensation segment of the upper end of the gravity super heat-conductive pipe of band radiator is placed in (F) superconducting fluid thermal current diffusion shell; (AB) lower end (A-3) evaporator section of the gravity super heat-conductive pipe of band radiator inserts the upper end that is connected in (J) superconducting fluid cup in (C) evaporation casing; Connecting (R) light emitting diode that (R0) LED heat radiating sheet connects above (J) superconducting fluid cup outer ring in (C2-3) U molding box bottom of (C) evaporation casing lower end; (R) light emitting diode is connecting (S) photo-cell assembly and is comprising that (S-1) connection electric wire, (S-2) battery, (S-3) photocell power supply interface, (S-4) two-way switch, (S-5) commercial power interface, (T) direct current transducer of being connected in turn by (S-0) photovoltaic cell module are connected the commercial power interface device with (T1); Connecting (K2) Temperature probe that (K1) temperature controller connects and (K3) power line in (C2-3) U molding box outside.

In Figure 18: a evaporator section, b span line, c condensation segment, d heat insulation, e imbibition core, the f vapor space, g shell, h end cap, j gravity direction/liquid pass direction; (0) water, (01) air, (02 hot-air), (03) superconducting fluid; (A) gravity super heat-conductive pipe, (A-1) condensation segment, (A-2) connect outer bolt, (A-3) evaporator section, (B) gravity super heat-conductive pipe heat radiator dedicated,

Claims (10)

1, the multifunctional domestic superconducting heat tube heating device of a kind of not electricity consumption and LED comprises that gravity super heat-conductive pipe, (C) evaporation casing by (AB) band radiator comprises by (C1) duplex seat, (C2) evaporation tank to form: (C1) the duplex seat comprises and goes up clamping ring, (C1-2) by (C1-1) top cover face, (C1-0) clamping ring, (C1-3) connect inner nut, (C1-4) superconducting fluid cup and connect rim of a cup, (C1-5) water inlet connection mouth of pipe, (C1-6) two-purpose frame, (C1-6-0) and connect base down; (C2) evaporation tank comprise go up interface, (C2-3) U molding box by (C2-1) U molding box, (C2-2) at the bottom of, (C2-4) adiabator layer, (C2-5) infrared coating layer, (C2-6) draining mouth of pipe, (C2-7) universal wheel; (D) Y shape infrared coating heat sink comprises that (D1) natural heat dissipation plate comprises (D1-1) erect plate, (D1-2) V-shaped groove, (D1-3) bedplate, (D1-4) connecting hole, (D1-5) U type reflector; (D2) the blower fan heat diffuser comprises the air-flow that (D2-1) bedplate, (D2-2) riser, (D2-3) V-shaped groove louvre, (D2-4) exhaust blower, (D2-5) exhaust duct, (D2-6) wind exhausting outlet, (D2-7) discharge; (E) the thermal current diffusion shell comprises (E1-0) outer cover, (E1-1) top cover, (E1-2) diffusion hole, (E1-3) base clamping ring, (E1-4) connecting hole; (F) superconducting fluid thermal current diffusion shell comprises (F1-0) outer cover, (F1-1) top mouth, (F1-2) fin lower end, (F1-3) top cover, (F1-4) liquid feeding mouth, (F1-5) lower end, (F1-6) lower end clamping ring, (F1-7) connecting hole; (G) O-ring seal, (G0) connecting hole; (H) hot-water heating system comprises (H0) hyponome lid, (H1) pour water funnel, (H2) filler tube, (H3) water out, (H4) two water pipes, (H5) water pipe folder; (K) switch comprises (K1) temperature controller, (K2) Temperature probe, (K3) power line, (K4) battery case; (J) superconducting fluid cup; (L) quartzy infrared tube comprises the quartzy infrared tube of (L1) 250W, (L1-1) power line, the quartzy infrared tube of (L2) 100W, (L2-1) power line; (M) the carbon fiber infrared tube comprises (M1) 250W carbon fiber infrared tube, (M2) 100W carbon fiber infrared tube; (N) 250W infrared lamp; (P) 5～10 on 25W Electric radiant Heating Film cover, (P1) Electric radiant Heating Film connect electric wire; (Q) the electromagnetic induction warmer comprises (Q1) electromagnetic eddy heater, (Q1-1) metal square frame, (Q1-2) solenoid, (Q1-3) eddy current high temperature pipe, (Q2) electromagnetic circuit; (R) light emitting diode, (R0) LED heat radiating sheet; (S) photo-cell assembly comprises that (S-0) photovoltaic cell module, (S-1) connect electric wire, (S-2) battery, (S-3) photocell power supply interface, (S-4) two-way switch, (S-5) commercial power interface, (T) direct current transducer, (T1) connection civil power formation, is characterized in that; (C) the evaporation casing comprises by (C1) duplex seat, (C2) evaporation tank and forming: (C1) the duplex seat comprises and (C1-0) that connected by (C1-1) top cover face goes up clamping ring, (C1-2) clamping ring, (C1-3) connect inner nut, (C1-4) superconducting fluid cup and connect rim of a cup, (C1-5) water inlet and connect the mouth of pipe, (C1-6) two-purpose frame, (C1-6-0) connection base and form down; In (C1-3) of (C1) duplex seat connection inner nut, insert (A-3) evaporator section of the gravity super heat-conductive pipe that connects (AB) band radiator and be connected outer bolt and be connected with (A-2), (A-1) condensation segment is on (C1) duplex seat (C1-1) top cover face, and (A-3) evaporator section is below (C1-1) top cover face; (C2) evaporation tank comprises that going up outside interface and (C2-4) adiabator layer that is being connected in turn with (C2-1) U molding box internal layer at the bottom of (C2-3) U molding box and (C2-6) draining mouth of pipe of (C2-5) infrared coating layer and bottom and (C2-1) the U molding box (C2-7) universal wheel of bottom by (C2-2) of (C2-1) U molding box has constituted (C) of the present invention and evaporate casing; (C) (D)Y (D1) (D1-1) (D1-2)V (D1-3) (D1-4) (D1-1) (D1-5)U (D2) (D2-1) (D2-2) (D2-3)V (D2-4) (D2-5) (D2-6) (D2-7)； (D)Y (E) (E1-0) (E1-1) (E1-0) (E1-2) (E1-0) (E1-3) (E1-4) (G) (G0) (C1) (C1-0) (F) (F1-0) (F1-1) (F1-3) (F1-4) (F1-2) (F1-5) (F1-6) (F17) (G) (G0) (C1) (C1-0)； (E) thermal current diffusion shell insertion connection (C1) duplex seat is connected with (C2) evaporation tank again; (H) hot-water heating system comprises that (E1-1) top cover of pouring water (H1) that connected in turn by (H0) hyponome lid funnel inserting (E) thermal current diffusion shell upper end is connected mouth of pipe insertion connection through (H2) filler tube, (H3) water out with (C1-5) water inlet above (C1) duplex seat; (H4) two water pipes, (H5) water pipe folder with (C2-3) U molding box bottom constitutes drainage system again; Outside (C2-1) U molding box, then connecting (K) switch comprise (K1) low temperature alarm and (K2) Temperature probe that is connected and (K3) power line and (K4) battery case or (F) insertion of superconducting fluid thermal current diffusion shell be connected (C1) duplex seat and be connected with (C2) evaporation tank again; (H) hot-water heating system comprises that (F1-3) top cover of pouring water (H1) that connected in turn by (H0) hyponome lid funnel inserting (F) superconducting fluid thermal current diffusion shell upper end is connected mouth of pipe insertion connection through (H2) filler tube, (H3) water out with (C1-5) water inlet above (C1) duplex seat; (H4) two water pipes, (H5) water pipe folder with (C2-3) U molding box bottom constitutes drainage system again; Outside (C2-1) U molding box, then connect (K) switch and comprising (K1) low temperature alarm and (K2) Temperature probe that is connected and (K3) power line and (K4) battery case formation.

2, the multifunctional domestic superconducting heat tube heating device of a kind of not electricity consumption according to claim 1 and LED is characterized in that; (A) the gravity super heat-conductive pipe comprises that (A-1) condensation segment by the upper end is connected outer bolt and lower end with (A-2) of middle-end (A-3) evaporator section forms; Outside (A-1) of upper end condensation segment, be inserted in the heat radiator dedicated gravity super heat-conductive pipe that constitutes (AB) band radiator of connection (B) gravity super heat-conductive pipe;

3, the multifunctional domestic superconducting heat tube heating device of a kind of not electricity consumption according to claim 1 and LED is characterized in that; (E) the thermal current diffusion shell or (F) superconducting fluid thermal current diffusion shell insert (C1-4) superconducting fluid cup in (C1) duplex seat and connect (J) superconducting fluid cup that rim of a cup connects and be connected with (C2) evaporation tank again; (H) hot-water heating system comprises that (E1-1) top cover of pouring water (H1) that connected in turn by (H0) hyponome lid funnel inserting (E) thermal current diffusion shell upper end is connected the mouth of pipe through (H2) filler tube, (H3) water out and inserts (H4) two water pipes, (H5) water pipe of connecting with (C2-3) U molding box bottom again and press from both sides the formation drainage system with (C1-5) water inlet above (C1) duplex seat; Connect (K) switch in (C2-1) U molding box outside and comprising (K1) low temperature alarm and (K2) Temperature probe that is connected and (K3) power line and (K4) battery case formation.

4, the multifunctional domestic superconducting heat tube heating device of a kind of not electricity consumption according to claim 1 and LED is characterized in that; Connecting in the upper end of (C) evaporation casing and to have (D) Y shape infrared coating heat sink or (D2) (E) thermal current diffusion shell of blower fan heat diffuser; Connecting the quartzy infrared tube of (L1) 250W and (L2) the quartzy infrared tube of 100W and (L1-1) (L2-1) power line above in (C2-3) U molding box bottom of (C) evaporation casing lower end; Connecting (K2) Temperature probe that (K1) temperature controller connects and (K3) power line in (C2-3) U molding box outside.

5, the multifunctional domestic superconducting heat tube heating device of a kind of not electricity consumption according to claim 1 and LED is characterized in that; On (C) evaporation casing, connecting (F) superconducting fluid thermal current diffusion shell that has (D) Y shape infrared coating heat sink; (J) superconducting fluid cup that is connected with (C1-4) superconducting fluid cup connection rim of a cup connection in (C1) duplex seat on (C) evaporation casing is connected with (C2) evaporation tank again; (AB) upper end (A-1) condensation segment of the gravity super heat-conductive pipe of band radiator is placed in (F) superconducting fluid thermal current diffusion shell; (AB) lower end (A-3) evaporator section of the gravity super heat-conductive pipe of band radiator inserts the upper end that is connected in (J) superconducting fluid cup in (C) evaporation casing; Connecting the quartzy infrared tube of (L1) 250W and (L2) the quartzy infrared tube of 100W and (L1-1) (L2-1) power line above in (C2-3) U molding box bottom of (C) evaporation casing lower end; Connecting (K2) Temperature probe that (K1) temperature controller connects and (K3) power line in (C2-3) U molding box outside.

6, the multifunctional domestic superconducting heat tube heating device of a kind of not electricity consumption according to claim 1 and LED is characterized in that; On (C) evaporation casing, connecting and having (F1-3) connects (F1-4) liquid feeding mouth above the top cover (F) superconducting fluid thermal current diffusion shell; (J) superconducting fluid cup that is connected with (C1-4) superconducting fluid cup connection rim of a cup connection in (C1) duplex seat on (C) evaporation casing is connected with (C2) evaporation tank again; (AB) (A-1) condensation segment of the upper end of the gravity super heat-conductive pipe of band radiator is placed in (F) superconducting fluid thermal current diffusion shell; (AB) lower end (A-3) evaporator section of the gravity super heat-conductive pipe of band radiator inserts the upper end that is connected in (J) superconducting fluid cup in (C) evaporation casing; Connect (M) carbon fiber infrared tube above in (C2-3) U molding box bottom of (C) evaporation casing lower end and comprising (M1) 250W carbon fiber infrared tube, (M2) 100W carbon fiber infrared tube; Connecting (K2) Temperature probe that (K1) temperature controller connects and (K3) power line in (C2-3) U molding box outside.

7, the multifunctional domestic superconducting heat tube heating device of a kind of not electricity consumption according to claim 1 and LED is characterized in that; On (C) evaporation casing, connecting and having (F1-3) connects (F1-4) liquid feeding mouth above the top cover (F) superconducting fluid thermal current diffusion shell; (J) superconducting fluid cup that is connected with (C1-4) superconducting fluid cup connection rim of a cup connection in (C1) duplex seat on (C) evaporation casing is connected with (C2) evaporation tank again; (AB) (A-1) condensation segment of the upper end of the gravity super heat-conductive pipe of band radiator is placed in (F) superconducting fluid thermal current diffusion shell; (AB) lower end (A-3) evaporator section of the gravity super heat-conductive pipe of band radiator inserts the upper end that is connected in (J) superconducting fluid cup in (C) evaporation casing; Connecting (N) 250W infrared lamp above in (C2-3) U molding box bottom of (C) evaporation casing lower end; Connecting (K2) Temperature probe that (K1) temperature controller connects and (K3) power line in (C2-3) U molding box outside.

8, the multifunctional domestic superconducting heat tube heating device of a kind of not electricity consumption according to claim 1 and LED is characterized in that; On (C) evaporation casing, connecting and having (F1-3) connects (F1-4) liquid feeding mouth above the top cover (F) superconducting fluid thermal current diffusion shell; (J) superconducting fluid cup that is connected with (C1-4) superconducting fluid cup connection rim of a cup connection in (C1) duplex seat on (C) evaporation casing is connected with (C2) evaporation tank again; (AB) (A-1) condensation segment of the upper end of the gravity super heat-conductive pipe of band radiator is placed in (F) superconducting fluid thermal current diffusion shell; (AB) lower end (A-3) evaporator section of the gravity super heat-conductive pipe of band radiator inserts the upper end that is connected in (J) superconducting fluid cup in (C) evaporation casing; Connecting 5～10 on (P) 25W Electric radiant Heating Film cover of connecting by (P1) Electric radiant Heating Film connection electric wire above in (C2-3) U molding box bottom of (C) evaporation casing lower end; Connecting (K2) Temperature probe that (K1) temperature controller connects and (K3) power line in (C2-3) U molding box outside.

9, the multifunctional domestic superconducting heat tube heating device of a kind of not electricity consumption according to claim 1 and LED is characterized in that; On (C) evaporation casing, connecting and having (F1-3) connects (F1-4) liquid feeding mouth above the top cover (F) superconducting fluid thermal current diffusion shell; (J) superconducting fluid cup that is connected with (C1-4) superconducting fluid cup connection rim of a cup connection in (C1) duplex seat on (C) evaporation casing is connected with (C2) evaporation tank again; (AB) (A-1) condensation segment of the upper end of the gravity super heat-conductive pipe of band radiator is placed in (F) superconducting fluid thermal current diffusion shell; (AB) lower end (A-3) evaporator section of the gravity super heat-conductive pipe of band radiator inserts the upper end that is connected in (J) superconducting fluid cup in (C) evaporation casing; Connecting above in (C2-3) U molding box bottom of (C) evaporation casing lower end and comprising (Q1) electromagnetic eddy heater that connects by (Q2) electromagnetic circuit; (Q1) the electromagnetic eddy heater is included in (Q1-1) metal square frame and is connecting (Q1-2) solenoid; Connecting (Q) electromagnetic induction warmer that (Q1-3) eddy current high temperature pipe is formed in (Q1-1) metal square frame outer ring; Connecting (K2) Temperature probe that (K1) temperature controller connects and (K3) power line in (C2-3) U molding box outside.

10, the multifunctional domestic superconducting heat tube heating device of a kind of not electricity consumption according to claim 1 and LED is characterized in that; On (C) evaporation casing, connecting and having (F1-3) connects (F1-4) liquid feeding mouth above the top cover (F) superconducting fluid thermal current diffusion shell; (J) superconducting fluid cup that is connected with (C1-4) superconducting fluid cup connection rim of a cup connection in (C1) duplex seat on (C) evaporation casing is connected with (C2) evaporation tank again; (AB) (A-1) condensation segment of the upper end of the gravity super heat-conductive pipe of band radiator is placed in (F) superconducting fluid thermal current diffusion shell; (AB) lower end (A-3) evaporator section of the gravity super heat-conductive pipe of band radiator inserts the upper end that is connected in (J) superconducting fluid cup in (C) evaporation casing; Connecting (R) light emitting diode that (R0) LED heat radiating sheet connects above (J) superconducting fluid cup outer ring in (C2-3) U molding box bottom of (C) evaporation casing lower end; (R) light emitting diode is connecting (S) photo-cell assembly and is comprising that (S-1) connection electric wire, (S-2) battery, (S-3) photocell power supply interface, (S-4) two-way switch, (S-5) commercial power interface, (T) direct current transducer of being connected in turn by (S-0) photovoltaic cell module are connected the commercial power interface device with (T1); Connecting (K2) Temperature probe that (K1) temperature controller connects and (K3) power line in (C2-3) U molding box outside.

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