CN104061617A - Printing carbon crystal infrared negative oxygen ion air heater and manufacturing method thereof - Google Patents

Abstract

The invention discloses a printing carbon crystal infrared negative oxygen ion air heater. The printing carbon-crystal infrared negative oxygen ion air heater comprises a housing, wherein an air grid is arranged on one side of the housing; an air inlet is formed in the other side of the housing; a plurality of printing carbon crystal infrared negative oxygen ion plates are arranged in the housing and in positions close to the air grid in parallel; the direction in which the printing carbon crystal infrared negative oxygen ion plates are arranged is parallel to or perpendicular to the direction of air inlet; a fan, an anion material filtering layer and an activated carbon filter screen are sequentially arranged between the printing carbon crystal infrared negative oxygen ion plates and the air inlet; the manufacturing method for the printing carbon crystal infrared negative oxygen ion fan heater comprises the following steps: negative oxygen ion conducting adhesive is prepared and printed on an anion insulating piece; copper conducting wires are arranged on both sides of the negative oxygen ion conducting adhesive on the anion insulating piece; the sides of the negative oxygen ion conducting adhesive on the anion insulating piece are covered with plurality of epoxy glass cloth prepreg; under the vacuum condition, the anion insulating piece covered with the epoxy glass cloth prepreg is pressed into a whole, so that the printing carbon-crystal infrared negative oxygen ion plate is obtained; eventually, after assembly, the printing carbon-crystal infrared negative oxygen ion fan heater is manufactured. The invention solves problems that conventional fan heaters are low in electro thermal conversion rate, lack the function of filtering and purifying indoor pollutants, low in heating and quick in thermal efficiency decline.

Description

Brilliant infrared negative oxygen ion steam air heater of printing carbon and preparation method thereof

Technical field

The invention belongs to steam air heater technical field, the present invention relates to the brilliant infrared negative oxygen ion steam air heater of a kind of printing carbon, the invention still further relates to the preparation method of this steam air heater.

Background technology

Steam air heater can heat indoor or outdoors air, strengthens air circulation, and indoor air temperature is improved.Existing steam air heater heating principle mainly relies on the traditional heating mode such as resistive heater or quartz ampoule, and its shortcoming one is power consumption, high power but electric conversion rate is not high; The 2nd, function is more single, there is no indoor pollutant filtration, purification function, and also, without the generation function of negative aeroion, when indoor sealing, end user can feel unhappy, is unfavorable for health; The 3rd, heat slowly, conventionally need 2～5 minutes; The 4th, thermal effect decline is fast, because traditional heater is longer service time, the efficiency that produces heat is just lower, uses after 1 year or occurs heat fading phenomenon.

Summary of the invention

The object of this invention is to provide the brilliant infrared negative oxygen ion steam air heater of a kind of printing carbon, solved existing steam air heater electric conversion rate low, lack indoor pollutant filtration, purification function and heat the slow and thermal effect fast problem that fails.

The present invention also aims to, be provided for printing the negative oxygen ion conducting resinl of negative oxygen ion conductive adhesive layer and the preparation method of above-mentioned steam air heater.

The first technical scheme of the present invention is: the brilliant infrared negative oxygen ion steam air heater of printing carbon, comprise shell, shell one side is provided with air grid, opposite side is provided with air inlet, in shell, near air grid side, be arranged with the brilliant infrared negative oxygen ion plate of multiple printing carbon in parallel, the setting party of the brilliant infrared negative oxygen ion plate of printing carbon, to parallel or vertical with air intake direction, is disposed with fan, anion material filter course and activated charcoal strainer between the brilliant infrared negative oxygen ion plate of printing carbon and air inlet.

The brilliant infrared negative oxygen ion plate of printing carbon comprises anion insulating trip, on anion insulating trip, be printed with negative oxygen ion conductive adhesive layer, negative oxygen ion conductive adhesive layer is printed and is formed by negative oxygen ion conducting resinl, the both sides of negative oxygen ion conductive adhesive layer are laid with copper conductor, and laminating on anion insulating trip have a multi-disc epoxy glass fabric prepreg; Copper conductor is connected with respectively switch and controller; The brilliant infrared negative oxygen ion plate of printing carbon surface is provided with vibrator; Outer casing bottom is also provided with support.

The second technical scheme that the present invention takes is: for printing the negative oxygen ion conducting resinl of negative oxygen ion conductive adhesive layer, according to mass fraction, following raw material, consist of: 70～80 parts of heat-resistant fireproof epoxy resin, 2～50 parts of tourmaline nano materials, 2～50 parts of strange ice stone nano materials, 2～50 parts of cerias, 1～50 part of bamboo-carbon fibre, 1～50 part of high electrical-conductive nanometer carbon crystalline flour, 1～3 part, curing agent, 0.01～0.1 part of curing accelerator, 20～40 parts of solvents, 1～20 part of filler.

Feature of the present invention is also,

Curing agent is dicyandiamide, and curing accelerator is imidazoles, and solvent is acetone, and filler is magnesium hydroxide.

The third technical scheme that the present invention takes is: the preparation method of the brilliant infrared negative oxygen ion steam air heater of printing carbon, comprises the following steps:

Step 1: preparation negative oxygen ion conducting resinl, for printing negative oxygen ion conductive adhesive layer;

Step 2: use silk screen that the negative oxygen ion conducting resinl of step 1 preparation is printed on anion insulating trip, then dry the anion insulating trip that obtains once printing;

Step 3: use silk screen that the negative oxygen ion conducting resinl of step 1 preparation is printed on to the anion insulating trip of once printing that step 2 obtains, then dry the anion insulating trip after being printed;

Step 4: copper conductor is laid on the negative oxygen ion conductive adhesive layer both sides on the anion insulating trip after the printing obtaining in step 3, obtains the anion insulating trip with copper conductor;

Step 5: cover multi-disc epoxy glass fabric prepreg on the anion insulating trip with copper conductor obtaining in step 4, obtain being coated with the anion insulating trip of epoxy glass fabric prepreg;

Step 6: the anion insulating trip that is coated with epoxy glass fabric prepreg that step 5 is obtained presses down and is integrated at vacuum condition, obtains printing the brilliant infrared negative oxygen ion plate of carbon;

Step 7: the brilliant infrared negative oxygen ion plate of printing carbon that multiple steps 6 are obtained forms one group, mounting casing, fan, anion material filter course, activated charcoal strainer by copper conductor connecting valve and controller, obtain printing the brilliant infrared negative oxygen ion steam air heater finished product of carbon.

Feature of the present invention is also,

In step 1, negative oxygen ion conducting resinl is comprised of following raw material according to mass fraction: 70～80 parts of heat-resistant fireproof epoxy resin, 2～50 parts of tourmaline nano materials, 2～50 parts of strange ice stone nano materials, 2～50 parts of cerias, 1～50 part of bamboo-carbon fibre, 1～50 part of high electrical-conductive nanometer carbon crystalline flour, 1～3 part of dicyandiamide, 0.01～0.1 part of imidazoles, 20～40 parts, acetone, 1～20 part of magnesium hydroxide.

In step 2, the order number of silk screen is 45～80 orders, and the thickness of anion insulating trip is 1.0～1.5mm; The temperature of drying is 150 ℃～200 ℃, and the time is 20～60min.

In step 3, the order number of silk screen is 45～80 orders; The temperature of drying is 150 ℃～200 ℃, and the time is 20～60min; In step 3, the printing position of negative oxygen ion conducting resinl is identical with the printing position of negative oxygen ion conducting resinl in step 2.

In step 6, vacuum condition is-60～-80KPa, and the temperature of pressing is 150 ℃～200 ℃, and pressure is 4.0～6.0MPa, and the time is 60～100min.

In step 7, anion material filter course is comprised of following raw material according to mass fraction: 2～50 parts of tourmaline nano materials, 2～50 parts of strange ice stone nano materials, 2～50 parts of cerias, 1～50 part of bamboo-carbon fibre.

The invention has the beneficial effects as follows: the present invention prints the brilliant infrared negative oxygen ion steam air heater of carbon, tourmaline nano material can produce anion, after the energising of negative oxygen ion conducting resinl, heating is fast, the tourmaline nano material that ceria activates and the bamboo-carbon fibre pollutants such as formaldehyde in can absorbed air, solved existing steam air heater electric conversion rate low, lack indoor pollutant filtration, purification function and heat the slow and thermal effect fast problem that fails, can produce negative oxygen ion, have that air pollutants are filtered, anion discharges and produce warm air function.

Accompanying drawing explanation

Fig. 1 is the horizontal type structure schematic diagram that the present invention prints the brilliant infrared negative oxygen ion steam air heater of carbon;

Fig. 2 is the vertical structure schematic diagram that the present invention prints the brilliant infrared negative oxygen ion steam air heater of carbon;

Fig. 3 is the structural representation that the present invention prints the brilliant infrared negative oxygen ion plate of carbon;

Fig. 4 is the generalized section that the present invention prints the brilliant infrared negative oxygen ion plate of carbon;

Fig. 5 is the making flow chart that the present invention prints the brilliant infrared negative oxygen ion steam air heater of carbon.

In figure, 1. shell, 2. prints the brilliant infrared negative oxygen ion plate of carbon, 21. anion insulating trips, 22. copper conductors, 23. epoxy glass fabric prepregs, 24. negative oxygen ion conductive adhesive layers, 3. air grid, 4. fan, 5. anion material filter course, 6. activated charcoal strainer, 7. air inlet, 8. support.

The specific embodiment

Below in conjunction with the drawings and specific embodiments, the present invention is described in detail.

The present invention prints the brilliant infrared negative oxygen ion steam air heater of carbon, as shown in Figure 1, comprise shell 1, shell 1 one sides are provided with air grid 3, opposite side is provided with air inlet 7, in shell 1, near air grid 3 sides, be arranged with the brilliant infrared negative oxygen ion plate 2 of multiple printing carbon in parallel, the setting party of the brilliant infrared negative oxygen ion plate 2 of printing carbon is to parallel with air intake direction, or as shown in Figure 2, the brilliant infrared negative oxygen ion plate 2 of printing carbon arranges with air intake direction is vertical, between the brilliant infrared negative oxygen ion plate 2 of printing carbon and air inlet 7, be disposed with fan 4, anion material filter course 5 and activated charcoal strainer 6, the brilliant infrared negative oxygen ion plate of printing carbon 2 surfaces are provided with vibrator, as shown in Figure 3 and Figure 4, the brilliant infrared negative oxygen ion plate 2 of printing carbon comprises anion insulating trip 21, on anion insulating trip 21, be printed with negative oxygen ion conductive adhesive layer 24, negative oxygen ion conductive adhesive layer 24 is printed and is formed by negative oxygen ion conducting resinl, the both sides of negative oxygen ion conductive adhesive layer 24 are laid with copper conductor 22, and laminating on anion insulating trip 21 have a multi-disc epoxy glass fabric prepreg 23, copper conductor 22 is connected with respectively switch and controller, shell 1 bottom is also provided with support 8.

For printing the negative oxygen ion conducting resinl of negative oxygen ion conductive adhesive layer, according to mass fraction, by following raw material, formed: 70～80 parts of heat-resistant fireproof epoxy resin, 2～50 parts of tourmaline nano materials, 2～50 parts of strange ice stone nano materials, 2～50 parts of cerias, 1～50 part of bamboo-carbon fibre, 1～50 part of high electrical-conductive nanometer carbon crystalline flour, 1～3 part of dicyandiamide, 0.01～0.1 part of imidazoles, 20～40 parts, acetone, 1～20 part of magnesium hydroxide.

The preparation method of the brilliant infrared negative oxygen ion steam air heater of above-mentioned printing carbon, as shown in Figure 5, comprises the following steps:

Step 1: preparation negative oxygen ion conducting resinl, for printing negative oxygen ion conductive adhesive layer 24; Wherein, negative oxygen ion conducting resinl is comprised of following raw material according to mass fraction: 70～80 parts of heat-resistant fireproof epoxy resin, 2～50 parts of tourmaline nano materials, 2～50 parts of strange ice stone nano materials, 2～50 parts of cerias, 1～50 part of bamboo-carbon fibre, 1～50 part of high electrical-conductive nanometer carbon crystalline flour, 1～3 part of dicyandiamide, 0.01～0.1 part of imidazoles, 20～40 parts, acetone, 1～20 part of magnesium hydroxide;

Step 2: using order number is that 45～80 object silk screens are printed on the negative oxygen ion conducting resinl of step 1 preparation on the anion insulating trip 21 that thickness is 1.0～1.5mm, then dry, the temperature of drying is 150～200 ℃, and the time is 20～60min, the anion insulating trip that obtains once printing;

Step 3: using order number is that 45～80 object silk screens are printed on by the negative oxygen ion conducting resinl of step 1 preparation the anion insulating trip of once printing that step 2 obtains, print position identical with the printing position of negative oxygen ion conducting resinl in step 2, then dry, the temperature of drying is 150～200 ℃, time is 20～60min, the anion insulating trip after being printed;

Step 4: copper conductor 22 is laid on negative oxygen ion conductive adhesive layer 24 both sides on the anion insulating trip after the printing obtaining in step 3, obtains the anion insulating trip with copper conductor;

Step 5: cover multi-disc 7628 epoxy glass fabric prepregs 23 on the anion insulating trip with copper conductor obtaining in step 4, obtain being coated with the anion insulating trip of epoxy glass fabric prepreg;

Step 6: the anion insulating trip that is coated with epoxy glass fabric prepreg that step 5 is obtained presses down and is integrated at-60～vacuum condition of-80KPa, the temperature of pressing is 150～200 ℃, pressure is 4.0～6.0MPa, time is 60～100min, obtains printing the brilliant infrared negative oxygen ion plate 2 of carbon;

Step 7: the brilliant infrared negative oxygen ion plate 2 of printing carbon that multiple steps 6 are obtained forms one group, mounting casing 1, fan 4, anion material filter course 5, activated charcoal strainer 6 by copper conductor 22 connecting valves and controller, obtain printing the brilliant infrared negative oxygen ion steam air heater finished product of carbon; Wherein anion material filter course is comprised of following raw material according to mass fraction: 2～50 parts of tourmaline nano materials, 2～50 parts of strange ice stone nano materials, 2～50 parts of cerias, 1～50 part of bamboo-carbon fibre.

Two important electrical properties of tourmaline are piezo-electric effect and pyroelectric effect, this two individual character is upright connect with the generation of anion closely related.When being subject to extraneous pressure change or temperature rising when tourmaline, its crystal structure changes, and surface charge strengthens, and the anion of generation is just more.Utilize this principle, can be by adding electromagnetic shaker to aggravate its piezo-electric effect; I.e. heating after the energising of negative oxygen ion conducting resinl, makes product self have heating function in addition.In addition, take the tourmaline after rare-earth activated, in tourmaline, add appropriate ceria, the tourmaline after activating is stronger for the pollutant abilities such as formaldehyde in purifying air.

The present invention prints the brilliant infrared negative oxygen ion steam air heater of carbon, in air filtration step, except activated charcoal strainer 6, increased anion material filter course 5, take tourmaline nano material, strange ice stone nano material and bamboo-carbon fibre as main, can further increase anion generation.Design facilitates removable filter layer in addition, to facilitate the replacing of activated charcoal strainer 6 or anion material filter course 5.

The present invention has following beneficial effect:

(1) electric conversion rate that heating part that the present invention adopts prints the brilliant infrared negative oxygen ion plate of carbon is more than 98%, has solved that existing steam air heater conversion efficiency of thermoelectric is low, the problem of power consumption;

(2) the present invention has adopted anion material filter course and activated charcoal strainer, can remove indoor formaldehyde, peculiar smell and granule floating dust; The anion that anion material produces can be combined with granule floating dust, promotes its sedimentation, unhappy even if indoor sealing can not felt yet, can make room air more pure and fresh, has solved the problem that can not purify the air of a room when existing product is used;

(3) the heating part that the present invention adopts prints the brilliant infrared negative oxygen ion plate quick heating of carbon, and the latter one minute inner plate surface temperature of switching on can arrive 65 ℃;

(4) heating part thermal effect of the present invention decline is extremely slow, be difficult for aging, long service life, the theoretical life-span is 50 years.

Embodiment 1

Step 1: preparation negative oxygen ion conducting resinl, for printing negative oxygen ion conductive adhesive layer 24; Wherein, negative oxygen ion conducting resinl is comprised of following raw material: TG150 heat-resistant fireproof epoxy resin 350g, white 8000 object tourmaline nano material 150g, the strange ice stone of black 5000 object nano material 10g, ceria 10g, bamboo-carbon fibre 250g, the high electrical-conductive nanometer carbon of black 2000 object crystalline flour 150g, dicyandiamide 15g, imidazoles 0.5g, acetone 100g, magnesium hydroxide 50g;

Step 2: using order number is that 45 object silk screens are printed on the negative oxygen ion conducting resinl of step 1 preparation on the anion insulating trip 21 that thickness is 1.0mm, then dries, and the temperature of oven dry is 150 ℃, and the time is 60min, the anion insulating trip that obtains once printing;

Step 3: using order number is that 45 object silk screens are printed on by the negative oxygen ion conducting resinl of step 1 preparation the anion insulating trip of once printing that step 2 obtains, print position identical with the printing position of negative oxygen ion conducting resinl in step 2, then dry, the temperature of drying is 150 ℃, time is 60min, the anion insulating trip after being printed;

Step 4: copper conductor 22 is laid on negative oxygen ion conductive adhesive layer 24 both sides on the anion insulating trip after the printing obtaining in step 3, obtains the anion insulating trip with copper conductor;

Step 5: cover 4 7628 epoxy glass fabric prepregs 23 on the anion insulating trip with copper conductor obtaining in step 4, obtain being coated with the anion insulating trip of epoxy glass fabric prepreg;

Step 6: the anion insulating trip that is coated with epoxy glass fabric prepreg that step 5 is obtained presses down and is integrated at-the vacuum condition of 60KPa, the temperature of pressing is 150 ℃, pressure is 6.0MPa, and the time is 100min, obtains printing the brilliant infrared negative oxygen ion plate 2 of carbon;

Step 7: the brilliant infrared negative oxygen ion plate 2 of printing carbon that 4 steps 6 are obtained forms one group, mounting casing 1, fan 4, anion material filter course 5, activated charcoal strainer 6 by copper conductor 22 connecting valves and controller, obtain printing the brilliant infrared negative oxygen ion steam air heater finished product of carbon; Wherein anion material filter course is comprised of following raw material: tourmaline nano material 150g, strange ice stone nano material 10g, ceria 10g, bamboo-carbon fibre 250g.

Embodiment 2

Step 1: preparation negative oxygen ion conducting resinl, for printing negative oxygen ion conductive adhesive layer 24; Wherein, negative oxygen ion conducting resinl is comprised of following raw material: TG150 heat-resistant fireproof epoxy resin 375g, white 8000 object tourmaline nano material 10g, the strange ice stone of black 5000 object nano material 250g, ceria 150g, bamboo-carbon fibre 5g, the high electrical-conductive nanometer carbon of black 2000 object crystalline flour 250g, dicyandiamide 5g, imidazoles 0.25g, acetone 150g, magnesium hydroxide 5g;

Step 2: using order number is that 60 object silk screens are printed on the negative oxygen ion conducting resinl of step 1 preparation on the anion insulating trip 21 that thickness is 1.3mm, then dries, and the temperature of oven dry is 180 ℃, and the time is 40min, the anion insulating trip that obtains once printing;

Step 3: using order number is that 60 object silk screens are printed on by the negative oxygen ion conducting resinl of step 1 preparation the anion insulating trip of once printing that step 2 obtains, print position identical with the printing position of negative oxygen ion conducting resinl in step 2, then dry, the temperature of drying is 180 ℃, time is 40min, the anion insulating trip after being printed;

Step 4: copper conductor 22 is laid on negative oxygen ion conductive adhesive layer 24 both sides on the anion insulating trip after the printing obtaining in step 3, obtains the anion insulating trip with copper conductor;

Step 5: cover 5 7628 epoxy glass fabric prepregs 23 on the anion insulating trip with copper conductor obtaining in step 4, obtain being coated with the anion insulating trip of epoxy glass fabric prepreg;

Step 6: the anion insulating trip that is coated with epoxy glass fabric prepreg that step 5 is obtained presses down and is integrated at-the vacuum condition of 70KPa, the temperature of pressing is 180 ℃, pressure is 5.0MPa, time is 80min, obtain printing the brilliant infrared negative oxygen ion plate 2 of carbon, and on the brilliant infrared negative oxygen ion plate of printing carbon 2 surfaces, vibrator is installed;

Step 7: the brilliant infrared negative oxygen ion plate 2 of printing carbon that 5 steps 6 are obtained forms one group, mounting casing 1, fan 4, anion material filter course 5, activated charcoal strainer 6 by copper conductor 22 connecting valves and controller, obtain printing the brilliant infrared negative oxygen ion steam air heater finished product of carbon; Wherein anion material filter course is comprised of following raw material: tourmaline nano material 10g, strange ice stone nano material 250g, ceria 150g, bamboo-carbon fibre 5g.

Embodiment 3

Step 1: preparation negative oxygen ion conducting resinl, for printing negative oxygen ion conductive adhesive layer 24; Wherein, negative oxygen ion conducting resinl is comprised of following raw material: TG150 heat-resistant fireproof epoxy resin 400g, white 8000 object tourmaline nano material 250g, the strange ice stone of black 5000 object nano material 150g, ceria 250g, bamboo-carbon fibre 150g, the high electrical-conductive nanometer carbon of black 2000 object crystalline flour 5g, dicyandiamide 10g, imidazoles 0.05g, acetone 200g, magnesium hydroxide 100g;

Step 2: using order number is that 80 object silk screens are printed on the negative oxygen ion conducting resinl of step 1 preparation on the anion insulating trip 21 that thickness is 1.5mm, then dries, and the temperature of oven dry is 200 ℃, and the time is 20min, the anion insulating trip that obtains once printing;

Step 3: using order number is that 80 object silk screens are printed on by the negative oxygen ion conducting resinl of step 1 preparation the anion insulating trip of once printing that step 2 obtains, print position identical with the printing position of negative oxygen ion conducting resinl in step 2, then dry, the temperature of drying is 200 ℃, time is 20min, the anion insulating trip after being printed;

Step 4: copper conductor 22 is laid on negative oxygen ion conductive adhesive layer 24 both sides on the anion insulating trip after the printing obtaining in step 3, obtains the anion insulating trip with copper conductor;

Step 5: cover 6 7628 epoxy glass fabric prepregs 23 on the anion insulating trip with copper conductor obtaining in step 4, obtain being coated with the anion insulating trip of epoxy glass fabric prepreg;

Step 6: the anion insulating trip that is coated with epoxy glass fabric prepreg that step 5 is obtained presses down and is integrated at-the vacuum condition of 80KPa, the temperature of pressing is 200 ℃, pressure is 4.0MPa, and the time is 60min, obtains printing the brilliant infrared negative oxygen ion plate 2 of carbon;

Step 7: the brilliant infrared negative oxygen ion plate 2 of printing carbon that 6 steps 6 are obtained forms one group, mounting casing 1, fan 4, anion material filter course 5, activated charcoal strainer 6 by copper conductor 22 connecting valves and controller, obtain printing the brilliant infrared negative oxygen ion steam air heater finished product of carbon; Wherein anion material filter course is comprised of following raw material: tourmaline nano material 250g, strange ice stone nano material 150g, ceria 250g, bamboo-carbon fibre 15g.

Claims (10)

1. print the brilliant infrared negative oxygen ion steam air heater of carbon, it is characterized in that, comprise shell (1), described shell (1) one side is provided with air grid (3), opposite side is provided with air inlet (7), in described shell (1), near described air grid (3) side, be arranged with the brilliant infrared negative oxygen ion plate (2) of multiple printing carbon in parallel, the setting party of the brilliant infrared negative oxygen ion plate of described printing carbon (2) is to parallel or vertical with air intake direction, between the brilliant infrared negative oxygen ion plate (2) of described printing carbon and described air inlet (7), be disposed with fan (4), anion material filter course (5) and activated charcoal strainer (6).

2. the brilliant infrared negative oxygen ion steam air heater of printing carbon as claimed in claim 1, it is characterized in that, the brilliant infrared negative oxygen ion plate of described printing carbon (2) comprises anion insulating trip (21), on described anion insulating trip (21), be printed with negative oxygen ion conductive adhesive layer (24), described negative oxygen ion conductive adhesive layer (24) is printed and is formed by negative oxygen ion conducting resinl, the both sides of described negative oxygen ion conductive adhesive layer (24) are laid with copper conductor (22), the upper laminating multi-disc epoxy glass fabric prepreg (23) that has of described anion insulating trip (21); Described copper conductor (22) is connected with respectively switch and controller; The brilliant infrared negative oxygen ion plate (2) of described printing carbon surface is provided with vibrator; Described shell (1) bottom is also provided with support (8).

3. for printing the negative oxygen ion conducting resinl of negative oxygen ion conductive adhesive layer, it is characterized in that, according to mass fraction, by following raw material, formed: 70～80 parts of heat-resistant fireproof epoxy resin, 2～50 parts of tourmaline nano materials, 2～50 parts of strange ice stone nano materials, 2～50 parts of cerias, 1～50 part of bamboo-carbon fibre, 1～50 part of high electrical-conductive nanometer carbon crystalline flour, 1～3 part, curing agent, 0.01～0.1 part of curing accelerator, 20～40 parts of solvents, 1～20 part of filler.

4. as claimed in claim 3ly for printing the negative oxygen ion conducting resinl of negative oxygen ion conductive adhesive layer, it is characterized in that, described curing agent is dicyandiamide, and described curing accelerator is imidazoles, and described solvent is acetone, and described filler is magnesium hydroxide.

5. the preparation method of the brilliant infrared negative oxygen ion steam air heater of printing carbon, is characterized in that, comprises the following steps:

Step 1: preparation negative oxygen ion conducting resinl, for printing negative oxygen ion conductive adhesive layer (24);

Step 2: use silk screen that the negative oxygen ion conducting resinl of described step 1 preparation is printed on to anion insulating trip (21) upper, then dry the anion insulating trip that obtains once printing;

Step 3: use silk screen that the negative oxygen ion conducting resinl of described step 1 preparation is printed on to the anion insulating trip of once printing that described step 2 obtains, then dry the anion insulating trip after being printed;

Step 4: copper conductor (22) is laid on negative oxygen ion conductive adhesive layer (24) both sides on the anion insulating trip after the printing obtaining in described step 3, obtains the anion insulating trip with copper conductor;

Step 5: cover multi-disc epoxy glass fabric prepreg (23) on the anion insulating trip with copper conductor obtaining in described step 4, obtain being coated with the anion insulating trip of epoxy glass fabric prepreg;

Step 6: the anion insulating trip that is coated with epoxy glass fabric prepreg that described step 5 is obtained presses down and is integrated at vacuum condition, obtains printing the brilliant infrared negative oxygen ion plate (2) of carbon;

Step 7: the brilliant infrared negative oxygen ion plate of printing carbon (2) that step 6 described in multiple is obtained forms one group, mounting casing (1), fan (4), anion material filter course (5), activated charcoal strainer (6) by copper conductor (22) connecting valve and controller, obtain printing the brilliant infrared negative oxygen ion steam air heater finished product of carbon.

6. the preparation method of the brilliant infrared negative oxygen ion steam air heater of printing carbon as claimed in claim 5, it is characterized in that, in described step 1, negative oxygen ion conducting resinl is comprised of following raw material according to mass fraction: 70～80 parts of heat-resistant fireproof epoxy resin, 2～50 parts of tourmaline nano materials, 2～50 parts of strange ice stone nano materials, 2～50 parts of cerias, 1～50 part of bamboo-carbon fibre, 1～50 part of high electrical-conductive nanometer carbon crystalline flour, 1～3 part of dicyandiamide, 0.01～0.1 part of imidazoles, 20～40 parts, acetone, 1～20 part of magnesium hydroxide.

7. the preparation method of the brilliant infrared negative oxygen ion steam air heater of printing carbon as claimed in claim 5, is characterized in that, in described step 2, the order number of silk screen is 45～80 orders, and the thickness of described anion insulating trip (21) is 1.0～1.5mm; The temperature of described oven dry is 150 ℃～200 ℃, and the time is 20～60min.

8. the preparation method of the brilliant infrared negative oxygen ion steam air heater of printing carbon as claimed in claim 5, is characterized in that, in described step 3, the order number of silk screen is 45～80 orders; The temperature of described oven dry is 150 ℃～200 ℃, and the time is 20～60min; In described step 3, the printing position of negative oxygen ion conducting resinl is identical with the printing position of negative oxygen ion conducting resinl in described step 2.

9. the preparation method of the brilliant infrared negative oxygen ion steam air heater of printing carbon as claimed in claim 5, it is characterized in that, in described step 6, vacuum condition is-60～-80KPa, and the temperature of pressing is 150 ℃～200 ℃, pressure is 4.0～6.0MPa, and the time is 60～100min.

10. the preparation method of the brilliant infrared negative oxygen ion steam air heater of printing carbon as claimed in claim 5, it is characterized in that, in described step 7, anion material filter course is comprised of following raw material according to mass fraction: 2～50 parts of tourmaline nano materials, 2～50 parts of strange ice stone nano materials, 2～50 parts of cerias, 1～50 part of bamboo-carbon fibre.