CN201564992U - Frequency spectrum generator - Google Patents

Abstract

The utility model discloses a frequency spectrum generator which comprises an electric heating layer and a frequency spectrum generating layer, wherein the frequency spectrum generating layer is arranged on the surface of the electric heating layer, and the frequency spectrum generating layer consists of far infrared radiation coatings which are coated on the surface of the electric heating layer. The utility model provides a frequency spectrum generator which solves the technical problem that existing frequency spectrum generators have complicated structures, and realizes the purposes that the frequency spectrum generators have simple structures, the radiation wave length can be matched with optimal absorbing wave length matched with human bodies, and the radiation rate is comparatively higher.

Description

Spectrum generator

Technical field

This utility model relates to medical instruments field, the particularly a kind of spectrum generator that can simulate human-body biological optimal absorption frequency spectrum.

Background technology

Along with improving constantly of people's living standard, the spectrum generator with medical care effect more and more is subjected to people's favor.

In the prior art; have the advanced relatively spectrum generator of a kind of structure, it comprises an Electric radiant Heating Film zone of heating, is provided with the PET insulating barrier above the Electric radiant Heating Film zone of heating; above the PET insulating barrier, be provided with the frequency spectrum genetic horizon, below the Electric radiant Heating Film zone of heating, be provided with the protection quilt cover.But the spectrum generator of this multiple structure makes itself manufacturing process or relative complex.

The utility model content

The purpose of this utility model provides a kind of spectrum generator, solved the baroque technical problem of existing spectrum generator, realized that spectrum generator simple structure and its radiation wavelength can mate the optimum absorb wavelength of human body, the higher relatively purpose of radiance.

For achieving the above object, this utility model provides a kind of spectrum generator, it is characterized in that, comprises electrothermal layer and frequency spectrum genetic horizon,

Described frequency spectrum genetic horizon is arranged at the surface of described electrothermal layer, and described frequency spectrum genetic horizon is coated on the surface of described electrothermal layer by coatings capable of preventing from far infrared radiation and forms.

Spectrum generator of the present utility model has by coatings capable of preventing from far infrared radiation and is coated on the surface of described electrothermal layer and the frequency spectrum genetic horizon that forms and the easy structure of electrothermal layer.And, form owing to the surface that is coated on described electrothermal layer in the coatings capable of preventing from far infrared radiation of frequency spectrum genetic horizon and comprise the composition of anion emulsion, and make spectrum generator of the present utility model have the advantage that radiation wavelength can mate the optimum absorb wavelength of human body; Further, because in the process of the described infrared radiation coating of preparation, adopted twice grinding technics and made that particle grain size arrives micro-nano scope (being generally about 100～400nm) in the coatings capable of preventing from far infrared radiation, make this infrared radiation coating have high radiant rate, make spectrum generator of the present utility model also have the relative advantage of higher of radiance simultaneously.

Description of drawings

Fig. 1 is the structural representation of this utility model spectrum generator;

Fig. 2 is the preparation method flow chart of this utility model coatings capable of preventing from far infrared radiation;

Fig. 3 is the preparation method flow chart of this utility model spectrum generator.

The specific embodiment

Below by drawings and Examples, the technical solution of the utility model is described in further detail.

Fig. 1 is the structural representation of this utility model spectrum generator.As shown in Figure 1, the spectrum generator of present embodiment comprises electrothermal layer 11 and frequency spectrum genetic horizon 12, wherein, frequency spectrum genetic horizon 12 is arranged at the surface of electrothermal layer 11, and frequency spectrum genetic horizon 12 is coated on the surface of electrothermal layer 11 by coatings capable of preventing from far infrared radiation and forms, and described electrothermal layer 11 is metal electric heating membrane, carbon fiber electrothermal plate or Muscovitum electric hot plate.The component that is coated on electrothermal layer 11 surface and forms the coatings capable of preventing from far infrared radiation of frequency spectrum genetic horizon 12 comprises mixed slurry and water-base epoxy film former, wherein, described mixed slurry comprises anion emulsion 3～15%, oxide mixture 15～30%, dispersant 0.1～0.5%, water 20～30%, and described dispersant is aqueous dispersion or aqueous dispersion mixture; Described water-base epoxy film former comprises water-base epoxy film former B component 12～30% and water-base epoxy film former A component 10～25%, described water-base epoxy film former A component is epoxy resin or epoxy resin composition, and described water-base epoxy film former B component is an aqueous epoxy curing agent.

Further, shown in the preparation method flow chart that Fig. 2 is this utility model coatings capable of preventing from far infrared radiation, the method for preparing coatings capable of preventing from far infrared radiation comprises:

Step 21, mixed slurry is put into agitating ball mill ground 2～4 hours; being put into ultra-fine grinding machine for super again ground 1～2 hour; to generate the micro-nano granules mixed slurry, the mixed slurry in the present embodiment comprises anion emulsion 3～15%, oxide mixture 15～30%, dispersant 0.1～0.5%, water 20～30%.Why mixed slurry is carried out twice grinding in this step, be in order further to improve the radiance of the coatings capable of preventing from far infrared radiation of final prepared one-tenth, make through twice grinding that particle grain size arrives micro-nano scope in the mixed slurry, be generally about 100～400nm.Because particle grain size is more little, surface area is just big more, and the atom that is distributed in the surface is just many more, will cause particulate surface activity to enlarge markedly; Again since surface-active increase helps microcosmic particle absorb external energy after, discharge unnecessary energy, the mode that releases energy has many kinds, far infrared radiation is exactly wherein a kind of.Therefore, the more little raising that helps radiance more of particle grain size in the coating.

Wherein the anion emulsion contains the anion mineral material, its can be radiation infrared wavelength in 2～18 mu m ranges, coordinate fine with the far infrared optimal wavelength 9.6 μ m of suitable absorption of human body, can all be absorbed by human body, and anion can be facilitated the synthetic and vitamin storage of human body, the physiological activity of reinforcement and human activin, be called as " air vitamin ", anion can also make oxygen content increase in the blood further, helping blood oxygen carries, absorb and utilization, has the human body of promotion metabolism, improve the human body immunity, strengthen human body flesh energy, regulate the effect of human body function balance, in addition, the function that anion also has killing pathogenic bacteria and purifies air, described in the present embodiment anion emulsion is prepared from through extra-fine grinding to 100～200nm by the natural minerals tourmaline, compare with the method for artificial acquisition anion, the permanent release anion of tourmaline capable, and in discharging the anion process, do not consume energy, do not produce the ozone and the active oxygen that human body there are harm, the environmental protection practicality yet;

Described dispersant is aqueous dispersion or aqueous dispersion mixture, specifically can be 8030N, SN-5040, the aqueous dispersion mixture that a kind of aqueous dispersion or several aqueous dispersion mix in the trade mark aqueous dispersions such as TH-904;

Described oxide mixture is three kinds or a multiple mixture in the oxides such as chrome oxide green, zirconium oxide, cobalt sesquioxide, aluminium oxide, silicon dioxide, titanium dioxide, ferrum oxide, niobium pentaoxide, cobalt oxide, magnesium oxide, manganese dioxide, molybdenum oxide; Selective oxidation thing mixture why in the present embodiment, be because single oxide often can only have bigger radiance in some narrower dominant wavelength ranges, two or more oxides are mixed, can make the material that can in quite wide wave-length coverage, all have, more help absorption of human body than the large radiation rate.Further, the selection of oxide and mixed proportion are foundation with following two standards:

One, according to different physical therapy purposes, selection can radiation be mated the oxide of wavelength, and mixes in the proper ratio;

Two, under the prerequisite of conformance with standard one, the mixing of different colours oxide, with radiating layer higher degree of blackness being arranged is preferential the selection, thereby the coatings capable of preventing from far infrared radiation that makes present embodiment has the radiation condition of similar absolute black body, improved radiance, as the green system of industrial oxidation chromium: chrome oxide green is a bottle green, and mixing such as magnesium oxide, aluminium oxide, molybdenum oxide that the are equipped with light color afterwards color of coatings capable of preventing from far infrared radiation are bottle green; Titanium-zirconium system: with titanium dioxide, zirconium oxide is main component, adds melanism oxides such as ferrum oxide, manganese dioxide, chromic oxide, and the color of mixing the back coatings capable of preventing from far infrared radiation is a black; Melanism zirconium system: with zirconium oxide, silicon dioxide is main component, adds melanism oxides such as ferrum oxide, manganese dioxide, cobalt oxide, and the color of mixing the back coatings capable of preventing from far infrared radiation is a black; Aluminum system: based on aluminium oxide, zirconium oxide, silicon dioxide, add melanism oxides such as ferrum oxide, cobalt oxide, chromic oxide, the color of mixing the back coatings capable of preventing from far infrared radiation is a black.

Step 22, described micro-nano granules mixed slurry and water-base epoxy film former B component 12～30% are put into high function agitator mix, put into again and mediate 2～3 times on the three-roll grinder, to generate hybridized mixed liquid, described water-base epoxy film former B component is an aqueous epoxy curing agent; Wherein, the preparation process of described aqueous epoxy curing agent comprises:

The bis-epoxy long-chain compound is added drop-wise in the mixed liquor of polyethylene polyamine and organic solvent, is added dropwise to complete the reaction temperature 2～3 hours that the back keeps 45～75 ℃, generate first reactant liquor, described bis-epoxy long-chain compound is the polyether polyol diglycidyl ether; Described polyether polyol diglycidyl ether is one of polyethyleneglycol diglycidylether or polypropylene glycol diglycidyl ether, or the mixture of polyethyleneglycol diglycidylether and polypropylene glycol diglycidyl ether; Described polyethylene polyamine is any one of diethylenetriamine, triethylene tetramine, TEPA, m-xylene diamine or a benzene two methanediamines;

Diluent is added drop-wise in described first reactant liquor, be added dropwise to complete the reaction temperature 2～3 hours that the back keeps 45～75 ℃, generate second reactant liquor, described epoxy resin is bisphenol A type epoxy resin, and this bisphenol A type epoxy resin specifically can be selected epoxy 828,834 for use, 618, the bisphenol A type epoxy resin of the domestic and international trade mark such as 637,638,6101 grades;

Finally by will carrying out distilling under reduced pressure, remove organic solvent and diluent to described second reactant liquor, being prepared into aqueous epoxy curing agent, and described organic solvent and all preferred propylene glycol monomethyl ether of diluent.

Step 23, hybridized mixed liquid and the water-base epoxy film former A component 10～25% that is generated fully mixed, to be prepared into coatings capable of preventing from far infrared radiation, described water-base epoxy film former A component is epoxy resin or epoxy resin composition, particularly, water-base epoxy film former A component is a kind of epoxy resin or several epoxy resin composition that mixes in epoxy resin 128,6002,828 etc.

In actual applications, the preparation of water-base epoxy film former comprises water-base epoxy film former A component and water-base epoxy film former B component, wherein,

To be epoxy resin 128,6002 form according to 1: 1 mixed water-base epoxy film former A component;

Water-base epoxy film former B component is an aqueous epoxy curing agent, and the preparation process of its aqueous epoxy curing agent is as follows:

Add the 70ml propylene glycol monomethyl ether in the 500ml four-hole bottle of condensing tube, agitator is housed, starts stirring, the triethylene tetramine with 0.4mol under nitrogen protection adds in the four-hole bottle; Mixing speed is 550r/min, adopt heating in water bath, temperature is set at 60 ℃, when reaching setting value, temperature begins to drip polyethyleneglycol diglycidylether 0.2mol, rate of addition is 0.5ml/min, behind the dropping beginning 10min, stops logical nitrogen, be incubated 2.5h after being added dropwise to complete again, to generate first reactant liquor.After insulation finishes, to generating the epoxy resin 828 of first reactant liquor with the speed dropping 0.15mol of 1ml/min, be viscosity and the controls reaction speed that reduces epoxy resin, the propylene glycol monomethyl ether of using 40ml is to 828 dilution back droppings, be added dropwise to complete back insulation 2.5h, to generate second reactant liquor.Reaction is finished postcooling to the room temperature discharging, in 70～90 ℃ of intervals second reactant liquor that is generated is carried out distilling under reduced pressure, removes the organic solvent propylene glycol monomethyl ether, obtains the aqueous epoxy curing agent of oyster transparent and homogeneous.

Prepare on the basis of finishing in above-mentioned water-base epoxy film former A component and water-base epoxy film former B component, the detailed process of coatings capable of preventing from far infrared radiation preparation can be:

With anion emulsion 210 grams, titanium dioxide 600 grams, zirconium oxide 150 grams, three oxygen, two cobalts, 45 grams, niobium pentaoxide 35 grams, water 1200 grams, the mixed slurry that dispersant SN-504015 gram is made into is put into agitating ball mill and is ground 3h; Then, the slurry after grinding for the first time is put into regrinding 2h in the ultra-fine grinding machine for super, reaches about 200nm with particle diameter and be advisable, and be prepared into the micro-nano granules mixed slurry.The micro-nano granules slurry of preparation and water-base epoxy film former B component 900 gram are put into high function agitator to be mixed, then put on the three-roll grinder and mediate 3 times, to generate hybridized mixed liquid, again hybridized mixed liquid and water-base epoxy film former A component 700 grams are fully mixed afterwards.So far, just finished the preparation of coatings capable of preventing from far infrared radiation.

Perhaps, with anion emulsion 250 grams, titanium dioxide 600 grams, zirconium oxide 150 grams, ferrum oxide 50 grams, manganese dioxide 30 grams, water 1200 grams, the mixed slurry that dispersant 8030N 12 grams are made into is put into agitating ball mill and is ground 3h; Then, the slurry after grinding for the first time is put into regrinding 2h in the ultra-fine grinding machine for super, reaches about 200nm with particle diameter and be advisable, and be prepared into the micro-nano granules mixed slurry.The micro-nano granules slurry of preparation and water-base epoxy film former B component 1100 gram are put into high function agitator to be mixed, then put on the three-roll grinder and mediate 3 times, to generate hybridized mixed liquid, again hybridized mixed liquid and water-base epoxy film former A component 900 grams are fully mixed afterwards.So far, just finished the preparation of coatings capable of preventing from far infrared radiation.

Perhaps, with anion emulsion 470 grams, aluminium oxide is 120 grams, molybdenum oxide 100 grams, and chrome oxide green 462 grams, water 1200 grams, the mixed slurry that dispersant 8030N 12 grams are made into is put into agitating ball mill and is ground 4h; Then, the slurry after grinding for the first time is put into regrinding 2h in the ultra-fine grinding machine for super, reaches about 200nm with particle diameter and be advisable, and be prepared into the micro-nano granules mixed slurry.。The micro-nano granules slurry of preparation and water-base epoxy film former B component 1000 gram are put into high function agitator to be mixed, then put on the three-roll grinder and mediate 3 times, to generate hybridized mixed liquid, again hybridized mixed liquid and water-base epoxy film former A component 800 grams are fully mixed afterwards.So far, just finished the preparation of coatings capable of preventing from far infrared radiation.

Perhaps, with anion emulsion 150 grams, silicon dioxide 500 grams, zirconium oxide 200 grams, cobalt oxide 40 grams, manganese dioxide 40 grams, water 1200 grams, the mixed slurry that dispersant SN-504015 gram is made into is put into agitating ball mill and is ground 4h; Then, the slurry after grinding for the first time is put into regrinding 2h in the ultra-fine grinding machine for super, reaches about 200nm with particle diameter and be advisable, and be prepared into the micro-nano granules mixed slurry.The micro-nano granules slurry of preparation and water-base epoxy film former B component 1000 gram are put into high function agitator to be mixed, then put on the three-roll grinder and mediate 3 times, to generate hybridized mixed liquid, again hybridized mixed liquid and water-base epoxy film former A component 800 grams are fully mixed afterwards.So far, just finished the preparation of coatings capable of preventing from far infrared radiation.

Perhaps, with anion emulsion 270 grams, silicon dioxide 500 grams, zirconium oxide 200 grams, ferrum oxide 30 grams, manganese dioxide 55 grams, water 1200 grams, the mixed slurry that dispersant 8030N 12 grams are made into is put into agitating ball mill and is ground 4h; Then, the slurry after grinding for the first time is put into regrinding 2h in the ultra-fine grinding machine for super, reaches about 200nm with particle diameter and be advisable, and be prepared into the micro-nano granules mixed slurry.The micro-nano granules slurry of preparation and water-base epoxy film former B component 1200 gram are put into high function agitator to be mixed, then put on the three-roll grinder and mediate 3 times, to generate hybridized mixed liquid, again hybridized mixed liquid and water-base epoxy film former A component 1100 grams are fully mixed afterwards.So far, just finished the preparation of coatings capable of preventing from far infrared radiation.

Perhaps, with anion emulsion 210 grams, aluminium oxide is 550 grams, zirconium oxide 200 grams, and silica 1 50 grams, ferrum oxide 50 grams, chromic oxide 50 grams, water 1300 grams, the mixed slurry that dispersant TH-90413 gram is made into is put into agitating ball mill and is ground 3h; Then, the slurry after grinding for the first time is put into regrinding 2h in the ultra-fine grinding machine for super, reaches about 200nm with particle diameter and be advisable, and be prepared into the micro-nano granules mixed slurry.The micro-nano granules slurry of preparation and water-base epoxy film former B component 1000 gram are put into high function agitator to be mixed, then put on the three-roll grinder and mediate 3 times, to generate hybridized mixed liquid, again hybridized mixed liquid and water-base epoxy film former A component 800 grams are fully mixed afterwards.So far, just finished the preparation of coatings capable of preventing from far infrared radiation.

The preparation process of the coatings capable of preventing from far infrared radiation of present embodiment, the oxide and the anion emulsion combination that contains anion that will have function far infrared radiation function, make the coatings capable of preventing from far infrared radiation that is prepared into have far infrared effect and negative ion effect simultaneously, and the optimum absorb wavelength matching of its radiation wavelength and human body is good, have the radiance advantage of higher, so the spectrum generator of present embodiment also has same advantage; In far-infrared radiation material, introduce the aqueous epoxy resins film former simultaneously, because the aqueous epoxy resins film former has strong adhesion, therefore will directly be coated on the surface of electrothermal layer and form the frequency spectrum genetic horizon at far-infrared radiation material, and then be prepared into spectrum generator, and the aqueous epoxy resins film former also has corrosion-resistant, characteristics such as mechanical performance is good, and the aqueous, environmental protective product that belongs to nontoxic pollution-free, therefore this coatings capable of preventing from far infrared radiation also has these characteristics, present embodiment also has corrosion-resistant with the spectrum generator of the prepared one-tenth of this coatings capable of preventing from far infrared radiation, characteristics such as mechanical performance is good, and belong to the aqueous, environmental protective product of nontoxic pollution-free.Further, in the process of this coatings capable of preventing from far infrared radiation of preparation, owing to mixing, the oxide of having selected different colours generates oxide mixture, regulation and control have been realized to the coatings capable of preventing from far infrared radiation color, make this coating that higher degree of blackness be arranged, have the radiation condition of similar absolute black body, improved radiance; Again further, this utility model adopts stirring ball-milling and extra-fine grinding successively mixed slurry to be ground, particle grain size reaches micro-nano scope (being generally about 100～400nm) in the coatings capable of preventing from far infrared radiation of preparation, the radiance of far infrared radiation coating can be further improved, therefore with the spectrum generator of the prepared one-tenth of this coatings capable of preventing from far infrared radiation with respect to spectrum generator of the prior art, its radiance increases substantially.

Again further, shown in the preparation method flow chart that Fig. 3 is this utility model coatings capable of preventing from far infrared radiation, in practical application, the preparation method of the spectrum generator of present embodiment can comprise:

Step 31, coatings capable of preventing from far infrared radiation is coated on the surface of electrothermal layer, to make the semi-finished product spectrum generator;

The prepared coatings capable of preventing from far infrared radiation that forms in the foregoing description can be coated on the surface of electrothermal layer in the mode of spraying, wherein this coatings capable of preventing from far infrared radiation thickness of being coated on the surface of electrothermal layer can be 150～350 μ m, and described electrothermal layer can be metal electric heating membrane, carbon fiber electrothermal plate or Muscovitum electric hot plate

Step 32, by the coatings capable of preventing from far infrared radiation of cured coated in the surface of described electrothermal layer, described semi-finished product spectrum generator is prepared into spectrum generator.

Be coated on the coatings capable of preventing from far infrared radiation on the surface of described electrothermal layer by cold curing in 24～48 hours, described semi-finished product spectrum generator is prepared into spectrum generator;

Perhaps, be coated on the coatings capable of preventing from far infrared radiation on the surface of described electrothermal layer by cold curing in 1～3 hour; By 3～10 hours described coatings capable of preventing from far infrared radiation that are coated on the surface of described electrothermal layer of curing oven, described semi-finished product spectrum generator is prepared into spectrum generator again, the control temperature of described curing oven is 40～80 ℃.

In actual applications, the detailed process of this utility model spectrum generator preparation can be:

The method of grinding, deployed coatings capable of preventing from far infrared radiation employing sprays is coated on the metal electric heating membrane substrate, to be prepared into the semi-finished product spectrum generator, general coating thickness is about 150～350 μ m, after spraying is finished, be coated on the coatings capable of preventing from far infrared radiation on the surface of described electrothermal layer by cold curing in 3 hours, put into baking oven then, again by 3 hours described coatings capable of preventing from far infrared radiation that are coated on the surface of described electrothermal layer of curing oven, described semi-finished product spectrum generator is prepared into spectrum generator, and the control temperature of described curing oven is 80 ℃.

Perhaps, the method of grinding, deployed coatings capable of preventing from far infrared radiation employing sprays is coated on the carbon fiber electrothermal plate, to be prepared into the semi-finished product spectrum generator, general coating thickness is about 150～350 μ m, after spraying is finished, be coated on the coatings capable of preventing from far infrared radiation on the surface of described electrothermal layer by cold curing in 3 hours, put into baking oven then, again by 6 hours described coatings capable of preventing from far infrared radiation that are coated on the surface of described electrothermal layer of curing oven, described semi-finished product spectrum generator is prepared into spectrum generator, and the control temperature of described curing oven is 60 ℃.

Perhaps, the method of grinding, deployed coatings capable of preventing from far infrared radiation employing sprays is coated on the Muscovitum electric hot plate, to be prepared into the semi-finished product spectrum generator, general coating thickness is about 150～350 μ m, after spraying is finished, be coated on the coatings capable of preventing from far infrared radiation on the surface of described electrothermal layer by cold curing in 2 hours, put into baking oven then, again by 5 hours described coatings capable of preventing from far infrared radiation that are coated on the surface of described electrothermal layer of curing oven, described semi-finished product spectrum generator is prepared into spectrum generator, and the control temperature of described curing oven is 70 ℃.

Perhaps, the method of grinding, deployed coatings capable of preventing from far infrared radiation employing sprays is coated on the Muscovitum electric hot plate, to be prepared into the semi-finished product spectrum generator, general coating thickness is about 150～350 μ m, after spraying is finished, be coated on the coatings capable of preventing from far infrared radiation on the surface of described electrothermal layer by cold curing in 3 hours, put into baking oven then, again by 5 hours described coatings capable of preventing from far infrared radiation that are coated on the surface of described electrothermal layer of curing oven, described semi-finished product spectrum generator is prepared into spectrum generator, and the control temperature of described curing oven is 70 ℃.

Perhaps, the method of grinding, deployed coatings capable of preventing from far infrared radiation employing sprays is coated on the carbon fiber reinforced substrate, to be prepared into the semi-finished product spectrum generator, general coating thickness is about 150～350 μ m, after spraying is finished, be coated on the coatings capable of preventing from far infrared radiation on the surface of described electrothermal layer by cold curing in 24～48 hours, described semi-finished product spectrum generator is prepared into spectrum generator.

Perhaps, the method of grinding, deployed coatings capable of preventing from far infrared radiation employing sprays is coated on the Muscovitum electric hot plate, to be prepared into the semi-finished product spectrum generator, general coating thickness is about 150～350 μ m, after spraying is finished, be coated on the coatings capable of preventing from far infrared radiation on the surface of described electrothermal layer by cold curing in 3 hours, put into baking oven then, again by 7 hours described coatings capable of preventing from far infrared radiation that are coated on the surface of described electrothermal layer of curing oven, described semi-finished product spectrum generator is prepared into spectrum generator, and the control temperature of described curing oven is 50 ℃.

In the process of the preparation spectrum generator of present embodiment, because the adhesive force that coatings capable of preventing from far infrared radiation is coated with is stronger, can be by directly coatings capable of preventing from far infrared radiation being coated on the surface of electrothermal layer, be cured by coatings capable of preventing from far infrared radiation again the surface that is coated on electrothermal layer, can be prepared into spectrum generator, compare with the technology that needs high-temperature calcination in the prior art, the coatings capable of preventing from far infrared radiation that is coated on the surface of electrothermal layer only needs lower solidification temperature, or it is promptly curable at normal temperatures, it is simple to have preparation technology, does not need the advantage of complex device; Again because characteristic such as the mechanical performance that is coated with of coatings capable of preventing from far infrared radiation is good, and it is strong to be fit to the preparation impact resistance, the spectrum generator of large-size.

Again further, analyze by experiment, comprise the anion composition owing to be prepared into the coatings capable of preventing from far infrared radiation of frequency spectrum genetic horizon 12, therefore the present embodiment spectrum generator has higher and wide radiation peak at 7.5～10.5 μ m places, and the far infrared optimal wavelength 9.6 μ m of this section radiation peak and suitable absorption of human body mate very much, can make human body obtain good assimilation effect, make the spectrum generator in the present embodiment have the effect of simulation human body biological spectrum.

It should be noted that at last: above embodiment is only in order to explanation the technical solution of the utility model but not limit it, although this utility model is had been described in detail with reference to preferred embodiment, those of ordinary skill in the art is to be understood that: it still can make amendment or be equal to replacement the technical solution of the utility model, and these modifications or be equal to replacement and also can not make amended technical scheme break away from the spirit and scope of technical solutions of the utility model.

Claims (2)

1. a spectrum generator is characterized in that, comprises electrothermal layer and frequency spectrum genetic horizon,

Described frequency spectrum genetic horizon is arranged at the surface of described electrothermal layer, and described frequency spectrum genetic horizon is coated on the surface of described electrothermal layer by coatings capable of preventing from far infrared radiation and forms.

2. spectrum generator according to claim 1 is characterized in that, described electrothermal layer is metal electric heating membrane, carbon fiber electrothermal plate or Muscovitum electric hot plate.

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