CN106911072A - Far-infrared ray generating apparatus and far infrared production method - Google Patents
Far-infrared ray generating apparatus and far infrared production method Download PDFInfo
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- CN106911072A CN106911072A CN201710109578.4A CN201710109578A CN106911072A CN 106911072 A CN106911072 A CN 106911072A CN 201710109578 A CN201710109578 A CN 201710109578A CN 106911072 A CN106911072 A CN 106911072A
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- far
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- infrared
- electromagnetic wave
- complex spectrum
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01S—DEVICES USING THE PROCESS OF LIGHT AMPLIFICATION BY STIMULATED EMISSION OF RADIATION [LASER] TO AMPLIFY OR GENERATE LIGHT; DEVICES USING STIMULATED EMISSION OF ELECTROMAGNETIC RADIATION IN WAVE RANGES OTHER THAN OPTICAL
- H01S4/00—Devices using stimulated emission of electromagnetic radiation in wave ranges other than those covered by groups H01S1/00, H01S3/00 or H01S5/00, e.g. phonon masers, X-ray lasers or gamma-ray lasers
Abstract
A kind of far-infrared ray generating apparatus and far infrared production method, complex spectrum electromagnetic wave is exported using complex spectrum electromagnetic wave generation unit, and launching complex spectrum electromagnetic wave by transmitting antenna excites far-infrared material to produce far infrared.The far-infrared ray generating apparatus that the present invention is provided are not only able to far infrared easy, efficiently needed for generation, while with simple structure, compact, advantage with low cost;The far infrared production method that the present invention is provided is not only able to far infrared easy, efficiently needed for generation, while with advantage with low cost.
Description
【Technical field】
The present invention is on a kind of far infrared technology, especially with regard to a kind of far-infrared ray generating apparatus and far infrared
Line production method.
【Background technology】
At present, far infrared technology is applied to many technical fields such as optics, communication, astronomy, military affairs, medical treatment,
Particularly in medical domain, wavelength is beneficial to human body in 4 μm~16 μm of far infrared.But common material, such as steel, skin
The wavelength that the materials such as leather, cloth are discharged in 4 μm~16 μm of far infrared normal emittance only 0.02~0.03, so not
With far-infrared health-care function.Far infrared normal emittance material higher is referred to as far-infrared material, such as tourmaline,
The materials such as medical stone, volcanic rock, far-infrared ceramic.It is currently used for emitting far-infrared method for exchange type, that is, passes through
The mode for heating far-infrared material produces far infrared.Above-mentioned exchange type produces the method for far infrared to have the following disadvantages:
1st, equipment is complicated, unsuitable portable use;2nd, in medical procedure is applied to, heat is difficult to control, and is produced when heating inadequate remote red
The effect on driving birds is not good of outside line, easily user is scalded during superheated.
【The content of the invention】
On the one hand, it is an object of the invention to provide a kind of far-infrared ray generating apparatus, excited using complex spectrum electromagnetic wave
Far-infrared material produces far infrared.
To achieve these goals, the present invention provides a kind of far-infrared ray generating apparatus, wherein, including:Complex spectrum electricity
Magnetic wave generation unit, for exporting complex spectrum electromagnetic wave, transmitting antenna, the transmitting antenna and the complex spectrum electromagnetic wave
The output end electrical connection of generation unit, far-infrared material, the far-infrared material corresponds to the surface of emission point of the transmitting antenna
Cloth is set, and the transmitting antenna is launched by being combined that the complex spectrum electromagnetic wave generation unit is exported to the far-infrared material
Frequency spectrum electromagnetic wave, the complex spectrum electromagnetic wave excites the far-infrared material to produce far infrared.
Described far-infrared ray generating apparatus, wherein, the far-infrared material is attached to the transmitting antenna by carrier
The surface of emission.
Described far-infrared ray generating apparatus, wherein, the material of the carrier is plastics or rubber or silica gel.
Described far-infrared ray generating apparatus, wherein, the transmitting antenna is made up of the low carbon steel plate through normalized treatment.
Described far-infrared ray generating apparatus, wherein, the far-infrared material is selected from:Tourmaline, medical stone, volcanic rock,
The combination of any one or more in far-infrared ceramic, and it is ground into many fine particles.
Described far-infrared ray generating apparatus, wherein, the far-infrared material is iron tourmaline powder.
Described far-infrared ray generating apparatus, wherein, the complex spectrum electromagnetic wave generation unit includes:Low-frequency oscillation
Device, for producing low frequency signal, high-frequency generator, for producing high-frequency signal, the low-frequency oscillator sequentially to electrically connect frequency dividing
Device and differential circuit, the divided device of low frequency signal that the low-frequency oscillator is produced enter after carrying out down conversion process into differential circuit
Traveling wave fractal transform, forms burst pulse;The high-frequency generator sequentially electrically connects electronic switch, bandpass filter and frequency synthesis electricity
Road;The electronic switch is electrically connected with the low-frequency oscillator, and the opening and closing of the electronic switch are controlled by low frequency signal
System is intercepted to high-frequency signal, and high-frequency signal is intercepted into a Duan Bo;The differential circuit electrically connects the frequency synthesis electricity
Road, the frequency synthesizer circuit electrically connects amplification output circuit, and the high-frequency signal is filtered through Duan Bojing band logicals between interception formation
After ripple device filters spurious signal, the burst pulse formed after treatment with low frequency signal in frequency synthesizer circuit is overlapped mixed
Frequently, low-and high-frequency complex spectrum signal is constituted, amplification output circuit is entered back into, exports compound after being amplified by amplification output circuit
Frequency spectrum electromagnetic wave.
Described far-infrared ray generating apparatus, wherein, it is additionally provided between the frequency synthesizer circuit and amplification output circuit
Amplify combiner circuit and power distributing circuit, combiner circuit, the amplification synthesis electricity are amplified in the frequency synthesizer circuit electrical connection
Road sequentially electrically connects the power distributing circuit and the amplification output circuit, the low-and high-frequency complex spectrum signal input synthesis
Amplifying circuit is amplified treatment, then adjusts different power outputs as needed through power distributing circuit, enters back into amplification defeated
Go out circuit, complex spectrum electromagnetic wave is exported after being amplified by amplification output circuit.
On the other hand, it is an object of the invention to provide far infrared production method, excited far using complex spectrum electromagnetic wave
Infra-red material produces far infrared.
To achieve these goals, the present invention proposes a kind of far infrared production method, wherein, using complex spectrum electricity
Magnetic wave generation unit exports complex spectrum electromagnetic wave, recycles the complex spectrum electromagnetic wave to excite far-infrared material to produce remote
Infrared ray.
Described far infrared production method, wherein, the complex spectrum electromagnetic wave is 50Hz~150Hz's comprising frequency
Low-frequency electromagnetic wave and frequency are the frequency electromagnetic waves of 10KHz~100KHz.
Described far infrared production method, wherein, the complex spectrum electromagnetic wave is the low-frequency electrical of 100Hz comprising frequency
Magnetic wave and frequency are the frequency electromagnetic waves of 50KHz.
Described far infrared production method, wherein, the far infrared wavelength of generation is 3 μm~21 μm.
Described far infrared production method, wherein, the complex spectrum electromagnetic wave generation unit output complex spectrum electricity
The method of magnetic wave includes:Low frequency signal is produced by low-frequency oscillator;High-frequency generator produces high-frequency signal;Electronic switch is by low
The control of frequency signal is intercepted to high-frequency signal, intercepts into a Duan Bo;The low frequency signal that the low-frequency oscillator is produced is through dividing
Frequency device carries out waveform conversion after carrying out down conversion process into differential circuit, forms burst pulse;The high-frequency signal is formed through interception
Between after Duan Bojing bandpass filters filter spurious signal, it is narrow with what low frequency signal was formed after treatment in frequency synthesizer circuit
Pulse is overlapped mixing, constitutes low-and high-frequency complex spectrum signal, enters back into output after amplification output circuit is amplified compound
Frequency spectrum electromagnetic wave.
Described far infrared production method, wherein, the low-and high-frequency complex spectrum signal is entering amplification output circuit
Before, first input synthesis amplifying circuit is amplified treatment, then adjusts different output works as needed through power distributing circuit
Rate, finally enters amplification output circuit, and complex spectrum electromagnetic wave is exported after being amplified by amplification output circuit.
Described far infrared production method, wherein, the far-infrared material is selected from:Tourmaline, medical stone, volcanic rock,
The combination of any one or more in far-infrared ceramic, and it is ground into many fine particles.
Described far-infrared ray generating apparatus, wherein, the far-infrared material is iron tourmaline powder.
With reference to above-mentioned, the far-infrared ray generating apparatus that the present invention is provided are not only able to remote needed for easy, efficient generation
Infrared ray, while with simple structure, compact, advantage with low cost;The far infrared generation side that the present invention is provided
Method is not only able to far infrared easy, that efficient generation is required, while with advantage with low cost.In addition, of the invention
Can also be by controlling the power output of complex spectrum electromagnetic wave, so as to the generation of the demand modeling far infrared according to user
State.
【Brief description of the drawings】
Fig. 1 is far-infrared ray generating apparatus external structure schematic diagram of the invention.
Fig. 2A is that the transmitting antenna of far-infrared ray generating apparatus of the invention and the cross-section structure amplification of radiation base junction conjunction are shown
It is intended to.
Fig. 2 B are the cross-section structure enlarged diagram of the transmitting antenna with radiation base junction conjunction of another embodiment of the present invention.
Fig. 3 is the complex spectrum electromagnetic wave generation unit structure block diagram of far-infrared ray generating apparatus of the invention.
【Specific embodiment】
The present invention is described in detail with reference to the accompanying drawings and detailed description.
Fig. 1 shows a preferred embodiment of far-infrared ray generating apparatus of the invention.As shown in figure 1, remote red
Outer beam generating apparatus include complex spectrum electromagnetic wave generation unit 10 and transmitting antenna 30, complex spectrum electromagnetic wave generation unit 10
Can be complex spectrum electromagnetic wave generator, the power supply of complex spectrum electromagnetic wave generation unit 10 can access mains supply, multiple
Electrically connected by connecting line 20 between the output end and transmitting antenna 30 of sum of fundamental frequencies spectrum electromagnetic wave generation unit 10, so that by compound frequency
Complex spectrum electromagnetic wave produced by spectrum electromagnetic wave generation unit 10 is transferred to transmitting antenna 30, and outside by transmitting antenna 30
Transmitting.The shell of complex spectrum electromagnetic wave generation unit 10 is provided with switch 11, single for selecting complex spectrum electromagnetic wave to produce
At least two gear buttons 12 of first 10 power outputs and for showing the working condition of complex spectrum electromagnetic wave generation unit 10
Display screen 13.In the present embodiment, the surface of emission of transmitting antenna 30 is attached with the carrier 40 that silica gel material is made, and carrier 40 is carried
There is far-infrared material particle, so as to form radiation base 41.The far-infrared material that the present embodiment is used is passed through for natural iron tourmaline
The iron tourmaline particle 50 of grinding.Exist in nature and be rich in Fe3+、Fe2+(FeO+Fe2O3) iron tourmaline (also known as:It is black
Color tourmaline).The above embodiment of the present invention excites iron tourmaline particle 50 to produce far infrared using complex spectrum electromagnetic wave.
Iron tourmaline particle 50 of the invention is obtained by the way that iron tourmaline to be ground to the fine particle of 25~150 μm of diameter, preferably
The particle diameter of iron tourmaline particle 50 be about 48 μm.Generally, the aggregate of discrete particle of the size less than 1mm is properly termed as
Powder, therefore the far-infrared material that above-described embodiment is used is iron tourmaline powder.
The present invention produces far infrared by the way of complex spectrum electromagnetic wave excites far-infrared material, and this mode is not limited
In exciting the iron tourmaline particle 50, far-infrared material therein can be selected from tourmaline, medical stone, fire with complex spectrum electromagnetic wave
The combination of any one or more in mountain rock, far-infrared ceramic, and it is ground into many fine particles or powder.
Fig. 2A is that the transmitting antenna 30 of far-infrared ray generating apparatus of the invention is put with the radiation cross-section structure that is combined of base 41
Big schematic diagram.As shown in Figure 2 A, in the above-described embodiments, transmitting antenna 30 is made up of iron plate, it is preferred that use mild steel
Plate makes transmitting antenna 30.The steel plate can be No. 08 steel plate, and steel plate is after normalized treatment, steel plate ferrite and pearly-lustre
Body is evenly distributed, so as to obtain more preferable launching effect.The carrier 40 is silica gel material, in the fabrication process, by many iron
Tourmaline particle 50 is uniformly mixed in liquid-state silicon gel material, uniform solidify afterwards shaping to be mixed, makes 50 points of iron tourmaline particle
Cloth forms the radiation base 41 of sheet in carrier 40, and radiation base 41 is covered in the surface of emission of transmitting antenna.In the present invention
State in embodiment, distribution density of the iron tourmaline particle 50 in base 41 is radiated is preferably 0.15g/cm3~0.5g/cm3, radiation
There is the gap for being enough to transmit far infrared between the molecule of the iron tourmaline particle 50 in base 41, therefore, it can permit
Perhaps far infrared is smoothly excited.When the present invention is implemented, plastics, rubber, or the material such as silica gel can be used as carrier 40.
Embodiments of the invention solidify to form piece during above-mentioned far-infrared material powder can be mixed uniformly the above-mentioned carrier 40 of liquid
The radiation base 41 of shape, and radiation base 41 is covered in the surface of emission of transmitting antenna 30, then specifically, can be above-mentioned remote red
Outer material powder solidify to form the radiation base 41 of sheet in uniformly mixing the silica gel of liquid, and radiation base 41 is covered in
The surface of emission of transmitting antenna 30.Another embodiment of the present invention can also be pasted powdered far-infrared material using latex
The surface of emission of transmitting antenna 30, is faced out by the transmitting of transmitting antenna 30 and sequentially forms emulsion layer and far-infrared material layer.
As shown in Figure 2 A, transmitting antenna 30 is shaped as rectangle in the above-described embodiments, but can also be according to actual need
The shape such as circular, oval is designed, and carrier 40 can be designed to and transmitting antenna 30 according to the shape of transmitting antenna 30
Shape that is corresponding or matching, it is also possible to be greater than any shape of the area of transmitting antenna 30, transmitting day is enveloped completely
The surface of emission of line 30 and side, even extend to the back side of transmitting antenna 30.As shown in Figure 2 A, the radiation base 41 is arranged on hair
The surface of emission of antenna 30 is penetrated, the iron tourmaline particle 50 in radiation base 41 is launched the complex spectrum that antenna 30 is launched
Electromagnetic wave excites generation far infrared.Due to 30 one-tenth tabulars of transmitting antenna of the invention, radiation base 41 is attached to transmitting antenna
30 surface of emission, overall radioactive department point be designed to it is open, therefore, the far infrared of generation can be towards the hair of transmitting antenna 30
Penetrate all directions square in front into radioactive emission.As shown in Figure 2 B, in another embodiment, the back side of transmitting antenna 30 may be used also
To set the coating 60 of the sheet that one layer of silica gel material is made, so as to coordinate the radiation base 41 of sheet by the transmitting antenna of sheet
30 are coated between coating 60 and radiation base 41, so as to be protected to transmitting antenna 30, it is to avoid transmitting antenna 30 is subject to draw
Wound is corroded.
Fig. 3 is the complex spectrum electromagnetic wave generation unit structure block diagram of far-infrared ray generating apparatus of the invention.
As shown in figure 3, in the above-described embodiments, the complex spectrum electromagnetic wave generation unit 10 includes:Low-frequency oscillator 101, high frequency
Oscillator 102, the low-frequency oscillator 101, high-frequency generator 102 can be by the power supplys of complex spectrum electromagnetic wave generation unit 10
Power supply, the power supply is opened and closed by the control of switch 11, and the low-frequency oscillator 101 sequentially electrically connects frequency divider 104 and micro-
Parallel circuit 105;The high-frequency generator 102 sequentially electrically connects electronic switch 103, bandpass filter 106 and frequency synthesizer circuit
107;The electronic switch 103 is electrically connected with the low-frequency oscillator 101, and the electronic switch 103 opening and closing
The low frequency signal control exported by low-frequency oscillator 101;The differential circuit 105 electrically connects the frequency synthesizer circuit 107, institute
State the electrical connection of frequency synthesizer circuit 107 and amplify combiner circuit 108, the amplification combiner circuit 108 sequentially electrically connects power distribution
Circuit 109 and amplification output circuit 110.The method that the complex spectrum electromagnetic wave generation unit 10 exports complex spectrum electromagnetic wave
Including:Low frequency signal is produced by low-frequency oscillator 101, low frequency signal waveform in the present embodiment is square wave, frequency can be
100Hz~300Hz;High-frequency generator 102 produces high-frequency signal, and the high-frequency signal waveform in the present embodiment is square wave, and frequency can
With in 10KHz~100KHz;Electronic switch 103 is intercepted by the control of low frequency signal to high-frequency signal, and high-frequency signal is cut
Take into a Duan Bo;The divided device 104 of low frequency signal that the low-frequency oscillator 101 is produced enters differential electricity after carrying out down conversion process
Road 105 carries out waveform conversion, forms burst pulse, and the frequency of the low frequency signal after being processed through frequency reducing (two divided-frequency) in the present embodiment can
Think 50Hz~150Hz;The high-frequency signal through interception formed between after Duan Bojing bandpass filters 106 filter spurious signal,
The burst pulse formed after treatment with low frequency signal in frequency synthesizer circuit 107 is overlapped mixing, and composition low-and high-frequency is combined
Spectrum signal, input synthesis amplifying circuit 108 is amplified treatment, and the complex spectrum electromagnetic wave after enhanced processing is through power distribution
Circuit 109 enters back into amplification output circuit 110 according to different power outputs are adjusted the need for user, by amplifying output electricity
Road 110 exports complex spectrum electromagnetic wave after being amplified.
Far infrared production method of the invention mainly uses complex spectrum electromagnetic wave to excite far-infrared material (for example:
Iron tourmaline powder) far infrared is produced, and complex spectrum electromagnetic wave can utilize above-mentioned complex spectrum electromagnetic wave to produce list
Unit 10 obtains.It is compound that far infrared production method of the invention mainly uses complex spectrum electromagnetic wave generation unit 10 to export
Frequency spectrum electromagnetic wave, recycles the complex spectrum electromagnetic wave to excite far-infrared material particle to produce far infrared.Using this hair
During bright above-mentioned far-infrared ray generating apparatus, it is possible to use the transmitting antenna electrically connected with complex spectrum electromagnetic wave generation unit 10
30, complex spectrum electromagnetic wave is sent by transmitting antenna 30, excite far-infrared material particle to produce far infrared.Meanwhile, this
Invention can also launch the complex spectrum electricity of varying strength by controlling the power output of complex spectrum electromagnetic wave generation unit 10
Magnetic wave, so as to control the intensity of far infrared for inspiring.
Far infrared generation efficiency is improved in order to significant, far infrared production method of the invention is multiple by adjustment
Sum of fundamental frequencies spectrum electromagnetic wave generation unit 10 is electric by the complex spectrum of low-frequency electromagnetic wave and frequency electromagnetic waves superposition mixing to obtain
Magnetic wave, in an embodiment of the present invention the complex spectrum electromagnetic wave can be by frequency for 50Hz~150Hz low frequency electromagnetic
Ripple and frequency are formed for the frequency electromagnetic waves of 10KHz~100KHz are superimposed mixing, therefore are the low of 50Hz~150Hz comprising frequency
Frequency electromagnetic waves and frequency are the frequency electromagnetic waves of 10KHz~100KHz;And in more preferably embodiment, complex spectrum electromagnetism
Ripple is formed for the frequency electromagnetic waves of 50KHz are superimposed mixing by low-frequency electromagnetic wave and frequency that frequency is 100Hz, therefore comprising frequency
Rate is the frequency electromagnetic waves of 50KHz for the low-frequency electromagnetic wave and frequency of 100Hz.After testing, the present invention can excite generation wavelength
It is 3 μm~21 μm far infrareds, particularly through meeting GB/T 4654-2008《The general skill of nonmetal basal body infrared radiation heater
Art condition》With GB/T 7287-2008《Infrared radiation heater test method》The detection method of standard, measuring the present invention can
Efficiently significant to produce the far infrared that wavelength is 8 μm~10 μm, normal emittance is 0.88, and above-mentioned wave-length coverage exists with human body
The far infrared wave-length coverage launched under normality is roughly the same, therefore, far-infrared ray generating apparatus of the invention and far infrared
Line production method can apply to medical technology and for being made Medical Devices.
The above, greatly only presently preferred embodiments of the present invention does not limit the scope of present invention implementation, i.e., with this
All simple equivalence changes made according to claims of the present invention and description and modification, all still belong to patent of the present invention and contain
In the range of lid.
Claims (16)
1. a kind of far-infrared ray generating apparatus, it is characterised in that including:
Complex spectrum electromagnetic wave generation unit, for exporting complex spectrum electromagnetic wave,
Transmitting antenna, the transmitting antenna is electrically connected with the output end of the complex spectrum electromagnetic wave generation unit,
Far-infrared material, the transmitting EDS maps that the far-infrared material corresponds to the transmitting antenna are set,
The transmitting antenna launches the compound frequency exported by the complex spectrum electromagnetic wave generation unit to the far-infrared material
Spectrum electromagnetic wave, the complex spectrum electromagnetic wave excites the far-infrared material to produce far infrared.
2. far-infrared ray generating apparatus as claimed in claim 1, it is characterised in that the far-infrared material is adhered to by carrier
In the surface of emission of the transmitting antenna.
3. far-infrared ray generating apparatus as claimed in claim 2, it is characterised in that the material of the carrier is plastics or rubber
Glue or silica gel.
4. far-infrared ray generating apparatus as claimed in claim 1, it is characterised in that the transmitting antenna is by through normalized treatment
Low carbon steel plate be made.
5. far-infrared ray generating apparatus as claimed in claim 1 or 2, it is characterised in that the far-infrared material is selected from:Electrically
The combination of any one or more in stone, medical stone, volcanic rock, far-infrared ceramic, and it is ground into many fine particles.
6. far-infrared ray generating apparatus as claimed in claim 5, it is characterised in that the far-infrared material is iron tourmaline powder
End.
7. far-infrared ray generating apparatus as claimed in claim 1, it is characterised in that the complex spectrum electromagnetic wave generation unit
Including:
Low-frequency oscillator, for producing low frequency signal,
High-frequency generator, for producing high-frequency signal,
The low-frequency oscillator sequentially electrically connects frequency divider and differential circuit, and the low frequency signal that the low-frequency oscillator is produced is through dividing
Frequency device carries out waveform conversion after carrying out down conversion process into differential circuit, forms burst pulse;
The high-frequency generator sequentially electrically connects electronic switch, bandpass filter and frequency synthesizer circuit;The electronic switch with
The low-frequency oscillator electrical connection, the opening and closing of the electronic switch are cut by the control of low frequency signal to high-frequency signal
Take, high-frequency signal is intercepted into a Duan Bo;
The differential circuit electrically connects the frequency synthesizer circuit, and the frequency synthesizer circuit electrically connects amplification output circuit,
The high-frequency signal through interception formed between after Duan Bojing bandpass filters filter spurious signal, in frequency synthesizer circuit
The burst pulse formed after treatment with low frequency signal is overlapped mixing, constitutes low-and high-frequency complex spectrum signal, enters back into amplification
Output circuit, exports complex spectrum electromagnetic wave after being amplified by amplification output circuit.
8. far-infrared ray generating apparatus as claimed in claim 7, it is characterised in that the frequency synthesizer circuit is exported with amplifying
Amplification combiner circuit and power distributing circuit are additionally provided between circuit, combiner circuit is amplified in the frequency synthesizer circuit electrical connection,
The amplification combiner circuit sequentially electrically connects the power distributing circuit and the amplification output circuit, the compound frequency of the low-and high-frequency
Spectrum signal input synthesis amplifying circuit is amplified treatment, then adjusts different output works as needed through power distributing circuit
Rate, enters back into amplification output circuit, and complex spectrum electromagnetic wave is exported after being amplified by amplification output circuit.
9. a kind of far infrared production method, it is characterised in that
Complex spectrum electromagnetic wave is exported using complex spectrum electromagnetic wave generation unit, recycles the complex spectrum electromagnetic wave to excite
Far-infrared material produces far infrared.
10. far infrared production method as claimed in claim 9, it is characterised in that the complex spectrum electromagnetic wave includes frequency
Rate is the frequency electromagnetic waves of 10KHz~100KHz for the low-frequency electromagnetic wave and frequency of 50Hz~150Hz.
11. far infrared production methods as claimed in claim 10, it is characterised in that the complex spectrum electromagnetic wave includes frequency
Rate is the frequency electromagnetic waves of 50KHz for the low-frequency electromagnetic wave and frequency of 100Hz.
12. far infrared production methods as claimed in claim 9, it is characterised in that the far infrared wavelength of generation is 3
μm~21 μm.
13. far infrared production methods as claimed in claim 9, it is characterised in that the complex spectrum electromagnetic wave produces single
The method of unit's output complex spectrum electromagnetic wave includes:Low frequency signal is produced by low-frequency oscillator;High-frequency generator produces high frequency
Signal;Electronic switch is intercepted by the control of low frequency signal to high-frequency signal, intercepts into a Duan Bo;The low-frequency oscillator is produced
The divided device of raw low frequency signal carries out waveform conversion after carrying out down conversion process into differential circuit, forms burst pulse;The height
Frequency signal through interception formed between after Duan Bojing bandpass filters filter spurious signal, with low frequency signal in frequency synthesizer circuit
The burst pulse formed after treatment is overlapped mixing, constitutes low-and high-frequency complex spectrum signal, enters back into amplification output circuit and enters
Row exports complex spectrum electromagnetic wave after amplifying.
14. far infrared production methods as claimed in claim 13, it is characterised in that the low-and high-frequency complex spectrum signal exists
Into before amplification output circuit, first input synthesis amplifying circuit is amplified treatment, then through power distributing circuit as needed
The different power output of adjustment, finally enters amplification output circuit, and complex spectrum is exported after being amplified by amplification output circuit
Electromagnetic wave.
15. far infrared production methods as claimed in claim 9, it is characterised in that the far-infrared material is selected from:Electrically
The combination of any one or more in stone, medical stone, volcanic rock, far-infrared ceramic, and it is ground into many fine particles.
16. far infrared production methods as claimed in claim 15, it is characterised in that the far-infrared material is iron tourmaline
Powder.
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| CN201710109578.4A CN106911072B (en) | 2017-02-27 | 2017-02-27 | Far infrared ray generating device and far infrared ray generating method |
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| CN201710109578.4A CN106911072B (en) | 2017-02-27 | 2017-02-27 | Far infrared ray generating device and far infrared ray generating method |
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| US5107126A (en) * | 1987-08-22 | 1992-04-21 | Shusuke Yano | Far infrared generator |
| JPH1133074A (en) * | 1997-07-16 | 1999-02-09 | Nippon Mizushiyori Giken:Kk | Method and device for promoting health using far infrared ray |
| WO2010067979A2 (en) * | 2008-12-08 | 2010-06-17 | Kim Han Woo | Radiation apparatus for far infrared revolving electromagnetic waves |
| CN101745185A (en) * | 2008-12-18 | 2010-06-23 | 潘欣祥 | Energy resonance spectrometer |
| JP2013228401A (en) * | 2013-06-21 | 2013-11-07 | Oki Denki Bosai Kk | Flame monitoring device |
| CN204485098U (en) * | 2015-03-12 | 2015-07-22 | 青岛绿频环保科技有限公司 | A kind of far infrared spectrum bucket |
| CN204485099U (en) * | 2015-03-12 | 2015-07-22 | 青岛绿频环保科技有限公司 | A kind of far infrared frequency spectrum physical therapy band |
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2017
- 2017-02-27 CN CN201710109578.4A patent/CN106911072B/en active Active
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| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US5107126A (en) * | 1987-08-22 | 1992-04-21 | Shusuke Yano | Far infrared generator |
| US4935633A (en) * | 1988-10-11 | 1990-06-19 | Bio-Rad Laboratories, Inc. | Low power infrared source assembly for spectrometer |
| JPH1133074A (en) * | 1997-07-16 | 1999-02-09 | Nippon Mizushiyori Giken:Kk | Method and device for promoting health using far infrared ray |
| WO2010067979A2 (en) * | 2008-12-08 | 2010-06-17 | Kim Han Woo | Radiation apparatus for far infrared revolving electromagnetic waves |
| CN101745185A (en) * | 2008-12-18 | 2010-06-23 | 潘欣祥 | Energy resonance spectrometer |
| JP2013228401A (en) * | 2013-06-21 | 2013-11-07 | Oki Denki Bosai Kk | Flame monitoring device |
| CN204485098U (en) * | 2015-03-12 | 2015-07-22 | 青岛绿频环保科技有限公司 | A kind of far infrared spectrum bucket |
| CN204485099U (en) * | 2015-03-12 | 2015-07-22 | 青岛绿频环保科技有限公司 | A kind of far infrared frequency spectrum physical therapy band |
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| Publication number | Publication date |
|---|---|
| CN106911072B (en) | 2023-05-09 |
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