KR20110044117A - Functional energy manufacturing method - Google Patents
Functional energy manufacturing method Download PDFInfo
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- KR20110044117A KR20110044117A KR1020090101522A KR20090101522A KR20110044117A KR 20110044117 A KR20110044117 A KR 20110044117A KR 1020090101522 A KR1020090101522 A KR 1020090101522A KR 20090101522 A KR20090101522 A KR 20090101522A KR 20110044117 A KR20110044117 A KR 20110044117A
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- C—CHEMISTRY; METALLURGY
- C04—CEMENTS; CONCRETE; ARTIFICIAL STONE; CERAMICS; REFRACTORIES
- C04B—LIME, MAGNESIA; SLAG; CEMENTS; COMPOSITIONS THEREOF, e.g. MORTARS, CONCRETE OR LIKE BUILDING MATERIALS; ARTIFICIAL STONE; CERAMICS; REFRACTORIES; TREATMENT OF NATURAL STONE
- C04B35/00—Shaped ceramic products characterised by their composition; Ceramics compositions; Processing powders of inorganic compounds preparatory to the manufacturing of ceramic products
- C04B35/01—Shaped ceramic products characterised by their composition; Ceramics compositions; Processing powders of inorganic compounds preparatory to the manufacturing of ceramic products based on oxide ceramics
- C04B35/16—Shaped ceramic products characterised by their composition; Ceramics compositions; Processing powders of inorganic compounds preparatory to the manufacturing of ceramic products based on oxide ceramics based on silicates other than clay
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- C—CHEMISTRY; METALLURGY
- C04—CEMENTS; CONCRETE; ARTIFICIAL STONE; CERAMICS; REFRACTORIES
- C04B—LIME, MAGNESIA; SLAG; CEMENTS; COMPOSITIONS THEREOF, e.g. MORTARS, CONCRETE OR LIKE BUILDING MATERIALS; ARTIFICIAL STONE; CERAMICS; REFRACTORIES; TREATMENT OF NATURAL STONE
- C04B2103/00—Function or property of ingredients for mortars, concrete or artificial stone
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- C04B2103/0097—Anion- and far-infrared-emitting materials
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Abstract
Description
The present invention is to develop a functional energy, mechanism function, improved composition comprising the igneous rock and tourmaline improved far-infrared radiation and power of the liquid body, and the present invention is energy resource function, technology, consumption of oil, gas, electricity, etc. , Electromagnetic radiation, radiation, excitation, vibration, and condensation of 60% of silicon and components of igneous rocks and fine powders, re-radiation, and physicochemical, electromagnetic, and chemical And natural heat and radiation of elemental components, and as a carrier of tourmaline fine powder, it is easy to use as piezoelectric effect, thermoelectric effect, and conversion function of semi-permanent DC power electrode material, and to increase the mineral size and mineral strength. Long lifespan and environmentally safe energy resources, development and functional technology and development, and multi-use and multi-functionality of functional liquids and dry powders relates to the composition manufactured product of the present invention to be.
The highly functional far-infrared radioactive composition of the liquid body (Patent 10-0340804) has a particle size of 40 nanoparticles, a hydrothermal pressure, and a synthetic technique, which is composed of hydrous components, aluminum silicate zirconia tetrachloride, titanium ions, silver, and additives. It is -12 microns
Functionality is due to far-infrared radiation, action due to composition and composition of electromagnetic waves, radiation, photoelectrons, emission, structural molecules, excitation, resonant action, thermoelectric conversion and physical and chemical adsorption due to composition, ion exchange, potential difference , Electrode, photoelectron / absorber radiation, self-heating and conduction
This is the peptizing, dispersing, and mixing functional properties of the composition and mixed additives, which are made into the basic energy source properties.
All the physical properties and igneous rock particle properties are coarse minerals, including basalt, granite, hornblende, feldspar, feldspar, etc. of igneous rocks of ceramics and raw materials, 30% colored minerals of 60% silicic acid of acid, alkali, and neutral rock. Among the components, silicon is composed of adsorption, agglomeration, re-spinning, titanium, photocatalyst, aluminum, adsorption, electrode, iron oxide, direct current, magnetic, iron, magnetic, magnesium, magnetic, potassium, phosphorus-natural radioactive electrons, phase and magnetic, It is a natural semi-permanent power source and energy property of piezoelectric, electron and chemical.
Literature, Foreign Materials, Ceramics and Raw Minerals in the Average Chemical Composition of the Igneous Rock Component Comparison
About the magnetic properties and the electromagnetic waves of pi, hwa, electron and hwa As a carrier, the nickel and nickel ions are used as a carrier and liquid far-infrared radiation. To gain.
In addition, the nature of the igneous rock, the electromagnetic radiation of the natural radioactivity of the phase, magnetic potassium, phosphorus, etc., the high functionality of the four-quadrate to the energy function of the adsorption, condensation, re-radiative function of silicon, component 60%.
Far-infrared radiation is known to emit 95% at high temperatures.
Distribution of composition minerals in igneous rock
The power and power generation properties are a tourmaline, hexagonal, and crystalline structure, which flows electrons from the negative electrode to the positive electrode continuously from the dielectric to the positive electrode, and is a natural semi-permanent DC power generation property of the piezoelectric thermal and electrical effects. Silicate 45, lime 16, boron 16, soluble boron 8, sodium 5, potassium 4 and hardness 7 to 7.5 Mohs, electrical conductivity, conductivity 20 ° C.012 m g / cm,
Tourmaline Features-Extremely sensitive to physical and chemical changes in crystals, mechanical displacement, magnetic field, temperature change, piezoelectric, thermoelectric, electromotive force of crystal structure and paramagnetic and far infrared radiation.
1) Piezoelectric effect- The distance of positive and negative ions in the direction of the polar axis of the crystal is charged according to the change in pressure or temperature.
2) Pyroelectric effect-Light, electrons, and radiant heat are charged positively to the pointed side of the tourmaline than the other side of the crystal.
3) Thermoelectric effect- When two kinds of conductors are joined together, one closed circuit is made, and the temperature of the junction of two metals is changed, electricity flows through the circuit.
4) The same phenomenon occurs when the two metals have different temperatures. 2 When the junction is cooled, current flows in the opposite direction.
5) Thermoelectrics are extremely sensitive to physical and chemical changes in crystal lattice.
Tourmaline Particle Conductive Carrier Function- Promotes conductivity and alternating magnetic properties, and converts elemental compounds such as silver, iron, or nickel to the crystal grains during purification to enhance the function of heat and electricity in the tourmaline particles. Composition with a carrier.
Piezoelectric, pyroelectric, electromechanical and thermoelectric effects are based on the properties of tourmaline, liquid, and igneous rock particles, absorbing light, electrons, and radiant heat in a sealed enclosure at high and low temperatures. Becomes the basic principle of
Functional Properties of Elemental Compounds in Functional Energy Materials
1) Properties of power source-Self-luminous, natural cleavage and alpha
Selenium, thorium oxide, strolium oxide
2) Magnetic element-magnetic force effect
Zinc, Nickel, Iron, Cobalt, Magnesium, etc.
3) Conductive material element- Conduction effect
Gold, Silver, Copper, Iron, Aluminum, Iridium, Zinc, Nickel, etc.
4) Thermoelectric element-thermal conduction effect
Selenium, tellurium, rhodium, buzzmouth, antimony, etc.
5) Thermal element-thermal conduction effect
Copper, Chrome, Manganese, Iron, Nickel, Selenium
6) Cold water property element-low temperature effect
Antimony, molybdenum, zinc, iron, potassium, phosphorous etc.
Purify the nanoparticles of the above-mentioned element compound framework, and add products by use as ions, hydroxides, water-containing compounds, etc. by application, coating, liquid, coating, coating, etc. to provide.
Application of lattice function structural material properties of each energy body
1) Power grid conductive material-Forima electrostatic, chemical fiber, plastic, pole grid,
Resin fiber, braided mesh, pole plate, porima, etc.
2) Positive pole (+) pole-pole pole over pole pole
Plastic lattice, resin fiber, braided mesh, polyma, film
3) Pole terminal-Pole cloth or coating
Conductive Silver, Copper, Pole, Aluminum Plate, Compression Strip, Solder, Tin Bonding
4) Negative pole body (-) pole-pole body, protrusion phase, pole body
Plastic material lattice, Resin fiber, Braided mesh, Porima, Film
Prize
5) Cutlet-Unporous Eponite Plate, Film, Porima Functional, Thermal Only
Cold and cold vinyl chloride, unheated plastic plates,
6) Inner packaging-Vinyl Jube phase, cold film
Film, functional film, functional sedimentation coating
7) Outer packaging-metal, cam or jujube
Protective, functional coating, foil and juve heat, compression sealing
Constituent Tablets of the Invention
Purification of hardness of 7 to 7.5 Mohs of 0.2 mm particles of sulfur rock and fine powder and 0.4 mm particles of tourmaline and fine powder
A fine amount of fine powder is added to pure or acidic water, and the lactic acid, nitric acid, hydrochloric acid, and dispersion of mine are set at concentrations of 20 to 30, followed by aging for 4 to 6 hours depending on the particle size of hot water, followed by hydrolysis or neutral filtration, Wash and dry to obtain particles.
The purified particle name is 10-100 nm.
It is also used to make particles of nano size
A suspension of pure water or normal water is added to adjust the pH of the mineral, lactic acid, nitric acid, hydrochloric acid, hydrofluoric acid, etc. to PH1-2, and the hot water agitation is aged for 2-4 hours, and then adjusted to PH7.0 with sodium hydroxide, followed by filtration, washing and drying.
Next, the obtained product was added with acidic water or pure water, sodium hydroxide, etc., in suspension to form a pH 12-13. After neutralization PH7.0, filtration, washing and drying give particles.
The particle size is 10 to 100 nm in the particle size determined by X-ray powder method or electron microscopic observation.
Purification of the elemental compound is suitable for the compound soluble in water such as lactate and chloride.
Physical Particle Purification Management Method
As alkali used for neutralization, sodium hydroxide, potassium hydroxide, anmonium carbonate, anmonia, amines are used.
Purification Temperature-Room Temperature ~ 80 ℃ Drying Temperature-140 ℃ ~ 180 ℃
Gel phase temperature-180 ℃ ~ 230 ℃ Powder drying-230 ℃ ~ 300 ℃
Oxidation, firing temperature-300 ℃ ~ 500 ℃ is suitable
Acid concentration-0.05-2 regulation 0.01-10 regulation
0.1-30 rule
Less than the regulations or more difficult to achieve
Aging aging of the mixture is required depending on size particle and concentration
The particle size is calculated by X-ray calculation method at 10 to 200 nm, 10 to 100 nm, and 5 to 20 nm.
Electron microscopy observation. The size of the purification process is refined depending on the application.
Table 1 below shows examples of particle size effects.
When the particle diameter of 0 120A or less particles, the increase in the yield is shown by the effect of the size. It is a particle effect
Functional effect of the present invention
1) Light, electrons, radiation, radiation, cardiac calendar, molecular excitation, resonance due to electromagnetic waves 4-12 microns of liquid body (Patent 10-0340804)
Due to the properties of physical properties-high-temperature, low-temperature circulation in electronics, radiation, absorption, radiation, re-radiation, and sealing
2) Light, electrons, radiation, cardiac calendar, molecular excitation, and resonance due to 6-12 microns of igneous rock particle function
Phase DC properties of magnetic properties, phases, magnetic emissions, pies of magnetic and electromagnetic waves, direct current of electromagnetic emission properties, magnetic emission, alternating current of carrier
Natural radioactivity of potassium, phosphorus component, electron emission, silicon, 60% absorption, condensation, respinning (condenser-like), high temperature, low temperature energy circulation, promotion effect of carrier
3) Natural electrode current generation with tourmaline particle function, current 1.5 ~ 8 electron bold, piezoelectric effect, electromotive force effect, thermoelectric conversion effect
Conductivity promoting effect of carrier
4) Functional energy body-igneous rock particle liquid body, liquid body particle, tourmaline particle A mixed functional body by use of liquids.Olso-liquid body and meta-dry powder. Explanation, promotion of health, resuscitation, growth, sterilization, insecticide, surface activity, water, waste / purification, mechanism / decomposition thermoronium, ionization, radiation waste purification, biological / leading generation, etc.
5) Functional energy electromotive force / causation-electromotive force generator, heat generator, and conversely, cooling transducer function of light, electron, radiant heat, pie, pyroelectric, and tourmaline function changer of physical properties without moving parts
6) Functional Energy Mechanism Power Generation, Cause-Mechanism, Generator, Battery, Battery, Direct Generator, Parallel Generator, Multiple Generator, Parallel Charge Generator, Laminated Generator, Combined Generator, Lamination / Combination, Coupling Whole, mechanism, heating body Mechanism, cold body
Hard Pump / Amplification for Shape Structure
Mechatronics-Motors & Functional Three-Stage Structure
Conventional liquid manufacturing method [Patent 10-0340804] has functions such as electromagnetic radiation radiation, electromagnetic radiation re-radiation, ion exchange adsorption, etc. due to the far infrared electromagnetic wave and composition.
In the development of liquid phase manufacturing patent, the voltage of electromagnetic wave of basic physical property is about 0.8 volt energy function is weak and the use is limited, and this development is to provide the development of functional energy properties.
As a means of the present invention, the present invention has developed a conventional refining technology to treat the igneous rock fine powder and tourmaline fine powder in the mine and alkali process to obtain the hydro-hydraulic refining and characteristics, and to refine the characteristics of the mineral and alkali The functional improvement technology has been developed by the hydrothermal treatment, and the piezoelectric effect using piezoelectric, electrochemical function conjugate, natural radioactive electron and function of potassium and phosphorus, etc. Electromotive effect The thermoelectric effect function is developed by developing energy mechanism, thermoelectric heating, thermoelectric and cold / hot function function without any working part, and developing technology of cultural life aspect energy body with olso-liquid body and meta-dry powder body.
In addition, the functional energy effect is to provide various commercialization of new technology energy development as a multi-functional body of purification effect and element and compound refining carrier technology developed physically as one of direct conversion of energy such as solar cell, fuel cell and electronic power generation.
Reference example-Foreign, Patent Publication 3.0.11.95 among the functions of photocatalyst and titanium oxide product removal effect that affects human body and life
In order to achieve the object of the present invention, the present invention provides a method for producing a functional energy body, including liquid body, igneous rock physical properties, tourmaline particle properties, and the like.
The present invention will be described in detail.
According to the present invention
Exemplary embodiments of the present invention purify igneous rock fine powder and tourmaline fine powder, except for liquids having a physical composition (particles No. 10-0340804).
The igneous rock fine powder and tourmaline fine powder have the same hardness as the ore hardness of 7.0 to 7.5 mos.
Example 1 100 to 200 grams of igneous rock fine powder is suspended in purified water or 1 to 2 liters of acid, and hydrochloric acid and hydrofluoric acid are stirred at 10 to 30 specified PH1 to 1.5 and hydrothermal agitated to maintain room temperature to 60 ° C, depending on the particle size. After 12 hours of stirring and aging, hydrolysis or neutralization is carried out to obtain a liquid / gel by filtration and washing. The temperature is adjusted at 180 to 230 ° C to partially evaporate water.
Or when dried at 300 degreeC, a dry powder phase is obtained.
The particle size is calculated by X-ray powder method or by electron microscope observation.
Example 2 Purification to Make Particles Small
The granite and the produced particles are suspended in purified or acidic water and hot water stirred at room temperature to 60 ° C., adjusted to lactic acid, sulfuric acid, and other minerals, PH 1.0 to 1.5, and stirred for 2 to 4 hours. After pH neutralization by adding ammonia water or hydrolysis, purified water was added, and the mixture was stirred by hot water with a turbid solution. Sodium hydroxide was added. After 4 to 12 hours, lactic acid and sulfuric acid are added to the mixture to obtain a neutral liquid, followed by filtration, washing, and drying.
Or at 300 degreeC, the produced particle | grains of the "ignition rock particle" or "tourmaline particle" of a dry powder are obtained.
The particle size can be calculated by X-ray powder method or by electron microscope observation.
Example 3-Purification of fine particles of elements and compounds It is usually used as fine particles purified from water and compounds by mineral acid and alkali.
Purification of elements and compounds is preferably water-soluble compounds such as lactates and chlorides.
It is applied as an element and a compound according to a use.
Magnetic and magnetic force-cobalt, nickel, magnet, zinc, magnesium
Conductivity and conductivity-gold, silver, copper, iron, rhodium, lithium
Thermoelectric and Thermal Conductivity-Selenium, Telenium, Bizmus, etc.
Archipelago, heat conduction-chromium, copper, iron, manganese, nickel
Cold and cold conductivity-molybdenum, antimonas, zinc, potassium, etc.
Thus, the characteristic method used as a standing product as a hydroxide compound produced by refining various fine particles of elements and compounds
Example 4-Purification of olso-liquid and meta-drying and fine powders by functional bodies and functional bodies will be described.
Implementation 5 Refining Method-Installation of Hot Water Pressure Vessel Saturated Steam Pressure
Refining-It is divided into mechanism effect, power generation effect, thermoelectric effect, heat resistance effect, and cold effect.
Refining composition-By the power generation material properties of functional energy bodies
Primary-Igneous igneous rock particles 100-200 grams, Suspension hydrothermally stirred in 1-2 liters of purified water, add 20-30 grams of liquid (patent product), add 1-2 cigars, acidic water pH 1.0-2.0
100-150 grams of secondary- tourmaline particles. Suspension of hot water in 1-2 liters of purified water, stirring 1.0-2.0 of liquid (patent product), and then adding sodium hydroxide and the like. After washing, it is obtained by 180 ~ 230 ℃ moisture evaporation adjusting liquid / gel.
Or a characteristic method of obtaining dry and far-infrared ray producing particles 230-300 ° C
Tertiary-1 to 2 liters of igneous rock particles and 65 to 70 grams of the product were subjected to hydrothermal agitation, followed by mixing the tourmaline particles and 20 to 30 grams of the mixture. After 1 ~ 2 hours of addition, 0.1 ~ 0.5 grams of nickel hydrate, etc. to promote the function is added. After stirring time, the addition of ammonia carbonate, etc. After the stirring time, PH12.0 ~ 13.0 after stirring, hot water pressure, saturated steam pressure, 150 ~ 180 ℃, and stirring for 2-3 hours. After aging, acidic water is added, pH
In this way, it is possible to provide a functional energy element body by being a part of the solution of the present invention by suppressing parts and functions as a "generating effect body, power source material" product of the stagnant composition.
Example 6 The composition of the electroconductivity of 0.6-2.0 m s / cm in the electrolytic effect of the electrode body and the electrode column will be described in the tablet composition "conduction, electromechanical effector and conductive property".
Put 30-40 grams of igneous rock particles in 1 to 2 liters of purified water and stir the suspension hydrothermally, mix the tourmaline particles and 55-60 grams of the mixture, and stir 10 to 15 grams of liquid (patent) after stirring for 1 to 2 hours. After 2 hours, stirring 1.0-1.5 grams of Bizmus, Serenium, etc. After stirring 1-2 hours, sodium carbonate was added and stirring PH 12.0-13.0 Adjusted hydrothermal rock saturated steam pressure 3-4 hours at 150-180 ° C Aging Aging After 1 ~ 2 hours in neutral pH, filtered and washed until electric conductivity 0.6 ~ 2.0 m s / cm, and water evaporation adjusting liquid, gel phase is obtained at 180 ~ 230 ℃.
Or 230 ~ 300 ℃ drying, feature method to suppress dry particle product with far infrared function
Example 7 Purification Composition A thermoelectric effect body and thermoelectric property are added, and 1 to 2 liters of igneous rock particles 40 to 50 grams of purified water are added. 50 to 60 grams of tourmaline particles are mixed and the mixture is stirred for 1 to 2 hours. Antimony, tellurium, etc. after stirring 10-15 grams of upper body (patent), etc. After adding 1-2 grams of antimony, tellurium, etc. 1 ~ 2 hours after stirring, adding sodium carbonate, etc. After stirring and stirring for 3 to 4 hours, the solution was added with acidic water and then neutralized for 1 to 2 hours. After filtration and washing until the electrical conductivity was 0.6 to 2 m s / cm, the water was evaporated to adjust the liquid and gel phase at 180 ° C to 230 ° C. Get
Or a characteristic method of obtaining a dried particle product having a function of drying at 230 ° C. to 300 ° C. and a far infrared ray.
Process purification by inspection measurement of the composition
Non-contact Thermometer Infrared or Electronic
Thermometer electromagnetic conversion heating element cold body
Magnetic-Electromagnetic Measurement Gaussian Measurement
Kaiga-Electromagnetic Measurements (1-2000μ)
Electron microscope-1000 times camera qck
Electrical Measurement-Challenge, Resistance, Voltage, Current
Implementation 8 According to the high aspect of the present invention
[Manufacture of each conductor material and assembly of each functional body]
The functional and energetic conduction grating of the present invention, the structural material is produced, the electrical power property conductive grating, positive electrode (+) pole lattice, electrode column, lattice body, negative electrode (-) pole, grid body, thermoelectric conversion electrode grid Characteristic method of manufacturing lattice structure material divided into self and insulation functional body
1) Conductive Material-Chemical Fiber, Plastic Fiber, Resin Fiber, Nailong Fiber, Porima, etc.
2) Conductive Material-Porieragene, Poracesirene, Poranirin, Porridgeofen, etc.
3) Conductive material lattice-Chemical fiber material, plastic fiber material, plastic material, etc. Precipitated by liquid, gel and concentration control according to various physical properties of material lattice with standard size.
4) For functional energy materials-Purification coating processing for each functional substance precipitation processing carrier such as poraririn and porridge
5) For thermoelectric converter-Coating function for precipitation of carrier for each functional material such as poriezirene and poria styrene
6) Insulator-Plastic fiber, chemical fiber, rubber, paraffin, sodium silicate, sherpan
7) Insulation function-methods such as heat dissipation, insulator, low temperature and insulator, direct current magnetic field, insulator, lower side, magnetic field, upper surface and low temperature insulator
8) Shape material fabric specification table by functional energy body
9) Physical composition coating process of conductor electrode body by functional energy and body by fabric manufacturing
Characteristic method by which 0.05 ~ 0.1% refinement of carrier adds functional improvement effect
Example 9 Fabrication and Manufacturing of Each Functional Body of Functional Energy Body of the Present Invention
Assembly of each functional energy body-Structure of sealed semi-permanent structure
Thin film type, film type, battery type, battery type, direct type, parallel type, polycrystalline type, laminated type, combination type, etc.
Characteristics of Assembly Structure-The series structure is a function of increasing voltage, and the parallel structure is a function of increasing capacity as it is.
Classification function assembly foundation / tl thickness 3.0-4.0 X width 2-3 length 4-5 centimeters
1) Power source, generator lattice type, two phase / cm thickness 7.0 * cloth 3 * length type (5 *
2) Power Generation Electrode (+) Body-Thickness 5.0 × Width 2.7
3) Power Generation Electrode (-) Body-Thickness 5.0 × Width 2.7
4) Power Generation & Functional Insulator-Thickness 1.5 × Width 3.0
5) Power generation pole (+)-thickness 5.0 × width 2.4 upper pole 0.3
6) Power generation pole (-)-thickness 5.0 × width 2.4 upper pole 0.3
7) Functional assembly 1) Grid, type, and complex 2) Electrode (+) body and 5) Electrode main (+) body attached and attached 4) Insulator DC, magnetic function, inner covering 1) lattice Put the adjustment into the phase type.
8) Next 3) Electrode (-) body and 6) Electrode main body (-) body by attaching the adhesive as a vinyl adhesive 1) On the grid, type 2) Electrode (+) body 4) Insulator in the center Assemble
9) The functional and power generation assemblies should be sealed with inner packaging, small vinyl or plastics to cover the low temperature functional body.
10) The power generation assembly and the inner packaging shall be packaged with outer packaging and aluminum packaging and sealed with a heat transfer compressor to cover the glass functional body.
11) Outer package The functional generator element product is completed by attaching an electrode and a negative electrode to the terminal of the electrode main.
12) Functional, Generator Multifunctional, Shaped Assemblies Thickness 0.3 ~ 1.5
13) Other functional energy bodies, such as functional thermoelectrics, functional thermal conductors, functional cold conductors, etc., are provided and reduced.
Example 10-Measurement of the efficacy of functional energy and power generator, which is an object of the present invention, is the following measurement result.
However, it is limited to experiment.
Voltage and current meter
DC voltage measurement, resistance measurement, chart measurement
Function, voltage DC / AC 500
Measuring Resin-Electrical Conductivity 0.6 ~ 0.2m s / cm 0.2 ~ 2 m s / cm
Voltage current 1.5 to 3.0 ev or 6.0 to 10.0 ev
Implementation 11-Liquid Functional Test of Functional Energy Properties of the Invention
Quality Control Test-Attached to Korea Building Materials Testing Institute
In comparison of the liquid 5-fold dilution of fibrous fabric lining samples and the dilution of 15-fold distillation of nonwoven fabric samples, the difference between the nanoparticle function and the electromagnetic wave was slightly different between 0.888 and 0.881 at 5-20 microns of radiation source.
Example 12-The efficacy measurement of a functional energy thermoelectric, which is an object of the present invention, is the following measurement result.
Experimental Method-Put 3 liters of container vessel into 1 liter of water, one as it is, and one into the functional generator and thermoelectric heater assembled with the functional generator and thermoelectric heater, and the other one with the functional generator. The temperature change after 40 minutes of the functional generator and thermoelectric cold body in which the thermoelectric cold body was assembled and connected was measured.
1) Measuring instrument-Infrared temperature measuring instrument function 0.00 ℃
Mercury thermometer function 0.0 ℃
2) 10 volts of functional current of functional generator
3) Comparative measurement room temperature ℃-18.5
4)
According to the three aspects of this invention
[Effect of the power generating body of the present invention]
[1] The present invention provides the above-mentioned <31> functional conductors of the present invention, and provides various functional features such as the functional shape and use of each functional body assembly manufacturing.
1) Functional shape-Thin film type, film type, battery type, battery type, direct heating type, parallel type, low layer type, multi-layer type, combination type
2) Usage-Classification, battery, column, battery, home appliance, electronics, classification, clothing, bedding
-Series, parallel, multi-generation power generation-Household appliances, household goods, school trucks, bicycles, shelving machines, motorcycles, hybrid cars, forklifts, passenger cars, passenger vans, minibuses, vans, farm machinery, ships, fishing vessels, Polar, Housing Development, Barn, Infant Tropical, Greenhouse Heating
-Laminated and combined power generation-Factory and office power generation, building, commercial power generation, molten steel and electric power generation, train and total electric power generation, year-round cooling, heating, large ships, airplane power, helicopters, ship power, mobile power generation, spacecraft power Guided missile
② Description using the functional shape and the features of the functional as the effect of the functional energy of the present invention
1) Shape coupling and functional structure of functional energy body
2) combination of component assemblies as an effect of functional energy;
-Functional energy body, integrating body, component coupling function
Voltage 5 Amps, Current 10 Electronic Volts
Composition-thickness 1.5 × width 3 × length 5 cm
Thermal element (6 strips x 6 strips) x 3 stacked = 108
Component assembly (including insulator) thickness 6 * width 18 * 20 centimeters in length
Voltage 540 Amps Current 1080 Electronic Volts
-Functional energy body, parallel body, component combination function
Voltage 5 Amps Current 10 Electronic Volts
Composition-thickness 1.5 * width 3 * 5 centimeters
Parallel body (6 rows × 3 rows) × 6 stacked = 108
Component assembly (including insulator) thickness 12 * width 9 * 20 centimeters in length
Voltage 180 Amps Current 1080 Electronic Volts
③ Comparison with the effects of functional energy bodies of the present invention-(foreign literature), chemical cells, new experimental contents
1) High-Power Battery-Device Composition (16 Lines × 4 Lines) × 5 Stacked = 320 Units
Device Function / Voltage 6.5 Amps Current 9 Volts
Voltage and current 210 amps 290 volts
Output capacity 60 KW 480 KW
-Experiment and result, efficiency of selection 83% Supply rate 70%
2) Low-Power Battery-Device Composition (25 Lines × 4 Bottles) × 4 Stacks = 400 Pieces
Device Function / Voltage 6 Amps Current 8 Volts
Voltage and current 150 amps 320 volts
Output and capacity 65 kilowatts 520 kilowatts
-Experiment and Result Battery Efficiency 77% Supply 64%
Use of the characteristics of the thermoelectric conversion functionality as a piezoelectric effect and a thermoelectric effect on the physical phenomenon of the functional energy of the present invention
1) Effect of the combined functional structure of the functional energy generator and the thermoelectric converter
Thermoelectric functional body shape-thin film, film body, seed body, screen body, direct heating body, parallel body, polycrystalline body, laminated body, combination body
2) Uses-Effect of the shape of the functional structure's coupling function structure and thermoelectric change type functional body
-Heat & Clothing, Heat & Carpet, Heat & Curtain, Heat & Wall, Heat & Fan, Heat & Floorboard
-Function of direct heating and parallel structure generator and thermoelectric conversion type functional body-Hot water, boiler, hot water, large heater, hot water bath, domestic hot water, house heating, office floor heating, livestock, vinyl house heating
-Layered, coarse structure functional generator and thermoelectric conversion type functional body shape
Dryer, hot food processing, type circulation heating, classroom / office heating, passenger car heating, train / bus heating, passenger ship / train heating, specific heating
The piezoelectric effect and the thermoelectric effect are applied to the physical phenomenon of the functional energy body of the present invention.
1) Effect of the combined functional structure of the functional energy generator and the thermoelectric conversion / effect functional body
Thermoelectric Conversion Effect Functional Shape-Thin Film, Film, Seed, Screen, Direct Heat, Parallel, Multi-Coupled, Laminated, Combination
2) Usage-Effect of the shape of the functional structure's type and the combined function structure of thermoelectric change disease function
-Low temperature / clothing, low temperature / carpet, low temperature / curtain, low temperature / wall, partition, low temperature fan, low temperature water purifier, heat / protective clothing, low temperature food / packaging
-Function generator and thermoelectric conversion effect type and functional body shape-Cooling water cooler, Cooling circulation radiator, Low temperature and fish display rack, Low temperature meat storage, Display rack, Low temperature and body display, Low temperature fruit storage
Laminated and coarse structure functional generators and thermoelectric conversion type functional bodies
Dual switch installation, cooling and heating control switch effect
Apartment / office air conditioning / heating switch control, school / building air conditioning / heating switch control, plastic house, barn air conditioner position control, car, ship, air-conditioning control, train / bus air-conditioning control, train / bus air-conditioning control, passenger ship / train Air conditioning
1 is a cross-sectional view of the functional energy body
Drawing- Brief Description
1) It becomes 20ev or -ev functional generator depending on processing of functional compound of functional energy body
2) Shape Thickness 3.0-14.0 Width 2-3 Length 4-5 cm Assembly
3) Function, voltage 2-5 amps
Current 1.5 ~ 3.0ev, 6 ~ 10ev
4) The shape of the drawings is limited to test explanations.
① Positive terminal-Metal coating, metal plate
② Negative terminal-metal coating, metal plate
③ Positive and negative electrode projecting terminals-Positive and negative electrode projecting bodies (lattice, thickness 5.0 ~ 7.0mm)
④ Positive and negative electrode body-Positive and negative electrode projecting body (lattice, thickness 5.0 ~ 7.0mm)
⑤ Insulator film-Power generator, set plate, Poriman (Low temperature thickness 1.5mm)
⑥ Power supply type U type-Sedimentation coating size adjustment (grid, thickness 7.0 ~ 10.0mm)
⑦ Inner packaging-Vinyl tube, heat resistant film (1.5mm thick on both sides)
⑧ Outer packaging-Metal, aluminum, protective film (2.0mm thick on both sides)
Figure 2 functional generator cross section
1) Functional body type-thin film body
Size, thickness 0.3 *
Function, voltage 1-2 ampere current 1.5-2.0ev
2) Function all-round type-diamond round, metal cylinder
Size, round neck 0.3 * 4 centimeters in length
Function, voltage 1-2 ampere current 1.5-2.0ev
3) Function direct type-battery, assembly battery, 2 assembly
Size, thickness 0.5 *
Function, voltage 2-3 ampere current 4-6ev
4) Function / Parallel Type-Mechanism / Electronic Generation
Size, thickness 0.5 *
Function, voltage 1-2 ampere current 4-6ev
5) Functional and multi-stage type-16 multi-stage power generation assembly
Size, thickness 1.0 * width 3 * four centimeters in length
4 squares × 4 rows = 16
Assembly
Size, thickness 1.1 * width 12 * 16 centimeters in length
Function, voltage 4 amp current 10ev
4A × 16 units = 64 amps
10ev × 16 units = 160ev
6) Function, Lamination, Combination-Assembly of 36 Multi-Layered Combined Power Generation
Size, thickness 1.0 * width 3 * 5 centimeters in length
6 squares × 6 rows × 3 layers = 108
Function, voltage 4 amps x 108 pieces = 432 amps
10ev × 108 currents = 1080ev
Assembly size
Thickness 3.3 * width 18 * 30 centimeters in length
Fig. 3 Cross-sectional view of functional power generating body and thermal conductor
1) Function, thermoelectric conversion, heating type parallel type
Size, thickness 1.0 * width 3 * 5 centimeters in length * 4 cloth
Function, voltage 4 amps × 4 = 16 amps
10ev × 4 currents = 40ev
Combined assembly according to usage
2) Function, thermoelectric conversion, cold heat type
Size, thickness 1.0 * width 3 * 5 centimeters in length * 4 cloth
Function, voltage 4 amps x 4 = 16 amps
10ev × 4 currents = 40ev
Cooling body-4 ~ 7 ℃ × 4 pieces = 16 ~ 28 ℃
Combined assembly according to usage
4 is a structural diagram of a vehicle, etc. of the functional power generator
-Combined assembly of high power generators-Oscillation, acceleration, and hill driving
-Combined assembly of low power generator
-Heating and cooling elements of functional generators and thermoelectric converters have a unit assembly effect.
.
1 is a side view of the functional energetic body of the present invention limited to the description of the test.
Figure 2 is a functional cross-sectional view illustrating each functional type.
1) Functional body type-thin film body, film body
2) Functions / batteries-diamond file, metal cylinder
3) Functions / Linear Type-Bacteria, Assembly Batteries, 2 Assembly Display
4) Function and parallel type-Parallel assembly of two mechanisms and electronic power generation
5) Function, multi-discipline-multi-assembly, power generation 16 assembly
6) Function, Lamination, Combination Type-Assembly of 36 Layers of Lamination, Combination and Power Generation
Fig. 3 is a cross-sectional view illustrating each functional shape with a functional power generating body and a thermal conductor cross-sectional view.
1) Function, thermoelectric conversion-heating type, parallel type
2) Function, thermoelectric conversion-cold heat type, direct heat type
4 is a diagram showing a structural structure of a vehicle and the like of the power generating body.
Claims (8)
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102491354A (en) * | 2011-12-05 | 2012-06-13 | 河北工业大学 | Preparation method of nano-scale tourmaline powder |
CN103723739A (en) * | 2014-01-04 | 2014-04-16 | 河北工业大学 | Method for preparing nano tourmaline powder on kilogram scale |
-
2009
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CN102491354A (en) * | 2011-12-05 | 2012-06-13 | 河北工业大学 | Preparation method of nano-scale tourmaline powder |
CN102491354B (en) * | 2011-12-05 | 2013-01-23 | 河北工业大学 | Preparation method of nano-scale tourmaline powder |
CN103723739A (en) * | 2014-01-04 | 2014-04-16 | 河北工业大学 | Method for preparing nano tourmaline powder on kilogram scale |
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