KR100555787B1 - Bio alcohol and bio fuel by far infrared therapy, and manufacturing methods thereof - Google Patents

Abstract

The present invention relates to a bio-alcohol, a biofuel by a far-infrared method, and a method for producing the same. , Obtained by mixing and stirring additives such as modifiers, ethers and vegetable supporting agents and radiating far infrared rays, or by mixing the vegetable bioethanol and methanol, and mixing and stirring various additives therein and radiating far infrared rays. It is a bio-alcohol, a biofuel by the far-infrared method, and its manufacturing method.

The biofuel is environmentally friendly by using vegetable raw materials instead of conventional fossil fuels, and applies far-infrared techniques to activate alcohol molecules to increase alcohol energy power, and to reform and activate biofuels for fuel rather than alcohol, distilling crude oil. Compared with the existing gasoline obtained, the quality and performance is superior, and it is effective to minimize the emission of pollutants.

Vegetable, Fuel, Alcohol, Ethanol, Far Infrared

Description

BIO ALCOHOL AND BIO FUEL BY FAR INFRARED THERAPY, AND MANUFACTURING METHODS THEREOF}             

1 is a CCD camera photographing results before and after bioalcohol production

Figure 2 is a graph showing the GDV change in the production of biofuel of the present invention

3 is a graph showing the change in GDV during the production of general ethanol fuel

The present invention relates to a bio-alcohol, a biofuel by a far-infrared method, and a method for manufacturing the same. The ethanol of vegetable ethanol is activated by a far-infrared method to increase alcohol energy power so as to use alcohol for fuel as a bio-alcohol. The modified alcohol is activated, and the modified alcohol is activated by a far-infrared method to obtain a bioalcohol.

In addition, the present invention is characterized by being obtained by mixing and stirring the vegetable bio ethanol and isopropyl alcohol and isobutyl alcohol, isooctane and isohexane, modifiers, ethers and vegetable coagulants and radiating far infrared rays.

In addition, the present invention is obtained by mixing vegetable bioethanol and methanol and adding a predetermined additive thereto, wherein the vegetable bioethanol and methanol, isopropyl alcohol and isobutyl alcohol, isooctane and isopentane, texol, ether and vegetable It is obtained by mixing and stirring a support agent and radiating far infrared rays.

The biofuel is eco-friendly by using vegetable raw materials instead of conventional fossil fuels, and by activating molecules by applying far-infrared rays technology, it has better quality or performance than conventional gasoline obtained by distilling crude oil and minimizes the emission of pollutants. It can be effective.

BACKGROUND ART Usually, gasoline (petrol) is used as a fuel used in an internal combustion engine that burns fuel inside an engine and converts thermal energy into mechanical energy.

The gasoline refers to a mixture of various hydrocarbons having a boiling point of 30 to 200 ° C., obtained by distilling crude oil or thermally and chemically treating them, and depending on the nature and state and the processing method thereof, paraffinic, olefinic, naphthenic, aromatic It is classified into a system, etc., and is classified into a direct gasoline, cracked gasoline, polymerized gasoline, natural gasoline, artificial gasoline, reformed gasoline, etc. according to the manufacturing method.

In addition, depending on the application, it is divided into industrial gasoline, automobile gasoline, aircraft gasoline, etc. The automobile gasoline is usually mixed with direct gasoline, decomposed gasoline, reformed gasoline, etc., and then adds an anti knock agent or stabilizer to increase the octane number. .

One such area being studied as fuel for automobiles is the field of alternative fuels using alcohol. In the United States, the study was started in the early 1800s, and gasoline mixed with 10% ethanol was commercially available in 1979. With significant ripple effects across the country, the use of ethanol is growing gradually, with the proportion of ethanol added to more than 7% of all US automobile fuels.

In general, alcohol fuel has the advantage of igniting even at a lower volatility than gasoline, but low calorific value compared to gasoline is often added to the aromatic raw material toluene, xylene, etc. in order to increase the amount of heat causes pollution.

In addition, alcohol fuel has higher oxygen content than gasoline fuel, and during incomplete combustion, alcohol fuel may heat the packing part and engine machine part of the internal combustion engine, causing mechanical failure, and corrode vehicles, nonferrous metal parts and various pipes based on acidification. In addition, it may cause a failure of the internal combustion engine of the vehicle, and may not start well at low temperatures, and may inevitably release incompletely burned carbonaceous materials such as formaldehyde and methyl formate, thereby polluting the environment.

On the other hand, in recent years, various additives for fuel have been introduced through various methods, but the manufacturing method is crude and continuity, causing pollution and not satisfactory in effect.

Accordingly, the present invention improves the above-mentioned conventional problems, and a first object of the present invention is to provide a bioalcohol suitable for fuel with high energy power by activating alcohol molecules by far-infrared methods of ordinary vegetable ethanol. will be.

A second object of the present invention is to provide a biofuel having improved physical properties as an alternative fuel by mixing and stirring various additives in vegetable bioethanol and radiating far infrared rays.

In addition, a third object of the present invention is to mix the vegetable bioethanol and methanol, and to mix and stir various additives, and to radiate far infrared rays, methanol mixed biofuel with improved physical properties as an alternative fuel mixed with methanol To provide.

Hereinafter, the configuration of the present invention will be described in detail.

In the first aspect of the present invention, the conventional vegetable ethanol is activated by the far-infrared technique to activate the alcohol molecule, and the alcohol energy power is increased so that the alcohol for alcohol can be used for fuel. It is characterized by obtaining a bio-alcohol by activating by a far infrared method.

As the vegetable ethanol, normal vegetable ethanol such as spirits is preferable. In addition, ethanol obtained from agricultural products such as cassava, beets, potatoes, yellow rich, acorns, corn or wild grass can be used.

In addition, the far-infrared method applied in the present invention is to modify the vegetable ethanol using a predetermined far-infrared device, and then activate it again in the storage tank to be stored and stored.

The far-infrared device used here is a cylindrical shape, sealed inside a reflective cylinder made of an aluminum plate, containing antibacterial ceramic balls capable of generating far-infrared rays, energy ores such as jewelry or tourmaline, and high-performance magnets.

The second invention of the present invention, 60 to 80% by weight of the plant bioethanol and 3 to 8% by weight of isopropyl alcohol and isobutyl alcohol, 7 to 13% by weight of isooctane and isohexane, 5 to 9% by weight of modifier, ether It is characterized in that it is obtained by mixing and stirring 2 to 4% by weight and 3 to 6% by weight of the vegetable supporting agent and radiating far infrared rays.

Here, the blending order of the vegetable bioethanol and various additives is not special, but from the viewpoint of work efficiency, it is preferable to first mix various additives including isopropyl alcohol at a predetermined ratio, and then add them to the vegetable bioethanol at once. Do.

In addition, the ratio of the added amount of each component is obtained from a number of test results, when the content of the vegetable bioethanol is less than 60% by weight, the calorific value is lowered and the effect of the addition is less, on the contrary, the oxygen content is more than 80% by weight Many alcohols are not good because of the risk of incomplete combustion.

The isopropyl alcohol and isobutyl alcohol are added as a balance component, but may be composed of only one of the two components, the total content is preferably 3 to 8% by weight.

In addition, isooctane and isohexane are added to improve the octane number, and may also be composed of only one of the two components, the total content of which is preferably 7 to 13% by weight, the content for the octane number Too high a problem of knocking is likely to occur, the amount of addition of other components is reduced by that much, it is good to maintain the above range.

The addition amount of the modifier is 5 to 9% by weight is good, but less than 5% by weight of the overall effect of the modification is negligible, even if it exceeds 9% by weight of the other components are not preferable, the ether is also preferred as an octane number enhancer 2-4 weight% is preferable.

In addition, if the addition amount of the vegetable supporting agent is less than 3% by weight, it is not good to generate a lot of formaldehyde or methyl formate due to incomplete combustion material, it is uneconomical to add too much relatively expensive vegetable supporting agent Then, the range is preferably 3 to 6% by weight.

In the second invention of the present invention, the far-infrared technique is applied in the process of adding, mixing and storing vegetable bioethanol and various additives to improve the performance of the biofuel.

On the other hand, the third invention of the present invention is obtained by mixing the vegetable bioethanol and methanol, 25 to 35% by weight of the vegetable bioethanol, 35 to 45% by weight methanol, isopropyl alcohol and isobutyl alcohol 4 to 8 It is characterized by obtained by mixing and stirring the weight%, 5-12% by weight of isooctane and isopentane, 6-10% by weight of texol, 2-4% by weight of ether and 3-6% by weight of vegetable softener.

Here, if the amount of methanol added to the vegetable bioethanol is less than 35% by weight, the desired effect of increasing the calorific value is economically reduced, whereas if it is more than 45% by weight, the amount of ethanol is relatively reduced, but the pollution is high. Many occur and are not desirable.

In addition, the texol is a solvent component, the content of which is preferably 6 to 10% by weight, if out of the range, other components that are relatively expensive to increase by that amount, or if the content of other components to function a predetermined It is not desirable because it should be reduced.

In the third invention of the present invention, the far-infrared method is applied to the process of adding, mixing, and storing various additives to the mixture of vegetable bioethanol and methanol, and at this time, the energy of antibacterial ceramic balls, jewelry, tourmaline, etc. Ores and high-performance magnets are placed, and a cylindrical far infrared device is molded using an aluminum plate on the outside.

Hereinafter, the configuration of the present invention through the embodiment in more detail.

Example 1 (bio alcohol production)

The far infrared device was immersed in ordinary vegetable ethanol, and the far infrared device was rotated through a motor mounted outside the reaction tank.

Accordingly, while the far-infrared device rotates to accelerate stirring, the fundamental characteristics of far-infrared radiation such as radiation, cardiac calendar, and resonance absorption are generated from the inside of the device, thereby accelerating the vibrational movement of the constituent molecules to activate the molecules, and Generated great energy.

Thus, by using the far-infrared device of this invention, biofar-infrared radiation was generate | occur | produced more than 4 hours, and the vegetable ethanol was reformed by the bioalcohol for fuel of this invention.

In other words, by activating the alcohol molecules in the far-infrared technique to increase the alcohol energy power to use the alcohol alcohol for fuel for reforming to bio-alcohol, and to activate the modified alcohol by the far-infrared technique to obtain the bio-alcohol.

The vegetable biofuel thus obtained is photographed with a CCD camera of changes in the energy field before and after the far-infrared treatment of the present invention, and is shown in FIG.

As shown in the figure, it can be seen that the energy field after the treatment is significantly larger than before the far-infrared treatment of the present invention, and it can be confirmed that energy is activated by the far-infrared method.

Example 2 (biofuel production)

First, 70% by weight of the vegetable bioethanol obtained in Example 1 is added to a mixing and reaction tank, and various additives are added and mixed.

As the additive, 2% by weight of isopropyl alcohol, 3% by weight of isobutyl alcohol, 5% by weight of isooctane, 5% by weight of isohexane, 7% by weight of modifier, 3% by weight of ether and 5% by weight of vegetable softener (SP-100) Mix and stir and add to the vegetable bioethanol at once.

At this time, the mixing and reaction tanks were immersed in a predetermined far infrared device used in Example 1, and the energy was activated by rotating the far infrared device through a motor mounted outside the reaction tank.

Although the reaction is slightly exothermic, it does not require a special cooling device, and stirring is not particularly difficult.

The test report of the biofuel obtained in this way was tested by Korea National Oil Inspection Corporation (Kimsco), as shown in Table 1 below.

Test Items Gasoline standards Invention fuel Test standard Benzene, vol% Max 2 0.13 ASTM D5134 Oleffin, vol% Max 23 0.83 〃 Aromatic, vol% Max 35 18.53 〃 Sulfur, ppm Max 200 7.2 ASTM D5453 R.V.P (37.8 ° C, Kpa) Max 82 43 ASTM D323 Phosphorus, g / l Max 0.0013 0.0001 ASTM D3231 Density, 15/4 ℃ - 0.7901 ASTM D4052 W / Sediment, vol% Max 0.01 Less than 0.01 ASTM D2709 Copper Corrosion, 50 ℃, 3hrs Max 1.0 1-a ASTM D130 Induction Period, Min Min 480 MT 720 ASTM D525 Existent Gum, mg / 100ml Max 5.0 2.0 ASTM D381 R.O.N 91-94 116.1 ASTM D2699 Distillation Range, ℃ I.B.P 10% 50% 90% F.B.P Residue, ml  Max 70 Max 125 Max 175 Max 225 Max 2.0  49.4 59.5 68.1 126.3 164.9 1.0 ASTM D86 Color Yellow Transparent Visual Doctor test Sweet Sweet ASTM D-4952 Alcohol Content, vol% - 57.0 ASTM D-4815

As can be seen from the above table, the biofuel of the present invention not only meets various gasoline standards, but also satisfies various gasoline standards in specific values.

In addition, although the change of each process proceeded in Example 2 is shown in Figure 2, Figure 2 is a graph showing the change in gas discharge visualization (GDV) during the production of the biofuel of the present invention.

The GDV technology is a technology that images the emission of the alcohol energy field through interaction with the electromagnetic field and analyzes it using a computer.

In Fig. 2, A is a conventional vegetable ethanol, B is a bioethanol obtained in Example 1, C is a mixture in which an additive is added to B, and D is a result of Example 2 in which this was activated again by a far infrared method.

As shown in the figure, the area of the energy field, which was about 1,300 in A, rose to 1600 after applying the predetermined far-infrared method. (B)

In the said B, since additives should be mixed, it goes down from C to 1500, and then rises to about 1700 in D which applied the far-infrared method of this invention again.

That is, it is possible to confirm the fact that the area of the energy field is increasing while biofueling conventional vegetable alcohols, and thus the effect of the far-infrared method of the present invention can be sensed.

On the other hand, Figure 3 is a graph showing the change in GDV in the production of general ethanol fuel, E is a general vegetable ethanol, F is added to the same additives as in the present invention, G is used again the far infrared device of the present invention Is to activate F.

Referring to FIG. 3, the area of the energy field of general vegetable ethanol (E) is about 1300 as in FIG. 2, but when it is added to the additive, the area is slightly lowered to 1200. However, when the far-infrared method as in the present invention is applied, it is again 1400. It can be seen that the vicinity rises.

Therefore, when comparing and observing FIG. 2 and FIG. 3, even if the same vegetable ethanol is added in the first activated state and then activated again (FIG. 2), the example is simply added to the additive (FIG. 3). It can be seen that it is much more effective than the end, and finally, the superiority of the present invention can be confirmed.

Example 3 (Methanol Mixed Biofuel Production)

The vegetable bioethanol obtained in Example 1 and general methanol are mixed to form a main component of alcohol, but 30% by weight of the vegetable bioethanol and 40% by weight of normal methanol are mixed, and various additives are added and mixed thereto.

As the additive, 3% by weight of isopropyl alcohol, 3% by weight of isobutyl alcohol, 6% by weight of isooctane, 2% by weight of isopentane, 8% by weight of texol, 3% by weight of ether and 5% by weight of vegetable supporting agent were mixed and stirred, To the mixture of vegetable bioethanol and methanol is added at once.

Here, as in Examples 1 and 2 above, when mixing and stirring various additives in a mixture of vegetable bioethanol and methanol, the far infrared method is installed inside the reaction tank, and the same method is used even after storage. Apply.

Also in the methanol mixed biofuel obtained in this way, when the energy field changed by the method similar to the said Example 2 was confirmed, the change of the energy field after a process was outstanding, and the superiority of this invention can be confirmed.

On the other hand, the embodiment of the present invention has been described with reference to the example of applying the far infrared method using the ethanol which is a vegetable raw material, the present invention is not limited to this, also when the far infrared method is applied using other pollution-free or low pollution raw materials. Similar to the technical spirit of the present invention will fall within the scope of the present invention.

 As described above, according to the present invention, by applying the far-infrared method to the conventional vegetable ethanol to obtain the vegetable bioethanol, by mixing and stirring the vegetable bioethanol and various additives, the far-infrared radiation to improve the physical properties as an alternative fuel A biofuel can be obtained, and a biofuel mixed with methanol can be obtained by mixing and stirring various additives with the vegetable bioethanol and methanol, and radiating far-infrared rays, and the use and application in related fields are expected. .

Claims (5)

The conventional vegetable ethanol is modified by the far-infrared method to produce vegetable bioethanol, and 60 to 80% by weight of the vegetable bioentanol, 3 to 8% by weight of isopropyl alcohol and isobutyl alcohol, 7 to 13% by weight of isooctane and isohexane %, Modifier 5-9% by weight, ether 2-4% by weight and vegetable softener 3-6% by weight, the method of producing a biofuel by the far-infrared method, characterized in that to produce a biofuel by radiating far infrared rays . Biofuel obtained by the method of claim 1 25 to 35% by weight of vegetable bioethanol obtained by modifying the vegetable ethanol by the far-infrared method and 35 to 45% by weight of ordinary methanol, 4 to 8% by weight of isopropyl alcohol and isobutyl alcohol, isooctane and isopentane 5 Method for producing biofuel by far-infrared method, characterized by mixing and stirring ~ 12% by weight, 6-10% by weight of texol, 2-4% by weight of ether and 3-6% by weight of vegetable softener Biofuel obtained by the method of claim 3 delete

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