Electromagnetically modified ethanol

Abstract

The present invention is a fuel additive that includes adducts which have been formed in a solution of metallic ions, ethanol and water. In particular, the adducts are formed for the fuel additive when the solution is electromagnetically radiated. When formed, the adducts have relatively strong permanent dipoles that will influence the temporary dipoles of hydrocarbons in untreated fuel. Specifically, under the influence of the fuel additive, hydrocarbons in the treated fuel will exhibit permanent dipoles that more effectively interact with oxygen molecules from air when the treated fuel is atomized in air in a combustion chamber.

Claims

1. A fuel additive which comprises: a solution of ethanol and water wherein the ethanol-water solution is a percentage of water to ethanol in a range between 2% and 7%; and a mineral solution containing metallic ions, wherein the ethanol-water solution and the mineral solution are pre-blended together to form a metallic ion solution, and wherein the metallic ion solution is radiated with an electromagnetic wave having predetermined operational parameters to create the fuel additive with adducts, wherein each adduct in the fuel additive has a relatively stronger permanent dipole than do corresponding molecules of the pre-blended ethanol-water solution prior to radiation.

2. The fuel additive recited in claim 1 wherein the permanent dipoles of the adducts have a predetermined change in polarity from a range between 1 Debye and 1.5 Debye to a range between 2 Debye and 2.5 Debye.

3. The fuel additive recited in claim 1 wherein the electromagnetic wave radiation has a predetermined wavelength ?, a predetermined energy E, and a predetermined time duration ?t.

4. The fuel additive recited in claim 3 wherein the predetermined wavelength ? is in a range between 10.sup.?7 m and 10.sup.?8 m.

5. The fuel additive recited in claim 3 wherein the predetermined energy E is in a range between 150 kJ/mol and 300 kJ/mol.

6. The fuel additive recited in claim 3 wherein the metallic ion solution is radiated for a time duration ?t between one and two hours.

7. The fuel additive recited in claim 3 wherein the electromagnetic radiation is uni-directionally radiated into the metallic ion solution.

8. The fuel additive recited in claim 1 wherein the mineral solution contains metallic ions selected from the group consisting of potassium, aluminum, boron, and iron.

9. An additive for interaction with hydrocarbons in a fuel, wherein the hydrocarbons have temporary dipoles, and wherein the additive comprises adducts, wherein the adducts are each an inclusion complex containing charged particles of a metallic ion and molecules in a shell of ethanol and water with each adduct having a permanent dipole for influencing the temporary dipoles of the hydrocarbons into permanent dipoles for an improved combustion efficiency of the influenced hydrocarbons.

10. The additive recited in claim 9 wherein the metallic ion is selected from the group consisting of potassium, aluminum, boron, and iron.

11. The additive recited in claim 9 wherein the adducts are formed in a blended solution of a mineral solution and a solution of ethanol and water, when the pre-blended solution is radiated with a predetermined electromagnetic wave.

12. The additive recited in claim 11 wherein the electromagnetic wave radiation has a predetermined wavelength ?, a predetermined energy E, and a predetermined time duration ?t.

13. The additive recited in claim 9 wherein the ethanol-water solution is a percentage of water to ethanol in a range between 2% and 7%.

14. A method for making a fuel additive which comprises the steps of: preparing a solution of ethanol and water; blending the ethanol-water solution with a mineral solution to create a metallic ion solution; and radiating the metallic ion solution with an electromagnetic wave to create adducts therein, wherein each adduct is an inclusion complex including a charged particle of a metallic ion in a shell of ethanol and water, and the adduct provides a permanent dipole with a predetermined polarity in a range between 2 Debye and 2.5 Debye for the fuel additive.

15. The method for making a fuel additive as recited in claim 14 wherein the ethanol-water solution is a percentage of water to ethanol in a range between 2% and 7%.

16. The method for making a fuel additive as recited in claim 15 wherein the permanent dipole of the adduct has a stronger dipole than do corresponding molecules in the metallic ion solution.

17. The method for making a fuel additive as recited in claim 14 wherein the electromagnetic wave radiation has a predetermined wavelength ?, a predetermined energy E, and a predetermined time duration ?t.

18. The method for making a fuel additive as recited in claim 14 wherein the metallic ion is selected from the group consisting of potassium, aluminum, boron, and iron, and wherein the metallic ion is pre-blended with the ethanol-water solution, when the metallic ion is in a mineral solution.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The novel features of this invention, as well as the invention itself, both as to its structure and its operation, will be best understood from the accompanying drawings, taken in conjunction with the accompanying description, in which similar reference characters refer to similar parts, and in which:

(2) The FIGURE is a schematic representation of the process required for making a fuel additive in accordance with the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

(3) Referring to the FIGURE, a process in accordance with the present invention is schematically shown and is generally designated 10. As indicated in the FIGURE, the process 10 for making a fuel additive 12 begins by dissolving ethanol 14 and water 16 to create an ethanol-water solvent 18 that contains molecules having a permanent dipole 20. The solvent 18 is then pre-blended with a mineral solute 22 to create a homogeneous metallic ion solution 24.

(4) As envisioned for the present invention the ethanol-water solvent 18 will preferably be pre-blended with a percentage of water 16 to ethanol 14 that is in a range between 2% and 7%. The FIGURE indicates that the ethanol-water solvent 18 will include molecules which have a permanent dipole 20. On the other hand, the mineral solute 22 which is to be dissolved into the ethanol-water solvent 18 will itself be a water solution of hydrated metallic ions having a permanent charge. For the present invention, the mineral solute 22 that is pre-blended with the ethanol-water solvent 18 to create the metallic ion solution 24 will preferably include ions of potassium, aluminum, boron, or iron.

(5) An important aspect of the present invention is that the homogeneous metallic ion solution 24, which includes the ethanol-water solvent 18 and the mineral solute 22, is radiated with an electromagnetic wave 26. In detail, the electromagnetic wave 26 is generated by a radiation generator 28, with the electromagnetic wave 26 having predetermined operational parameters. These parameters include a predetermined wavelength ?, a predetermined energy E, and a predetermined time duration ?t. Further, the electromagnetic wave 26 may be either uni-directionally or multi-directionally radiated into the metallic ion solution 24, and it may be generated continuously, or it may be pulsed.

(6) For purposes of the present invention, the operational parameters of the electromagnetic wave 26 will be as follows. The wavelength ? of the electromagnetic wave 26 will in a range between 10.sup.?7 m and 10.sup.?8 m. The energy E, of the electromagnetic wave 26 will be in a range between 150 kJ/mol and 300 kJ/mol. And, the metallic ion solution 24 will be radiated for a time duration ?t, between one and two hours. As noted above, the electromagnetic wave 26 may be pulsed. If so, the pulses (not shown) can each have a pulse duration and an interval between pulses that are predetermined by requirements of the process 10.

(7) As intended for the process 10 of the present invention, the purpose for radiating the metallic ion solution 24 with the electromagnetic wave 26 is to create adducts in the homogeneous metallic ion solution 24. Specifically, the adducts that are formed by this radiation are inclusion complexes containing charged particles from the mineral solute 22 (i.e. metallic ions), and the ethanol 14, as well as water 16. The result is the fuel additive 12 in which ethanol 14 in the solvent 18 has been modified for inclusion in the adducts (i.e. a modified ethanol 14). Importantly, the modified ethanol 14 is homogeneous and will have a relatively stronger permanent dipole 20.sup.+. In particular, as envisioned for the present invention, the permanent dipoles 20.sup.+ of the fuel additive 12 will experience a change in polarity from a range between 1 Debye and 1.5 Debye to a range between 2 Debye and 2.5 Debye. In any event, the dipole 20.sup.+ will have a polarity that is greater than a corresponding dipole 20 of ethanol molecules of the pre-blended ethanol-water solvent 18, prior to a radiation of the metallic ion solution 24.

(8) While the particular Electromagnetically Modified Ethanol as herein shown and disclosed in detail is fully capable of obtaining the objects and providing the advantages herein before stated, it is to be understood that it is merely illustrative of the presently preferred embodiments of the invention and that no limitations are intended to the details of construction or design herein shown other than as described in the appended claims.