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A water-in-fuel emulsion system comprises a reactor device, a fuel intake connected to said reactor device, a water intake connected to said reactor device, a pump connected to said reactor device, and a circulating emulsion reprocessing inline loop connected to said pump and feeding a load as neede

A water-in-fuel emulsion system comprises a reactor device, a fuel intake connected to said reactor device, a water intake connected to said reactor device, a pump connected to said reactor device, and a circulating emulsion reprocessing inline loop connected to said pump and feeding a load as needed in real time, wherein said reactor device comprises a non-vibrating anvil shaped to create cavitation sufficient to emulsify water-in-fuel from said water intake and said fuel intake.

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1. A reactor comprising: a housing having at least one inlet, an orifice at the inlet, and an outlet, anda non-vibrating anvil within the housing, the anvil having a working surface, the working surface being shaped such that material entering the inlet and passing through the orifice creates cavita

1. A reactor comprising: a housing having at least one inlet, an orifice at the inlet, and an outlet, anda non-vibrating anvil within the housing, the anvil having a working surface, the working surface being shaped such that material entering the inlet and passing through the orifice creates cavitation sufficient to emulsify or breakdown the material entering the inlet and passing through the orifice and impinging the work surface without the need for chemical surfactants or emulsifiers, resulting in a processed material that exits the reactor through the outlet. 2. The reactor of claim 1, wherein the housing is tubular and the anvil is substantially cylindrical. 3. The reactor of claim 1, wherein the orifice has at least a tapered portion having an angle and the working surface has at least a tapered portion having an angle corresponding to the angle of the tapered portion of the orifice. 4. The reactor of claim 3, wherein the taper portion terminates at a lip adjacent a trailer surface so that the material entering the inlet accelerates along the tapered portion and then impinges the lip, which disrupts the laminar flow of the material to create a pressure drop across the working surface, which creates a substantially constant cavitation along the trailing surface. 5. The reactor of claim 1, wherein the orifice has at least a cone-shaped portion having an angle and the working surface has at least a cone-shaped portion having an angle corresponding to the angle of the cone-shaped portion of the orifice. 6. The reactor of claim 5, wherein cone-shaped portion terminates at a lip adjacent a trailer surface so that the material entering the inlet accelerates along the cone-shaped portion and then impinges the lip, which disrupts the laminar flow of the material to create a pressure drop across the working surface, which creates a substantially constant cavitation along a trailing surface of the anvil. 7. The reactor of claim 1, wherein the shape of the working surface further includes a lip around which the material entering the inlet and passing through the orifice and impinging the working surface accelerates to create a pressure drop across the working surface, which creates a substantially constant cavitation along a trailing surface of the anvil. 8. The reactor of claim 7, wherein the pressure drop and a velocity of the material entering the inlet and passing through the orifice, combined with the cone-shape of the working surface, creates the substantially constant cavitation, which rolls down along the trailing surface of the anvil. 9. The reactor of claim 1, further comprising a shaft having at least a threaded part, the anvil being supported in relation to the shaft. 10. The reactor of claim 9, wherein the shaft is adjustable externally of the housing via the threaded part to adjust pressure, amplitude and frequency of the anvil to effect the cavitation. 11. The reactor of claim 9, further comprising a spring supported in relation to the shaft, the spring being biased to maintain a substantially constant pressure between the working surface and the orifice and act as a pressure relief if blockage occurs. 12. The reactor of claim 11, wherein the shaft is adjustable externally of the housing via the threaded part of the shaft to adjust compression of the spring. 13. The reactor of claim 11, wherein the spring is supported within the anvil so as not to interrupt flow of cavitation along the trailing surface of the anvil. 14. A reactor comprising: a housing having at least one inlet, an orifice at the inlet, and an outlet, anda non-vibrating anvil within the housing, the anvil having a working surface, the working surface being shaped such that material entering the inlet and passing through the orifice creates cavitation sufficient to emulsify or breakdown the material entering the inlet and passing through the orifice and impinging the work surface without the need for chemical surfactants or emulsifiers, resulting in a processed material that exits the reactor through the outlet, wherein an area of space between the anvil and the housing is at least as great as an area of a diameter of the outlet. 15. The reactor of claim 1, wherein the reactor is dimensioned and configured to be hydrosonic, creating both cavitation and sound. 16. The reactor of claim 1, wherein the inlet is connected to a source of the material including miscible or immiscible liquids or solids. 17. A reactor comprising: a housing having at least one inlet, an orifice at the inlet, and an outlet, anda non-vibrating anvil within the housing, the anvil having a working surface, the working surface being shaped such that material entering the inlet and passing through the orifice creates cavitation sufficient to emulsify or breakdown the material entering the inlet and passing through the orifice and impinging the work surface without the need for chemical surfactants or emulsifiers, resulting in a processed material that exits the reactor through the outlet, wherein the inlet is connected to a source of the material, which is selected from a group consisting essentially of food, paint, or cosmetics material. 18. The reactor of claim 1, wherein the inlet is connected to a source of the material including at least one additive. 19. The reactor of claim 1, wherein viscosity of the processed material effected by introducing at least one of an atom, a molecule, or a particle at the center of the material, so as to form at least a two-layer emulsion, wherein the atom, molecule, or particle is surrounded by the material. 20. The reactor of claim 1, in a system, the system comprising: an intake connected to the inlet of the reactor,a pump connected to the reactor, anda circulating emulsion reprocessing inline loop connected to the pump and feeding a load as needed in real time. 21. The reactor of claim 20, wherein the system further comprises a control to control the material entering into the inlet. 22. The reactor of claim 21, wherein the control is automatic to automatically control the material entering into the inlet. 23. The reactor of claim 21, wherein the control is an automatic switch in case of a system failure. 24. The reactor of claim 21, wherein the control is selected from a group consisting essentially of a management system, a computer, or a timer. 25. The reactor of claim 21, wherein the control is configured to control at least one cycle of the reactor selected from a group consisting essentially of start-up, shutdown or flush cycles of the reactor.