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A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream including the steps of conducting the stream between spaced apart electrodes in a treatment vessel, supplying from a voltage source an AC voltage of at least one base frequency F1 to at lea

A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream including the steps of conducting the stream between spaced apart electrodes in a treatment vessel, supplying from a voltage source an AC voltage of at least one base frequency F1 to at least one of the electrodes to establish an electric field within the vessel through which the stream passes, modulating the frequency F1 of the AC voltage at a modulation frequency F2, and withdrawing separated gaseous components from an upper portion of the vessel, heavier stream components from a lower portion of the vessel, and lighter liquid components from an intermediate portion of said vessel.

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What is claimed is: 1. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream, comprising: conducting the stream between spaced apart electrodes in a treatment vessel; supplying from a voltage source an AC voltage of at least one base frequenc

What is claimed is: 1. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream, comprising: conducting the stream between spaced apart electrodes in a treatment vessel; supplying from a voltage source an AC voltage of at least one base frequency F1 to at least one of said electrodes to establish an electric field within said vessel through which the stream passes; modulating the frequency F1 of said AC voltage at a modulation frequency F2; withdrawing separated gaseous components from an upper portion of said vessel, heavier stream components from a lower portion of said vessel, and lighter liquid components from an intermediate portion of said vessel. 2. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 wherein F1 and F2 are separately selected in accordance with separate characteristics of said heavier and lighter liquid components. 3. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 wherein said frequency of modulation F2 varies from a selected threshold frequency. 4. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 wherein one of said electrodes is at ground potential. 5. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 wherein said AC voltage has a format selected from the group comprising a sine wave, a square wave, a triangular shaped wave, a trapezoidal shaped wave, an exponentially shaped wave, a logarithmically shaped wave, a semi-circular shaped wave and an inverse semi-circular shaped wave and combinations thereof. 6. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 wherein F1 is influenced by the conductivity of the stream. 7. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 wherein F2 is essentially determined by droplet mass and/or the interfacial tension of the liquid components. 8. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 wherein F2 is in the range of near 0 to about 60 Hz. 9. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 wherein F1 is in a preferred range of about 100 to 1600 Hz. 10. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 wherein F1 is modulated concurrently in intensity and frequency. 11. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 wherein said AC voltage is cyclically modulated in amplitude in a wave form in which in the first half of each cycle the intensity of the AC voltage increases at a slow exponential rate and in the second half of each cycle the intensity of the AC voltage decreases at a fast exponential rate. 12. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 wherein said AC voltage is cyclically modulated in amplitude in a wave form in which in the first half of each cycle the intensity of the AC voltage increases at a high exponential rate and in the second half of each cycle the intensity of the AC voltage decreases at a low exponential rate. 13. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 wherein said AC voltage is cyclically modulated in amplitude in a wave form in which in the first half of each cycle the intensity of the AC voltage increases exponentially and in the second half of each cycle the intensity of the AC voltage decreases exponentially. 14. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 in which said AC voltage remains at a substantially constant intensity and in which the frequency F1 thereof varies cyclically between a higher frequency and a lower frequency and in which the higher frequency and lower frequency variation occur at a selected frequency F2. 15. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 wherein said AC voltage is cyclically modulated in amplitude in a wave form in which in the first half of each cycle the intensity of the AC voltage increases at a high linear rate and in the second half of each cycle the intensity of the AC voltage decreases at a low linear rate. 16. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 wherein said AC voltage is cyclically modulated in amplitude in a wave form in which in the first half of each cycle the intensity of the AC voltage increases at a low linear rate and in the second half of each cycle the intensity of the AC voltage decreases at a high linear rate. 17. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 wherein said AC voltage in cyclically modulated in amplitude in a wave form in which in the first half of each cycle the intensity of the AC voltage increases substantially linerally and in the second half of each cycle the intensity of the AC voltage decreases substantially linerally. 18. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 in which said AC voltage F1 varies cyclically in intensity between a lower and a higher intensity and in which the frequency thereof varies cyclically between a higher frequency and a lower frequency and in which the higher frequency and lower frequency variation occur at a selected frequency F2. 19. A method of separating gaseous components, heavier liquid components and lighter liquid components of a stream according to claim 1 in which said AC voltage F1 varies cyclically in intensity between a lower and a higher intensity and in which the frequency of the AC voltage simultaneously varies cyclically between a higher frequency and a lower frequency and wherein said frequency variations F2 occur cyclically in register with said AC voltage cyclic intensity variations F1. 20. A method of desalting a salty hydrocarbon stream having gaseous components, water components and oil components comprising: flowing the salty hydrocarbon stream into a separation vessel; providing a plurality of substantially paralleled spaced apart electrodes within said vessel; providing an AC voltage source of selectable frequency; in response to the characteristics of the stream employing from said AC voltage source an AC voltage of base frequency F1; applying said AC voltage of frequency F1 to said electrodes to thereby establish an electric field between adjacent electrodes; cyclically modulating the frequency of F1 at a modulation frequency F2; conducting said salty hydrocarbon stream between adjacent of said electrodes; flowing fresh water into said vessel between adjacent said electrodes counter current to the flow of said salty hydrocarbon stream; withdrawing separated gaseous components from an upper portion of said vessel; withdrawing water components from a lower portion of said vessel; and withdrawing reduced salty oil components from an intermediate portion of said vessel.