Multiple effect with vapor compression distillation apparatus

The invention claimed is: 1. A multiple effect diffusion distillation system comprising: a heat source fluidly connected a thermal energy source; a turbine or screw expander in operative connection with a power generator; a working fluid selected from the group consisting of Freon_and organic high molecular mass fluid, fluidly connected and introduced into a compressor wherein said heat source is coupled to a generator and turbine or screw expander providing energy to the heat source; a multiple effect distillation apparatus including a feed water inlet and distilled water outlet said MED further including a plurality of cylinders or plates having a zig-zag configuration which is fluidly connected to a regenerative compressor fluidly connected to said MED providing steam or vapor from said MED which is in fluid connection with an evaporator, the evaporator further including a distilled water outlet; said system including at least one variable flow valve coupled to at least one capacitive level sensor and controlled by a controller for controlling the multiple effect diffusion distillation system. 2. A multiple effect with vapor zig-zag path distillation system comprising: a plurality of evaporative cylinders, diaphragms or plates spaced apart defining a chamber having zig-zag vapor path with opposed evaporating and condensing faces; cylinders or plates being disposed at an angle to enable gravity flow of a liquid along said faces from the upper end to the lower end; distributing feed by spraying a thin film or liquid onto said evaporating face adjacent the upper end at a predetermined controlled rate for effective evaporation; condensation face for establishing a stable condensation; separately collecting said concentration and condensate at the lower portion of the system. 3. A multiple effect distillation desalination system as claimed in claim 2 , comprising: at least three evaporating-condensing elements coaxially superposed in a vertical structure; a feed tube above the topmost one of said elements for introducing salty water to be desalinated; the diaphragms having upwardly diverging inner walls with central ducts which constitute an axial vapor passageway to compress vapor back to the bottom chamber; liquid-conveying discharge meeting with each of said elements evaporated along zig-zag liquid path down to the next lower element while vapor rising in a zig-zag flow to the top to be compressed, except for the lowermost one of said elements, which has instead a tube for discharging concentrated salty water and a heater or compressed vapor for heating. 4. The system of claim 1 wherein the spacing between said cylinders or plates is between 0.2 and 5 inches. 5. The system of claim 1 wherein said feed water is selected from the group consisting of groundwater, brackish water, crude oil, chemicals and mixtures thereof. 6. The system of claim 2 including 0.2 to 2.5 atmospheric pressure in said chambers. 7. The system of claim 2 wherein said cylinders or plates are disposed at an angle of between 2°-89° from the horizontal. 8. The system of claim 2 comprising at least three heat transfer cylinders or plates and up to forty heat transfer cylinders. 9. The system of claim 2 wherein a meshed or woven layer is attached to said walls of the distillation cylinders or plates or diaphragms for maintaining said thin film wherein said cylinders plates or diaphragms comprises a plurality of parallel ribs. 10. The system of claim 2 wherein said MED evaporative cylinders, plates or diaphragms are configured from four cut-cross shapes selected from the group consisting of circular, rectangular, triangular and half-circular; and said four cross cut shapes can be used in a stacked distillation structure in a 2-level or 3-level configuration. 11. The system of claim 2 wherein said liquid film thickness is up to 0.5 inches. 12. The system of claim 2 wherein the system is filled with non-condensing gas so that said vapor is diffused through said gas. 13. The distillation system of claim 2 wherein said heat input cylinder or plate is centrally disposed within said plurality of cylinders or plates and including an heat output cylinder or plate on each side of said input plate. 14. The distillation system of claim 2 including at least a pair of centrally disposed heat input cylinders or plates having a space there between and a pair of spaced apart heat output cylinders or plates disposed outwardly of the input cylinders or plates and having at least one intermediate cylinder or plate disposed between the input cylinders or plates and the output plates. 15. The system of claim 14 wherein heat is applied to said first cylinder or plate by heating or condensing vapor or compressed vapor on the face thereof. 16. The multiple effect distillation system of claim 2 wherein feeding a thin film of liquid onto said evaporating face comprises a circular distributor between pairs of said cylinders or plates at the upper end thereof and a feed channel communicating from a source of liquid to the lower end of said separator communicating with the evaporating face of said plate. 17. The system of claim 16 wherein said feed tubes are substantially extend along the evaporating face of said cylinder or plate and opens to opposite sides on said evaporating face. 18. The system of claim 2 , further comprising a gas tight housing enclosing said system and controlling pressure between said cylinders and plates by different-sized openings and layer intervals. 19. The working fluid of claim 1 is Freon or organic high molecular mass fluid with boiling point from −50 to 400° C.