Subsea multiphase pump or compressor with magnetic coupling and cooling or lubrication by liquid or gas extracted from process fluid

What is claimed is: 1. A submersible fluid system for operating submersed in a body of water, the system comprising: an electric machine; a fluid-end, comprising a fluid-end housing having an inlet to a fluid rotor, the fluid rotor coupled to the electric machine and carried to rotate in the housing by a bearing in the housing; and a fluid separator system that receives a multiphase fluid and dispenses flows of a multiphase fluid to the inlet and dispenses flows of a substantially liquid flow extracted from the multiphase fluid to the bearing; wherein the fluid separator system comprises a separator tank having a top and a bottom, the separator tank comprising: an inlet for the multiphase fluid; a primary outlet in the bottom of the separator tank and coupled to the inlet of the fluid-end; and an outlet in the top of the separator tank and coupled to the fluid-end housing to supply substantially gas to a cavity surrounding a drive-end of the fluid rotor. 2. The submersible fluid system of claim 1 , wherein the fluid rotor is carried to rotate in the housing by the first mentioned bearing about one end of the fluid rotor and a second bearing about a second end of the fluid rotor and where the fluid separator system communicates a liquid flow extracted from the multiphase flow to the first mentioned bearing and the second bearing. 3. The submersible fluid system of the claim 1 , wherein the liquid flow extracted from the multiphase fluid is at a temperature below a temperature of the bearing. 4. The submersible fluid system of claim 1 , wherein the fluid separator system dispenses a fluid to a cavity surrounding the fluid rotor proximate a drive-end. 5. The submersible fluid system of claim 4 , wherein the drive-end of the fluid rotor is coupled to an electric machine rotor of the electric machine by a coupling and the fluid separator system further dispenses the flow of the fluid to a gap between a portion of the coupling on the fluid rotor and a portion of the coupling on the electric machine rotor. 6. The submersible fluid system of claim 5 , where the coupling comprises a magnetic coupling. 7. The submersible fluid system of claim 4 , wherein the fluid separator system further dispenses the substantially gas flow extracted from the multiphase fluid to a gap between a portion of the coupling on the fluid rotor and a portion of the coupling on an electric machine rotor. 8. The submersible fluid system of claim 1 , wherein the separator system comprises: an additional outlet in the bottom of the separator tank and coupled to the fluid-end housing to supply fluid, substantially liquid, to the bearing. 9. The submersible fluid system of claim 8 , wherein the additional outlet comprises an upward extending tube configured to release sand from a liquid flow flowing through the additional outlet. 10. The submersible fluid system of claim 8 , further comprising a reservoir tank, the reservoir tank being between the additional outlet and the housing of the fluid-end to receive and store liquid from the additional outlet for supplying to the fluid-end when no liquid is being produced from the additional outlet. 11. The submersible fluid system of claim 1 , further comprising an auxiliary liquid source in fluid communication with the bearing. 12. The submersible fluid system of claim 11 , wherein the auxiliary liquid source comprises at least one of a treatment liquid also being added to the multiphase fluid apart from the submersible fluid system or liquid from an outlet downstream of the fluid-end. 13. The submersible fluid system of claim 1 , wherein the fluid separator system receives the multiphase fluid upstream of the fluid-end. 14. A submersible fluid system for operating submersed in a body of water, the system comprising: an electric machine; a fluid-end, comprising a fluid-end housing having an inlet to a fluid rotor, the fluid rotor coupled to the electric machine and carried to rotate in the housing by a bearing in the housing; and a fluid separator system that receives a multiphase fluid and dispenses flows of a multiphase fluid to the inlet and dispenses flows of a substantially liquid flow extracted from the multiphase fluid to the bearing; wherein the separator system comprises a separator tank having a top and a bottom, the separator tank comprising: an inlet for the multiphase fluid; a primary outlet in the bottom of the separator tank and coupled to the inlet of the fluid-end; and an additional outlet in the bottom of the separator tank and coupled to the fluid-end housing to supply fluid, substantially liquid, to the bearing; wherein the submersible fluid system further comprises a reservoir tank, the reservoir tank being between the additional outlet and the housing of the fluid-end to receive and store liquid from the additional outlet for supplying to the fluid-end when no liquid is being produced from the additional outlet; and wherein the separator tank further comprises an outlet in the top of the separator tank and coupled to the fluid-end housing to supply substantially gas to a cavity surrounding a drive-end of the fluid rotor; and wherein the reservoir tank is between the outlet in the top of the separator tank and the fluid-end to receive fluid from the separator tank to drive liquid from the reservoir in the event no liquid is being produced from the additional outlet and the additional outlet is closed. 15. The submersible fluid system of claim 14 , wherein the bearing is configured to cause gas to exit the bearing in preference to liquids whenever gas is present within the bearing. 16. A method, comprising: operating, at a depth underwater, an electric machine and a fluid end, the fluid-end comprising a fluid-end housing having an inlet to a fluid rotor, the fluid rotor coupled to the electric machine and carried to rotate in the housing by a bearing in the housing; and operating a fluid separator system that receives a multiphase fluid comprising raw hydrocarbon process fluid and communicates a flow of the multiphase fluid to the inlet and a substantially liquid flow extracted from the multiphase fluid to the bearing; wherein the multiphase fluid is dispensed from the fluid-end away from both the fluid-end and fluid separator system; wherein the fluid separator system comprises a separator tank having a top and a bottom, the separator tank comprising: an inlet for the multiphase fluid; a primary outlet in the bottom of the separator tank and coupled to the inlet of the fluid-end; and an outlet in the top of the separator tank and coupled to the fluid-end housing to supply substantially gas to a cavity surrounding a drive-end of the fluid rotor. 17. The method of claim 16 wherein operating the fluid-end includes rotating the fluid rotor while carried by the first mentioned bearing about one end of the fluid rotor and a second bearing about a second end of the fluid rotor. 18. The method of claim 17 wherein the fluid separator system communicates a substantially liquid flow extracted from the multiphase flow to the first mentioned and the second bearings. 19. The method of claim 16 , wherein the drive-end of the fluid rotor is coupled to an electric machine rotor of the electric machine by a coupling and the fluid separator system further dispenses a flow of fluid to a gap between a portion of the coupling on the fluid rotor and a portion of the coupling on the electric machine rotor. 20. The method of claim 19 where the coupling comprises a magnetic coupling.