Filtration with internal fouling control

We claim: 1. A filtration system comprising: (a) spiral wound filtration membrane module, comprising: a spirally wound membrane, a retentate channel extending along a retentate side of the membrane for receiving a feed stream from a feed stream inlet and flow of retentate axially across a retentate side of the membrane to a retentate outlet for discharge from the module; a permeate channel located on a permeate side of the membrane that is opposite to the retentate side, for radial flow of permeate passing through the membrane to a central permeate collection tube in fluid communication therewith, said collection tube containing at least one flow resistance element and defining a fluid channel for flow of collected permeate to a permeate outlet for discharge of collected permeate from the module, and said collection tube has a permeate inlet for introducing at least a portion of discharged permeate back into the collection tube; (b) a permeate pump for returning a portion of the permeate discharged from said permeate collection tube at a controllable rate into the permeate inlet of the collection tube; (c) a feed stream pump for feeding the feed stream to the feed stream inlet at a controllable rate, wherein said permeate pump and feed stream pump being mutually controllable, (d) a controller for mutual control of the permeate pump and feed stream pump such the respective feed stream and permeate flow rates into the membrane module are mutually controllable effective to provide alternating separation and defouling phases during a production run wherein uniform transmembrane pressure is substantially maintained axially along the membrane during both phases of operation. 2. A filtration system according to claim 1 , further comprising: (e) a pressurized water line in fluid communication with the permeate channel. 3. The filtration system of claim 1 , wherein said spiral wound filtration membrane module further comprises: a housing having a first and second axial ends and defining an annular space in which the central permeate collection tube is located; a membrane leaf spirally wound around the permeate collection tube, said membrane leaf comprising a porous member sandwiched between semi-permeable membrane sheets to define the permeate passage as a radial flow channel, and a spacer arranged between windings of the membrane leaf to define the retentate channel, wherein an outer axial edge and lateral side edges of the membrane leaf are sealed and the inner axial edge thereof is in permeate flow communication with said permeate collection tube. 4. The filtration system of claim 1 , wherein said permeate pump and feed stream pump further being controllable for periodically overpressurizing the permeate side of the membrane relative to the retentate side sufficient to generate backflow across the membrane from the permeate side to the retentate side while maintaining axial, co-directional positive forward flow in the retentate and permeate channels. 5. The filtration system of claim 4 , wherein said permeate pump being controllable to increase return rate of discharged permeate to the permeate inlet while feed stream pump is controllable to maintain the feed stream at a constant rate. 6. The filtration system of claim 1 , wherein the flow resistance element is selected from the group consisting of a tapered unitary insert, a porous media packed within an internal space defined by a collection tube through which permeate flows, a static mixing device housed within a collection tube through which permeate flows, and at least one baffle extending radially inward from an inner wall of a collection tube through which permeate flows. 7. The filtration system of claim 1 , wherein the flow resistance element comprises a tapered unitary insert. 8. The filtration system of claim 1 , wherein the flow resistance element comprises a tapered unitary insert retained within the collection tube by at least one resilient sealing ring located between the insert and an inner wall of the collection tube, and said tapered unitary insert including at least one groove extending below said resilient sealing ring allowing passage of fluid under the sealing ring and along an outer surface of the tapered unitary insert. 9. The filtration system of claim 1 , wherein the membrane has a filter pore size of from about 0.005 micron to about 5 micron. 10. The filtration system of claim 1 , wherein the membrane is selected from a PVDF, a polysulfone, or a polyether sulfone membrane.