Process, apparatus and membrane bioreactor for wastewater treatment

What is claimed is: 1. A process for treating organic matter and nitrogen contained in wastewater in an aeration zone with a membrane module maintaining in a high flux operation condition, the process comprising: providing an aeration zone fitted with aerators and filled with liquid comprising a mixture of bacteria and influent wastewater to form a mixed liquid; providing the membrane module in the aeration tank comprising at least one macrofiltration membrane having a pore size of 5 μm to 150 μm, thereby providing a large pore size membrane which allows passage of treated wastewater at a high flux, while effectively stopping passage of large biological floc to retain activated sludge in the aeration tank as unfiltered activated sludge, the pore size minimizing biofouling of the membrane, the membrane held in a fixed position in a flat shape by corrosion-resistant supports at the membrane module in a manner to provide and control bio-cake growth on a surface of the membrane, wherein the membrane module comprises a membrane bioreactor that establishes a flux of the membrane bioreactor of between 2 and 16 m 3 /m 2 d and providing a trans-membrane pressure (TMP) kept at a low value of below 0.2 bar, and further reduced by backwashing the membrane, thereby reducing a tendency of the membrane to foul even at very high permeate flux; providing wastewater influent to the aeration zone; maintaining an oxygen surplus, sufficient for biological treatment by aerobic bacterial microorganisms, by controlling a rate of oxygen supplied to the aeration zone; processing the mixed liquid in the aeration zone by: filtering a first portion of the mixed liquid through the membrane to form a permeate as the treated effluent and leaving the residual part as the unfiltered activated sludge remaining suspended in the aeration zone, transferring a second portion of the mixed liquid from the aeration zone to an anaerobic zone, and mixing the second portion of the mixed liquid from the aeration zone with liquid present in the anaerobic zone to provide mixed liquid in the anaerobic zone; and transferring liquid mixed in the anaerobic zone from the anaerobic zone to the aerobic zone, wherein the aerator further comprises a membrane cleaning function using aeration bubbles to agitate the membrane to maintain a non-fouling condition of the membrane module in a high flux operation condition, further reducing a tendency of the membrane to foul even at very high permeate flux. 2. The process according to claim 1 , further comprising, in the aeration zone, performing at least one of the oxidation processes selected from the group consisting of: oxidation of organic carbon to carbon dioxide; oxidation of sulfide to sulfate; and oxidation of ammonia to nitrate by autotrophic denitrification. 3. The process according to claim 1 , further comprising, in the anaerobic zone, performing at least one of the processes selected from the group consisting of: reduction of sulfate to sulfide by oxidizing organic carbon to carbon dioxide; autotrophic denitrification using sulfide to reduce nitrate to nitrogen gas, and heterotrophic denitrification using organic carbon to reduce nitrate to nitrogen gas. 4. The process according to claim 1 , further comprising the provision of sulfide and sulfate through at least one of the group consisting of addition to one of liquids of seawater, addition to one of liquids of saline wastewater, and, in the case of the wastewater not containing sulfate or sulfite, addition to one of the liquids of sulfur selected from the group consisting of sulfate, sulfite, thiosulfates, sulfide and elemental sulfur. 5. The process according to claim 1 , further comprising using, as the membrane, a membrane having a construction comprising a material selected from the group consisting of non-woven fabric, plastic, polymer, metal, ceramic, fiber glass or thin film composites. 6. The process according to claim 1 , further comprising using a high flux membrane module, comprising a sheet type non-woven material membrane embedded therein, and fixed by the corrosion-resistant supports, in the aeration zone. 7. The process according to claim 1 , further comprising maintaining a trans-membrane pressure across the membrane modules in the aeration tank below 0.2 bar. 8. Wastewater treatment apparatus comprising: an aeration zone receiving wastewater influent and mixing the wastewater influent with activated sludge to form a first mixed liquor; a membrane module inside the aeration zone using at least one non-woven fabric macrofiltration membrane with pore sizes of 5 μm to 150 μm, thereby providing a large pore size membrane which allows passage of treated wastewater at a high flux, while effectively stopping passage of large biological floc to retain activated sludge in the aeration tank as unfiltered activated sludge, the pore size minimizing biofouling of the membrane, the membrane held in a fixed position in a flat shape by corrosion-resistant supports at the membrane module in a manner to provide and control bio-cake growth on a surface of the membrane, wherein the membrane module comprises a membrane bioreactor that establishes a flux of the membrane bioreactor of between 2 and 16 m 3 /m 2 d and providing a trans-membrane pressure (TMP) kept at a low value of below 0.2 bar, and further reduced by backwashing the membrane, thereby reducing a tendency of the membrane to foul even at very high permeate flux; an aerator maintaining an oxygen surplus, sufficient for biological treatment by aerobic bacterial microorganisms, by controlling a rate of oxygen supplied to the aeration zone; and a split processing section provided for processing the first mixed liquor by: filtering a first portion of the first mixed liquor to form a permeate and leaving the residual part as unfiltered activated sludge, mixing the unfiltered activated sludge with the activated sludge in the aeration zone, transferring a second portion of the first mixed liquor unfiltered activated sludge from the aeration zone to an anaerobic zone, and mixing the second portion of first mixed liquor unfiltered activated sludge with sludge in the anaerobic zone to form a second mixed liquor; and recycling a portion of the second mixed liquor to the aerobic zone, wherein the aerator further comprises a membrane cleaning function using aeration bubbles to agitate the membrane to maintain a non-fouling condition of the membrane module in a high flux operation condition, further reducing a tendency of the membrane to foul even at very high permeate flux. 9. The apparatus according to claim 8 , further comprising the apparatus configured for providing sulfide and sulfate through at least one of the group consisting of addition to one of liquids of seawater, addition to one of liquids of saline wastewater, and, in the case of the wastewater not containing sulfate or sulfite, addition to one of the liquids of sulfur selected from the group consisting of sulfate, sulfite, thiosulfates, sulfide and elemental sulfur. 10. The apparatus according to claim 8 , wherein the aeration zone promotes at least one of the oxidation processes selected from the group consisting of: oxidation of organic carbon to carbon dioxide; oxidation of ammonia to nitrate by an autotrophic nitrification; and oxidation of sulfide to sulfate. 11. The apparatus according to claim 8 , wherein the anaerobic zone promotes at least one of the processes selected from the group consisting of: reduction of sulfate to sulfide by oxidation of organic carbon to carbon dioxide; reduction of nitrate to nitrogen gas by autotrophic denitrification using sulfate; and reduction of nitrate to nitro