Orbital wastewater treatment system and method of operating same

What is claimed is: 1 . An orbital wastewater treatment system comprising: a tank assembly having at least a first treatment zone, a second treatment zone and a third treatment zone, said tank assembly having at least two passages between said first treatment zone and said second treatment zone and at least two second passages between said second treatment zone and said third treatment zone; and at least one impeller in said tank assembly for moving mixed liquor under process about said tank assembly and through said passages. 2 . The system defined in claim 1 , further comprising: at least one flow diversion mechanism, said at least one flow diversion mechanism being disposed at one of said first passages and said second passages; and an actuator operatively connected to said at least one flow-diversion mechanism. 3 . The system defined in claim 1 , further comprising a control unit operatively connected to said actuator for regulating or adjusting a flow state or configuration of said at least one flow-diversion mechanism. 4 . The system defined in claim 3 wherein said at least one flow-diversion mechanism is a first flow-diversion mechanism disposed at at least one of said first passages, further comprising a second flow-diversion mechanism disposed at at least one of said second passages, said actuator being a first actuator operatively connected to said first flow-diversion mechanism, also comprising a second actuator operatively connected to said second flow-diversion mechanism, said control unit being operatively connected to said first actuator and said second actuator for regulating or adjusting a flow state or configuration of said first flow-diversion mechanism and said second flow-diversion mechanism. 5 . The system defined in claim 4 , further comprising a third flow-diversion mechanism disposed at another of said second passages, also comprising a third actuator operatively connected to said third flow-diversion mechanism, said control unit being operatively connected to said first actuator, said second actuator and said third actuator for regulating or adjusting a flow state or configuration of said first flow-diversion mechanism, said second flow-diversion mechanism and said third flow-diversion mechanism. 6 . The system defined in claim 1 , further comprising an air diffuser or aeration element disposed in at least one of said treatment zones. 7 . The system defined in claim 6 , further comprising a control unit operatively connected to said impeller and said air diffuser or aeration element and configured to operate said impeller and said air diffuser or aeration element. 8 . The system defined in claim 1 , further comprising at least one mixer disposed in at least one of the treatment zones. 9 . The system defined in claim 8 wherein said at least one mixer is disposed in one of said first treatment zone and said third treatment zone, also comprising at least one air diffuser or aeration element disposed in said one of said first treatment zone and said third treatment zone. 10 . The system defined in claim 2 further comprising at least one weir disposed adjacent to and communicating with said third treatment zone. 11 . The system defined in claim 10 wherein said at least one flow diversion mechanism is disposed at one of said second passages, another flow diversion mechanism being disposed at one of said first passages, further comprising an additional actuator operatively connected to said another flow diversion mechanism. 12 . The system defined in claim 3 , further comprising at least one sensor in said tank assembly, said control unit being operatively connected to said sensor and said actuator for regulating or adjusting a flow state or configuration of said at least one flow-diversion mechanism at least partially in accordance with input from said sensor. 13 . The system defined in claim 12 wherein said control unit is programmed to adjust said flow-diversion mechanism to one of two states or configurations upon an earlier to occur of (i) a lapse of a predetermined time period after adjusting of said flow-diversion mechanism from said one of said two states or configurations and (ii) a detection by said sensor of a predetermined magnitude of a preselected control parameter in one of said treatment zone, said second treatment zone and said third treatment zone. 14 . The system defined in claim 13 wherein said control unit is further programmed to maintain said at least one flow-diversion mechanism in said one of said two states or configurations for a predetermined additional time period and to adjust said at least one flow-diversion mechanism from said one of said two states or configurations after termination of said additional time period. 15 . The system defined in claim 14 wherein said control unit is further programmed to adjust said at least one flow-diversion mechanism from said one of said two states or configurations upon an earlier to occur of (i) a lapse of said predetermined additional time period after moving of said at least one flow-diversion mechanism to said one of said two states or configurations and (ii) an automated detection of a predetermined magnitude of a preselected control parameter in one of said first treatment zone, said second treatment zone and said third treatment zone. 16 . The system defined in claim 12 wherein said control unit is further programmed to periodically and incrementally adjust said flow-diversion mechanism. 17 . The system defined in claim 13 wherein said first treatment zone is an anoxic zone convertible into an anaerobic zone, said second treatment zone is an aerobic zone convertible at least partially into an anoxic zone, and said third treatment zone is convertible between an aerobic zone and an at least partially anoxic zone, said one of said two states or configurations being a closed position inhibiting or preventing flow between said second treatment zone and at least one of said first treatment zone and said third treatment zone. 18 . The system defined in claim 12 wherein said first treatment zone is an anoxic zone convertible into an anaerobic zone, said second treatment zone is an aerobic zone convertible at least partially into an anoxic zone, said third treatment zone is convertible between an aerobic zone and an at least partially anoxic zone, said at least one flow-diversion mechanism being located in or at one of said first passages or in or at one of said second passages to regulate or adjust flow from said second treatment zone to said first treatment zone or from said third treatment zone to said second treatment zone. 19 . The system defined in claim 12 wherein said sensor is taken from the group consisting of a phosphorus (P) sensor, an oxidation reduction potential (ORP) sensor, a dihydride nicotinamide adenine dinucleotide (NADH) sensor, an NO 3 —N sensor, an ammonia (NH 3 —N) sensor, a dissolved oxygen (DO) sensor, and a velocity sensor. 20 . The system defined in claim 12 wherein said sensor is disposed in one of said first treatment zone and said second treatment zone, further comprising an additional sensor disposed in one of said first treatment zone, said second treatment zone and said third treatment zone, said additional sensor also being connected to said control unit for informing control operations thereof, said additional sensor being taken from the group consisting of a phosphorus (P) sensor, an oxidation reduction potential (ORP) sensor, a dihydride nicotinamide adenine di