Engine having oxygen pumping intake system and method of removing oxygen from intake air flow

What is claimed is: 1. An engine assembly comprising: an intake manifold in fluid communication with a combustion chamber; a first intake conduit having an inlet directly connected to an air supply and an outlet directly connected to said intake manifold; a voltage source; and a first oxygen pump assembly disposed in said first intake conduit, the oxygen pump assembly including an oxygen ion conducting cell, a first electrode in electrical communication with the voltage source and a second electrode in electrical communication with the voltage source, the first electrode being disposed on a first side of the cell and being exposed directly to an interior of the first intake conduit, and the second electrode being disposed on a second side of the cell and isolated from the interior of the conduit, the first oxygen pump assembly disposed between the inlet and the outlet and configured to remove oxygen from an air flow within the interior of the first intake conduit based on a voltage applied across the cell by the voltage source to create an oxygen depleted airflow that is directly supplied to the intake manifold. 2. The engine assembly of claim 1 , wherein the cell is formed from zirconium dioxide (ZrO 2 ). 3. The engine assembly of claim 1 , wherein the voltage source is configured to apply a voltage across the cell of greater than 12 volts. 4. The engine assembly of claim 1 , further comprising an exhaust manifold in fluid communication with the combustion chamber, the oxygen pump assembly including a first exhaust conduit in fluid communication with the exhaust manifold, the second electrode being exposed to an interior of the first exhaust conduit, the oxygen removed from the first intake conduit being provided to the first exhaust conduit. 5. The engine assembly of claim 4 , wherein the first exhaust conduit is in thermal communication with the cell such that an exhaust gas provided to the first exhaust conduit from the exhaust manifold heats the cell to increase oxygen removal from the first intake conduit. 6. The engine assembly of claim 1 , wherein the second electrode is exposed to atmosphere. 7. The engine assembly of claim 1 , further comprising a second oxygen pump assembly having an inlet in fluid communication with an air supply and an outlet in fluid communication with the intake manifold, the second oxygen pump assembly being in a parallel orientation to the first oxygen pump assembly. 8. An engine air intake assembly comprising: a first intake conduit having an inlet in fluid communication with an air supply and an outlet in direct fluid communication with an intake manifold of an engine; and a first oxygen pumping mechanism including a first oxygen ion conducting cell, a first electrode in electrical communication with a voltage source and a second electrode in electrical communication with the voltage source, the first electrode being disposed on a first side of the cell and being directly exposed to an interior of the first intake conduit, and the second electrode being disposed on a second side of the cell and isolated from the interior of the conduit, the first oxygen pumping mechanism disposed between the inlet and the outlet and configured to remove oxygen from an air flow within the interior of the first intake conduit based on a voltage applied across the cell by the voltage source, and to create an oxygen depleted airflow that is directly supplied to the intake manifold. 9. The engine air intake assembly of claim 8 , wherein the cell is formed from zirconium dioxide (ZrO 2 ). 10. The engine air intake assembly of claim 8 , wherein the voltage source is configured to apply a voltage across the cell of greater than 12 volts. 11. The engine air intake assembly of claim 8 , further comprising an exhaust manifold, wherein the oxygen pumping mechanism includes a first exhaust conduit in fluid communication with the exhaust manifold, the second electrode being exposed to an interior of the first exhaust conduit, the oxygen removed from the first intake conduit being provided to the first exhaust conduit. 12. The engine air intake assembly of claim 11 , wherein the first exhaust conduit is in thermal communication with the first intake conduit such that an exhaust gas within the first exhaust conduit heats the cell to increase oxygen removal from the first intake conduit. 13. The engine air intake assembly of claim 8 , wherein the second electrode is exposed to atmosphere. 14. The engine air intake assembly of claim 8 , further comprising: a second intake conduit in a parallel orientation to the first intake conduit and having an inlet in fluid communication with the air supply and an outlet in fluid communication with the intake manifold of the engine; and a second oxygen pumping mechanism including a second oxygen ion conducting cell, a third electrode in electrical communication with the voltage source and a fourth electrode in electrical communication with the voltage source, the third electrode being disposed on a first side of the second cell and being exposed to an interior of the second intake conduit and the fourth electrode being disposed on a second side of the second cell and isolated from the interior of the second intake conduit, the second oxygen pumping mechanism removing oxygen from an air flow within the interior of the second intake conduit based on a voltage applied across the second cell by the voltage source. 15. A method comprising: providing an air supply to an intake manifold of an internal combustion engine, the air supply being provided by a first intake conduit having an inlet in fluid communication with the air supply and an outlet directly in fluid communication with the intake manifold; and reducing an oxygen concentration of the air supplied to the intake manifold via a first oxygen pumping mechanism, the first oxygen pumping mechanism including a first oxygen ion conducting cell, a first electrode in electrical communication with a voltage source and a second electrode in electrical communication with the voltage source, the first electrode being disposed on a first side of the cell and being exposed to an interior of the first intake conduit and the second electrode being disposed on a second side of the cell and isolated from the interior of the conduit, the reducing including applying a voltage across the cell from the voltage source to remove oxygen from the air within the interior of the first intake conduit that is supplied directly to the intake manifold. 16. The method of claim 15 , wherein the reducing the oxygen concentration includes removing oxygen from a second intake conduit via a second oxygen pump mechanism, the second intake conduit being in a parallel orientation relative to the first intake conduit and including a second inlet in fluid communication with the air supply and a second outlet in fluid communication with the intake manifold, the second oxygen pumping mechanism including a second oxygen ion conducting cell, a third electrode in electrical communication with the voltage source and a fourth electrode in electrical communication with the voltage source, the third electrode being disposed on a first side of the second cell and being exposed to an interior of the second intake conduit and the fourth electrode being disposed on a second side of the second cell and isolated from the interior of the second intake conduit, the second oxygen pumping mechanism removing oxygen from an air flow within the interior of the second intake conduit based on a voltage applied across the second cell by the voltage source. 17.