EGR heat exchanger with continuous deaeration

What is claimed is: 1. A heat exchanger for an exhaust gas recirculation system for an engine, the heat exchanger comprising: an exhaust gas recirculation (EGR) heat exchange unit having a housing including an exhaust gas inlet end, an opposed exhaust gas outlet end, a bottom side, an opposed top side, and a chamber wall partitioning an internal volume of the heat exchange unit into a heat exchange chamber and a deaeration chamber; the heat exchange chamber including a coolant inlet proximate the exhaust gas outlet end, a coolant opening in the chamber wall proximate the exhaust gas outlet end, an exhaust gas inlet at the exhaust gas inlet end, an exhaust gas outlet at the exhaust gas outlet end, a transfer passage coupling the exhaust gas inlet to the exhaust gas outlet, and a deaeration opening in the chamber wall proximate the exhaust gas outlet end, the deaeration chamber including a coolant outlet proximate the exhaust gas inlet end; the heat exchange unit configured to cool exhaust gas flowing through the transfer passage with coolant flowing within the heat exchange chamber and around the transfer passage; and the heat exchange unit adapted to be mounted relative to the engine at an incline such that the deaeration opening is configured to evacuate gas from the heat exchange chamber to the deaeration chamber and the flow of coolant into the deaeration chamber from the heat exchange chamber via the coolant opening is configured to route the evacuated gas out of the deaeration chamber via the coolant outlet; wherein the deaeration chamber includes an exhaust gas outlet end height smaller than an exhaust gas inlet end height such that the coolant outlet is positioned at substantially a highest area of the heat exchange unit relative to the bottom side. 2. The heat exchanger of claim 1 , wherein the heat exchange unit is configured such that the coolant flows in a counter flow pattern from the exhaust gas outlet side to the exhaust gas inlet side. 3. The heat exchanger of claim 1 , wherein the deaeration opening is sized and shaped to have a smaller opening area relative to the coolant opening whereby a majority of the coolant flowing in the heat exchange chamber exits through the coolant opening while a portion of the coolant exits through the deaeration opening to evacuate gas from the heat exchange chamber. 4. The heat exchanger of claim 3 , wherein the heat exchange unit is adapted to be mounted at the incline relative to an exhaust manifold of the engine such that the deaeration opening is spaced apart from the exhaust manifold by a greater distance than the coolant opening. 5. A heat exchanger for an exhaust gas recirculation system for an engine, the heat exchanger comprising: an exhaust gas recirculation (EGR) heat exchange unit having a housing including an exhaust gas inlet end, an opposed exhaust gas outlet end, a bottom side, an opposed top side, and a chamber wall partitioning an internal volume of the heat exchange unit into a heat exchange chamber and a deaeration chamber; the heat exchange chamber including a coolant inlet proximate the exhaust gas outlet end, a coolant opening in the chamber wall proximate the exhaust gas outlet end, an exhaust gas inlet at the exhaust gas inlet end, an exhaust gas outlet at the exhaust gas outlet end, a transfer passage coupling the exhaust gas inlet to the exhaust gas outlet, and a deaeration opening in the chamber wall proximate the exhaust gas outlet end, the deaeration chamber including a coolant outlet proximate the exhaust gas inlet end; the heat exchange unit configured to cool exhaust gas flowing through the transfer passage with coolant flowing within the heat exchange chamber and around the transfer passage; and the heat exchange unit adapted to be mounted relative to the engine at an incline such that the deaeration opening is configured to evacuate gas from the heat exchange chamber to the deaeration chamber and the flow of coolant into the deaeration chamber from the heat exchange chamber via the coolant opening is configured to route the evacuated gas out of the deaeration chamber via the coolant outlet; wherein the deaeration chamber includes a bypass flow inlet adapted to receive coolant flow from the cooling circuit independent of the flow from the heat exchange chamber. 6. A vehicle, comprising: an engine system including an engine, an intake manifold, an exhaust manifold, an exhaust gas recirculation (EGR) system fluidly coupled to the intake manifold and the exhaust manifold, and a cooling circuit fluidly coupled to the engine and the EGR system; a heat exchanger for the EGR system, including: a housing forming a heat exchange chamber and a separate deaeration chamber in fluid communication with the heat exchange chamber, the housing including an exhaust gas inlet end, an opposed exhaust gas outlet end a bottom side, an opposed top side, and a chamber wall within the housing partitioning an internal volume of the housing into the heat exchange chamber and the deaeration chamber; the heat exchange chamber including a coolant inlet proximate the exhaust gas outlet end, a coolant opening in the chamber wall proximate the exhaust gas inlet end, an exhaust gas inlet at the exhaust gas inlet end, an exhaust gas outlet at the exhaust gas outlet end, a transfer passage coupling the exhaust gas inlet and outlet, and a deaeration opening in the chamber wall proximate the exhaust gas outlet end, the deaeration chamber including a coolant outlet proximate the exhaust gas inlet end; the heat exchange unit configured to cool exhaust gas from the exhaust manifold flowing through the transfer passage with coolant from the cooling circuit flowing into the heat exchange chamber via the coolant inlet and around the transfer passage; wherein the heat exchanger is configured to be mounted relative to the engine at an incline such that the deaeration opening is configured to evacuate gas from the heat exchange chamber to the deaeration chamber, and the flow of coolant into the deaeration chamber from the heat exchange chamber via the coolant opening is configured to route the evacuated gas out of the deaeration chamber via the coolant outlet to the cooling circuit; wherein the deaeration chamber includes an exhaust gas outlet end height smaller than an exhaust gas inlet end height such that the coolant outlet is positioned at substantially a highest area of the deaeration chamber relative to the bottom side of the heat exchanger and the exhaust manifold. 7. The vehicle of claim 6 , wherein the heat exchange unit is configured such that the coolant flows in a counter flow pattern from the exhaust gas outlet end to the exhaust gas inlet end. 8. The vehicle of claim 7 , wherein the deaeration opening is spaced apart a greater distance from the exhaust manifold than the coolant opening. 9. The vehicle of claim 6 , wherein the deaeration opening is sized and shaped to have a smaller opening area relative to the coolant opening whereby a majority of the coolant flowing in the heat exchange chamber exits through the coolant opening while a portion of the coolant exits through the deaeration opening to evacuate gas from the heat exchange chamber. 10. The vehicle of claim 6 , wherein the coolant flows in the heat exchange chamber from the exhaust gas outlet end to the exhaust gas inlet end and flows from the coolant opening at the exhaust gas inlet end to the coolant outlet at the exhaust gas inlet end thereby drawing coolant through the deaeration opening and though the deaeration chamber in the same direction as the coolant flows through the heat exchange chamber. 11. The vehicle of claim 6 , further comprising a bypass flow inlet fluidly coupled t