Dual inlet and outlet exhaust gas recirculation cooler for turbocharged engine

The invention claimed is: 1. An exhaust gas recirculation (EGR) cooler, comprising: a coolant passage with a coolant inlet positioned on a first longitudinal surface of the cooler, fluidically coupled to an external coolant circuit, and a coolant outlet positioned on a second lateral surface of the cooler, fluidically coupled to an external coolant circuit, the second lateral surface opposite and parallel to the first longitudinal surface; a first exhaust passage with an inlet and an outlet located on opposite lateral surfaces, the lateral surfaces perpendicular to the first and second longitudinal surfaces; and a second exhaust passage equal in length to the first exhaust passage, the second exhaust passage including an inlet and an outlet located on the opposite lateral surfaces, the second exhaust passage inlet on the same surface as the outlet of the first exhaust passage, and the second exhaust passage outlet on the same surface as the inlet of the first exhaust passage. 2. The EGR cooler of claim 1 , wherein the EGR cooler is mounted to an engine and the exhaust passage inlets and outlets of the EGR cooler are perpendicular to a crankshaft of the engine. 3. The EGR cooler of claim 1 , wherein the first and second exhaust passages merge to form a combined exhaust conduit downstream of the EGR cooler. 4. The EGR cooler of claim 1 , wherein the coolant decreases the temperature of the gases flowing through the first and second exhaust passages to a suitable temperature for reentry into an intake manifold of an engine. 5. The EGR cooler of claim 1 , wherein the coolant passage provides equal cooling to the gases flowing through the first and second exhaust passages. 6. The EGR cooler of claim 1 , wherein the coolant passage, first exhaust passage, and second exhaust passage are contained in a single cooler housing. 7. The EGR cooler of claim 1 , wherein the first and second exhaust passages are equal in length from the inlets to a merging junction at which the first and second exhaust passages form the combined exhaust conduit. 8. The EGR cooler of claim 7 , wherein the first and second exhaust passages maintain separate exhaust flows throughout the EGR cooler and only combine exhaust flows at the merging junction. 9. An engine method, comprising: directing first and second exhaust gases through two separate exhaust passages into first and second opposite sides of an EGR cooler, respectively; directing the still separate first and second exhaust gases out of the EGR cooler through the second and first sides, respectively; and merging the exhaust gases to form a single exhaust conduit outside the EGR cooler. 10. The engine method of claim 9 , wherein the two exhaust passages are maintained completely separated within the EGR cooler from the inlets to the outlets. 11. The engine method of claim 9 , wherein the two exhaust passages enter and exit the EGR cooler in opposite directions. 12. The engine method of claim 9 , wherein the two exhaust passages are equal in length from a source to a merging junction at which the two exhaust passages form the combined exhaust conduit. 13. The engine method of claim 9 , wherein the EGR cooler further includes a coolant passage adjacent to the two exhaust passages. 14. The engine method of claim 13 , wherein the coolant passage contains a coolant that decreases the temperature of the exhaust gases flowing through the first and second exhaust passages to a suitable temperature for reentry into an intake manifold of an engine. 15. The engine method of claim 14 , wherein the coolant passage provides equal cooling to the exhaust gases flowing through the first and second exhaust passages, the exhaust gases merging downstream of the EGR cooler, the EGR cooler being a single, unitary, EGR cooler. 16. An exhaust gas recirculation (EGR) system, comprising: two parallel turbochargers; an EGR cooler coupled downstream of two exhaust manifolds and upstream of an EGR control valve; a first exhaust conduit connecting the first exhaust manifold to a first inlet of the EGR cooler; a second exhaust conduit connecting the second exhaust manifold to a second inlet of the EGR cooler, the second inlet located on an opposite surface to the first inlet; a coolant passage within the EGR cooler with an inlet and outlet located on opposite surfaces, the inlet and outlet fluidically connected to an external cooling system; two exhaust gas outlets on the EGR cooler located on opposite surfaces; and a merging junction connecting two conduits leading from the two exhaust gas outlets, the merging junction forming a single combined exhaust conduit that is connected to the EGR control valve. 17. The EGR system of claim 16 , wherein the exhaust flows in the first and second exhaust passages enter the EGR cooler in opposite directions. 18. The EGR system of claim 16 , wherein the exhaust flows in the first and second exhaust passages exit the EGR cooler in opposite directions. 19. The EGR system of claim 16 , wherein the coolant inlet and outlet are on different surfaces of the EGR cooler than the inlets and outlets of the first and second exhaust passages. 20. The EGR system of claim 16 , wherein the coolant passage, first exhaust passage, and second exhaust passage are contained in a single cooler housing.