Adjustable, low loss valve for providing high pressure loop exhaust gas recirculation

What is claimed is: 1. An engine exhaust system for an engine that is coupled to a turbocharger, the engine exhaust system comprising an exhaust passage that connects the turbocharger to an exhaust of the engine; a valve disposed in the exhaust passage, the valve configured to generate pressure to drive high pressure exhaust gas recirculation to the engine, the valve including a first end that faces a flow of exhaust gas within the exhaust passage; a second end opposed to the first end; a valve longitudinal axis that extends through both the first end and the second end; a valve outer surface that is configured to conform to the shape and dimensions of the exhaust passage; and a valve inner surface that has a curvilinear profile when viewed in longitudinal cross section; and an actuator connected to the valve, the actuator configured to move the valve relative to the exhaust passage so as to control exhaust gas pressure within the exhaust passage, wherein the actuator is disposed such that the actuator movement is generally parallel to a direction of flow of exhaust gas contacting the valve. 2. The engine exhaust system of claim 1 wherein the valve inner surface defines a converging portion that adjoins the first end and a diverging portion disposed between the converging portion and the second end. 3. The engine exhaust system of claim 1 wherein the valve inner surface defines a first concave portion adjoining the first end, a second concave portion adjoining the second end, and a convex portion disposed between the first concave portion and the second concave portion. 4. The engine exhaust system of claim 3 , wherein the valve inner surface defines a smoothly curving surface. 5. The engine exhaust system of claim 1 , wherein the valve inner surface is configured so that the intersection of the valve with a first plane that is transverse to the valve longitudinal axis defines a first line at the valve inner surface, the first line is parallel to an axis that is transverse to the valve longitudinal axis, for any location of the first plane between the first end and the second end, and a second line that is defined by the intersection of a second transverse plane with the valve is parallel to the first line regardless of the axial location of the second transverse plane. 6. The engine exhaust system of claim 1 , wherein the valve is disposed in the exhaust passage such that the valve longitudinal axis is generally parallel to a direction of flow of exhaust gas within the exhaust passage. 7. The engine exhaust system of claim 1 , wherein the valve is disposed in the exhaust passage at a location upstream relative to the turbocharger. 8. The engine exhaust system of claim 7 , wherein a pilot tube is disposed in the exhaust passage, and the pilot tube is connected to an air intake of the engine via a duct, and is configured to increase pressure of gas introduced into the engine. 9. The engine exhaust system of claim 7 , wherein a pilot tube is disposed in the exhaust passage at a location corresponding to the valve, and the pilot tube is connected to an air intake of the engine via a duct, and is configured to increase pressure of gas introduced into the engine. 10. The engine exhaust system of claim 1 , comprising a pilot tube disposed in the exhaust passage so as to be aligned with a flow stream of exhaust gas within the exhaust passage, wherein the pilot tube includes a leading edge facing the flow stream and configured to reduce the velocity of the flow stream, a pilot tube internal passageway that opens in the leading edge at a location in which the flow stream has a maximum velocity, wherein the pilot tube internal passageway is connected to an air intake of the engine via duct, and when exhaust gas flows within the exhaust passage past the pilot tube, pressure within the pilot tube internal passageway is increased, whereby pressure of gas introduced into the air intake is increased. 11. The engine exhaust system of claim 10 , wherein the pilot tube is located within the exhaust passage at an axial location corresponding to the axial location of the valve. 12. The engine exhaust system of claim 1 , wherein the actuator is connected to the valve via a rod, the actuator is disposed externally of the exhaust passage, and the rod passes through an opening in a wall of the exhaust passage, a seal is disposed in the opening that provides a seal between the rod and the wall of the exhaust passage, a pressure drain is provided in the wall of the exhaust passage], and the pressure drain opens adjacent the seal. 13. The engine exhaust system of claim 12 , wherein the seal comprises a first piston ring and a second piston ring that are disposed in the opening and provide a labyrinth seal between the rod and the wall of the exhaust passage, and the pressure drain opens between the first piston ring and the second piston ring. 14. The engine exhaust system of claim 1 , further comprising at least one of the engine and the turbocharger. 15. The engine exhaust system of claim 1 , wherein the valve inner surface is spaced apart from a facing surface of the exhaust passage, regardless of valve position. 16. An engine exhaust system for an engine that is coupled to a turbocharger, the engine exhaust system comprising an exhaust passage that connects the turbocharger to an exhaust of the engine; a valve disposed in the exhaust passage, the valve configured to generate pressure to drive high pressure exhaust gas recirculation to the engine, the valve including a first end that faces a flow of exhaust gas within the exhaust passage; a second end opposed to the first end; a valve longitudinal axis that extends through both the first end and the second end; a valve outer surface that is configured to conform to the shape and dimensions of the exhaust passage; and a valve inner surface that has a curvilinear profile when viewed in longitudinal cross section; and an actuator connected to the valve, the actuator configured to move the valve relative to the exhaust passage so as to control exhaust gas pressure within the exhaust passage, wherein the actuator is disposed such that the actuator movement is generally parallel to a direction of flow of exhaust gas within the exhaust passage; wherein the actuator is connected to the valve via a rod, the actuator is disposed externally of the exhaust passage, and the rod passes through an opening in a wall of the exhaust passage; wherein the seal comprises a first piston ring and a second piston ring that are disposed in the opening and provide a labyrinth seal between the rod and the wall of the exhaust passage, and the pressure drain opens between the first piston ring and the second piston ring; and, wherein the pressure drain includes a first end that opens between the first piston ring and the second piston ring, and a second end that opens in the exhaust passage at a location disposed between the turbocharger and an exhaust after-treatment device. 17. A valve configured to control the flow of fluid in a passageway, the valve comprising a first end that faces a flow of fluid within the passageway; a second end opposed to the first end; a valve longitudinal axis that extends through both the first end and the second end; a valve outer surface that is configured to conform to the shape and dimensions of the passageway; and a valve inner surface that has a curvilinear profile when viewed in longitudinal cross section; wherein the entire valve is constructed and arranged to move longitudinally in the pa