Heat exchanger for a gas turbine engine propulsion system

What is claimed is: 1. A propulsion system for an aircraft, the propulsion system comprising: a gas turbine engine including an engine core and a fan coupled to the engine core for rotation about an engine axis, the fan configured to discharge pressurized bypass air that is passed around the engine core, and a nacelle surrounding a portion of the gas turbine engine, the nacelle including an outer shroud arranged around the gas turbine engine, a strut that extends radially between the outer shroud and the gas turbine engine, and a cooling unit housed in the strut, the cooling unit fluidly coupled to the gas turbine engine to cool fluid or gas from the gas turbine engine to provide a cooled fluid or gas and return the cooled fluid or gas to the gas turbine engine, wherein the cooling unit includes a duct located in the strut to conduct continuously a portion of the pressurized bypass air through the duct and the strut during operation of the gas turbine engine, a heat exchanger positioned within the duct, and a diverter valve that is movable within the duct from a first position arranged to direct the portion of the pressurized bypass air conducted through the duct toward and into contact with the heat exchanger to a second position arranged to divert the portion of the pressurized bypass air conducted through the duct away from and around the heat exchanger and away from and around any other heat exchanger positioned in the duct to avoid pressure loss caused by directing the portion of the pressurized bypass air into contact with the heat exchanger, wherein the duct includes a first wall housed in the strut and a second wall housed in the strut and spaced circumferentially apart from the first wall relative to the engine axis, the first and second walls extending radially outwardly away from the engine axis and extending axially relative to the engine axis, and wherein the heat exchanger is positioned between the first wall and a guide post that is located circumferentially between the first wall and the second wall, and the diverter valve is located adjacent the guide post and configured to move relative to the guide post between the first position in which the diverter valve engages the second wall and the second position in which the diverter valve engages the first wall. 2. The propulsion system of claim 1 , wherein the cooling unit is positioned radially-outward of the engine core and radially-inward of an outer shroud included in the nacelle. 3. The propulsion system of claim 1 , wherein the duct includes a divider extending along the length of the duct to divide the duct into an outer flow portion and an inner flow portion positioned radially-inward of the outer flow portion. 4. The propulsion system of claim 1 , wherein the diverter valve includes a first actuator and a plate coupled to the first actuator, the first actuator operable to pivot the plate relative to the duct between the first and the second positions. 5. The propulsion system of claim 4 , wherein the diverter valve includes a second actuator coupled to the plate, the second actuator operable to move the plate relative to the duct between the first and the second positions in the event of a failure of the first actuator. 6. The propulsion system of claim 1 , wherein (i) the heat exchanger has a core having a face, and (ii) the portion of the pressurized bypass air directed into contact with the heat exchanger by the diverter valve when the diverter valve is in the first position is conducted by a header included in the duct to the core at an angle to the face that is different from 90 degrees. 7. The propulsion system of claim 6 , wherein the portion of the pressurized bypass air directed into contact with the heat exchanger by the diverter valve when the diverter valve is in the first position is conducted by the header from an inlet of the duct to the core of the heat exchanger along a forward flow path generally parallel to an aft flow path along which the portion of the pressurized bypass air is conducted away from the heat exchanger to an outlet of the duct. 8. The propulsion system of claim 1 , wherein (i) the fan is configured to discharge the pressurized bypass air in a direction having a circumferential component and an axial component at an outlet thereof, and (ii) an inlet of the duct is shaped to open axially and circumferentially to receive the portion of the pressurized bypass air discharged from the fan so that the total pressure of the portion of the pressurized bypass air is captured by the duct during operation of the propulsion system. 9. The propulsion system of claim 1 , wherein the duct includes an inlet and an outlet spaced axially aft of the inlet relative to the engine axis and the diverter valve is spaced apart axially from both the inlet and the outlet of the duct. 10. The propulsion system of claim 1 , wherein the heat exchanger includes a first end located adjacent the first wall and a second end spaced apart circumferentially from the first and second walls to define a circumferential gap between the second wall and the second end of the heat exchanger. 11. The propulsion system of claim 10 , wherein the guide post includes a forward curved surface that engages the diverter valve and an aft curved surface opposite the forward curved surface that receives the second end of the heat exchanger to locate the heat exchanger between the first wall and the guide post. 12. The propulsion system of claim 11 , wherein the diverter valve includes a first actuator and a plate coupled to the first actuator, the first actuator operable to pivot the plate relative to the guide post between the first position to engage the plate with the second wall and the second position to engage the plate with the first wall. 13. An aircraft comprising: an airframe, a gas turbine engine supported by the airframe, the gas turbine engine including an engine core defining an engine axis and a fan coupled to the engine core, the fan configured to discharge pressurized bypass air that is passed around the engine core, and a nacelle supported by the airframe and surrounding a portion of the gas turbine engine, the nacelle including an outer shroud arranged around the gas turbine engine, a strut that extends outwardly from the gas turbine engine radially between the outer shroud and the gas turbine engine relative to the engine axis, and a cooling unit housed in the strut that is fluidly coupled to the gas turbine engine to cool fluid or gas from the gas turbine engine, wherein the cooling unit is configured to receive continuously a portion of the pressurized bypass air from the fan during operation of the gas turbine engine and to pass the portion of the pressurized bypass air through a heat exchanger included in the cooling unit during operation of the aircraft, wherein the cooling unit includes a duct housed in the strut and a diverter valve located in the duct, the heat exchanger is located in the duct, and the diverter valve is movable within the duct from a first position arranged to direct the portion of the pressurized bypass air conducted through the duct toward the heat exchanger to a second position arranged to divert the portion of the pressurized bypass air conducted through the duct away from the heat exchanger, wherein the duct includes a first wall housed in the strut, a second wall housed in the strut and spaced circumferentially apart from the first wall relative to the engine axis, and a guide post located circumferentially between both the first wall and the second wall to define a first passage between the first wall and the guide post and a second passage between the second wall