Heat exchanger systems and methods for controlling airflow cooling

What is claimed is: 1. A bypass pre-cooler comprising: a housing; an inlet configured to receive core engine airflow into the housing from one or more aircraft ducts; a heat exchanger within the housing; a bypass section within the housing having an airflow path separate from and surrounding the heat exchanger; a sleeve valve having an outer surface forming with the housing an annular inlet section of the bypass section, the sleeve valve coupled to the inlet and configured to switch airflow between the heat exchanger and the bypass section using circumferentially spaced ports; an outlet coupled to the heat exchanger and the bypass section; at least one processor; a pressure sensor coupled to the at least one processor, wherein the pressure sensor monitors an air pressure downstream from the housing; and an actuator coupled to the at least one processor and the sleeve valve to control opening and closing of the sleeve valve, wherein the at least one processor controls opening and closing of the sleeve valve based on the air pressure downstream of the housing as monitored by the pressure sensor. 2. The bypass pre-cooler of claim 1 , wherein the one or more ducts comprise a first duct extending from a low pressure section of the core engine airflow and a second duct extending from a high pressure section of the core engine airflow. 3. The bypass pre-cooler of claim 1 , wherein the inlet comprises a diffusion section. 4. The bypass pre-cooler of claim 1 , further comprising a double wall structure within the housing forming the bypass section. 5. The bypass pre-cooler of claim 1 , further comprising a pipe manifold forming the bypass section. 6. The bypass pre-cooler of claim 1 , wherein the heat exchanger comprises a plate fin air heat exchanger. 7. The bypass pre-cooler of claim 1 , wherein the at least one processor delays switching over to a high pressure stage from a low pressure stage by controlling the actuator to bypass the airflow around the heat exchanger. 8. A method of pressurizing an aircraft cabin, the method comprising: operating an aircraft engine; ducting bleed air from the aircraft engine at a high pressure stage and a low pressure stage of the engine; ducting the bleed air to a bypass pre-cooler within a housing, the bypass pre-cooler having a heat exchanger and a bypass section separate from and surrounding the heat exchanger; monitoring an air pressure downstream from the bypass pre-cooler with a pressure sensor; and using a processor to control a sleeve valve of the bypass pre-cooler based on the monitored air pressure downstream of the bypass pre-cooler to duct the bleed air through the heat exchanger or an annular inlet section of the bypass section; the annular inlet section of the bypass section formed between an outer surface of the sleeve valve and the housing. 9. The method of claim 8 , further comprising diffusing the bleed air at an inlet of the bypass pre-cooler. 10. The method of claim 8 , wherein the valve of the bypass pre-cooler comprises a sleeve valve and the heat exchanger comprises a plate fin air heat exchanger. 11. The method of claim 8 , wherein the bypass pre-cooler further comprises a pipe manifold forming the bypass section. 12. The method of claim 8 , further comprising delaying switching over to the high pressure stage from the low pressure stage, wherein the delaying comprises bypassing the heat exchanger. 13. An aircraft engine comprising: a first duct extending from a low pressure section of a core engine flow; a second duct extending from a high pressure section of the core engine flow; a bypass pre-cooler within a housing, having a heat exchanger, a bypass section separate from and surrounding the heat exchanger, and an inlet coupled to the first and second ducts, the bypass pre-cooler having a sleeve valve coupled to the inlet; the sleeve valve having an outer surface forming with the housing an annular inlet section of the bypass section, and configured to switchably couple the inlet to the heat exchanger and the bypass section within the bypass pre-cooler via circumferentially spaced ports; at least one processor; a pressure sensor coupled to the at least one processor, wherein the pressure sensor monitors an air pressure downstream from the bypass pre-cooler; and an actuator coupled to the at least one processor and the sleeve valve to control opening and closing of the sleeve valve, wherein the at least one processor controls opening and closing of the sleeve valve based on the air pressure downstream of the bypass pre-cooler as monitored by the pressure sensor. 14. The aircraft engine of claim 13 , wherein the inlet comprises a diffusion section. 15. The aircraft engine of claim 13 , wherein the bypass pre-cooler further comprises a double wall structure within a housing forming the bypass section. 16. The aircraft engine of claim 13 , wherein the bypass pre-cooler further comprises a pipe manifold forming the bypass section. 17. The aircraft engine of claim 13 , wherein the heat exchanger comprises a plate fin air heat exchanger. 18. The aircraft engine of claim 13 , wherein the at least one processor delays switching over to a high pressure from a low pressure stage by controlling the actuator to bypass the core engine flow around the heat exchanger.