Condition monitoring for an air separation module

The invention claimed is: 1. An air separation module comprising: a shell configured to house an air separation membrane; an inlet configured to receive supply air; an oxygen-enriched air outlet configured to exhaust oxygen from the air separation module; a nitrogen-enriched air outlet configured to supply a stream of nitrogen-enriched air to a fuel tank of an aircraft; a condition monitoring sensor integral with the air separation module and configured to measure at least one of a plurality of conditions, wherein the condition monitoring sensor is embedded in an element selected from a group consisting of the shell and an end plug of the air separation membrane; and a connector integral with the air separation module and configured to join the condition monitoring sensor with an electrical system of the aircraft, wherein the connector comprises a lead wire running through the shell. 2. The air separation module of claim 1 , wherein the shell comprises aluminum. 3. The air separation module of claim 2 , wherein the connector is fitted within a hole machined in the shell. 4. The air separation module of claim 1 , wherein the shell comprises a composite. 5. The air separation module of claim 4 , wherein the condition monitoring sensor is embedded in the composite. 6. The air separation module of claim 1 , wherein the connector is configured to receive an electrical connector of the electrical system. 7. The air separation module of claim 6 , wherein the connector and the electrical connector are secured by a fastener. 8. The air separation module of claim 7 , wherein the fastener is a quarter-turn fastener or a screw lock. 9. The air separation module of claim 4 , wherein the composite is selected from the group consisting of carbon fiber, aramid fiber, and polyethylene fiber. 10. The air separation module of claim 1 , wherein the condition monitoring sensor is embedded in the end plug of the air separation membrane. 11. The air separation module of claim 1 , wherein the condition monitoring sensor is selected from the group consisting of pressure transducers, temperature sensors, oxygen sensors, and ozone exposure indicators. 12. A method of assembling an air separation module, the method comprising: providing a shell; placing an air separation membrane within the shell; positioning a condition monitoring sensor within the shell such that the condition monitoring sensor is integral with the air separation module, wherein positioning the condition monitoring sensor comprises embedding the condition monitoring sensor within an element selected from a group consisting of the shell and an end plug of the air separation membrane; and joining the condition monitoring sensor with an electrical system of an aircraft by running a lead wire through the shell to connect the condition monitoring sensor to the electrical system. 13. The method of claim 12 , wherein positioning the condition monitoring sensor with the shell comprises embedding the condition monitoring sensor within the end plug of the air separation membrane. 14. The method of claim 12 , wherein positioning the condition monitoring sensor within the shell comprises installing the condition monitoring sensor within an aluminum shell. 15. The method of claim 14 , wherein joining the condition monitoring sensor with the electrical system of the aircraft comprises machining a hole in the aluminum shell and fitting a connector within the hole, wherein the lead wire connects to the condition monitoring sensor and an electrical connector of the electrical system of the aircraft via a fastener. 16. The method of claim 12 , wherein positioning the condition monitoring sensor within the shell comprises embedding the condition monitoring sensor within a carbon fiber composite. 17. The method of claim 16 , wherein joining the condition monitoring sensor with the electrical system of the aircraft comprises embedding the lead wire in layers of the carbon fiber composite. 18. The method of claim 16 , wherein joining the condition monitoring sensor with the electrical system of the aircraft comprises embedding a connector or a mounting plate for the connector within the carbon fiber composite, wherein the connector comprises the lead wire connecting the condition monitoring sensor and the electrical system of the aircraft via a fastener. 19. An air separation module comprising: a shell configured to house an air separation membrane; an inlet configured to receive supply air; an oxygen-enriched air outlet configured to exhaust oxygen from the air separation module; a nitrogen-enriched air outlet configured to supply a stream of nitrogen-enriched air to a fuel tank of an aircraft; a condition monitoring sensor integral with the air separation module and configured to measure at least one of a plurality of conditions, wherein the condition monitoring sensor is embedded in an end plug of the air separation membrane; and a connector integral with the air separation module and configured to join the condition monitoring sensor with an electrical system of the aircraft.