Current inspection techniques utilized in the aircraft industry require a structure to be taken out of service, which can be a time consuming and expensive process. The proposed smart structure will yield continuous and real time measurement of critical parameters, and feed this information to an aircraft pilot, or perhaps technicians assigned to monitor the performance of a number of bridges.

The initial sensing of a smart composite material can be achieved with optical fibers which can act as both sensor and data transmitter. There are a variety of fiber optic sensors which can measure such external forces as pressure, temperature, strain, and vibration. A key advantage with embedded optical fibers is that their small size does not greatly effect the mechanical properties of the composite reinforcement.

The issues to be addressed in the present study include:

• the manufacturing technology for the smart composite reinforcements, from hand layup fabrication to more automated processes such as pultrusion, filament winding, or tape laying;

• the choice of appropriate fiber optic sensors;

• interconnection of components;

• application for the non-destructive testing and monitoring of structures; and

• comparison with the traditional testing techniques.

Acknowledgment

This work has been supported by the ISIS-CANADA NCE (The Intelligent Sensing in Innovative Structures Canadian Network of Centres of Excellence) through the Project T3.4 on Smart Reinforcements and Connectors. REFERENCES

1. A. L. Kalamkarov, "Composite and Reinforced Elements of Construction", Chichester, New York: John Wiley & Sons, 1992
2. A. T. Alavie, R. Maaskant, M. M Ohn, S. Rizkalla and R. M. Measures, "Application and Characterization of Intracore Grating Sensors in a CFRP Prestressed Concrete Girder", Proc. "Smart Materials and Structures", SPIE-Vol. 2191, Orlando, February 1994.