Laser ultrasonic is currently the optimal method for non-destructive testing of composite materials in the aerospace industry. The process is based on a laser-generated, ultrasound wave which propagates inside the composite. The response at the material surface is detected and converted into a defect map across the aircraft. The design and optimization of a laser system for this application, together with the basic science involved, is reviewed in this paper. This includes the optimization of laser parameters, such as output couplers and gas mixture, and the impact these choices have on the laser chemistry. We present a theory for the catalytic recombination of the gas which shows excellent agreement with experiment. Finally, an operating laser system for this application, yielding a six fold improvement in performance over conventional laser systems, is described.
Reference:
Forbes, A, et al. 2006. Design and optimisation of a pulsed CO2 laser for laser ultrasonic applications. South African Journal of Science 102, July/August 2006, Vol. 102(7/8), pp 329-334
Forbes, A., Botha, L., Du Preez, N., & Drake, T. (2006). Design and optimisation of a pulsed CO2 laser for laser ultrasonic applications. http://hdl.handle.net/10204/978
Forbes, A, LR Botha, N Du Preez, and TE Drake "Design and optimisation of a pulsed CO2 laser for laser ultrasonic applications." (2006) http://hdl.handle.net/10204/978
Forbes A, Botha L, Du Preez N, Drake T. Design and optimisation of a pulsed CO2 laser for laser ultrasonic applications. 2006; http://hdl.handle.net/10204/978.
