Objective

Image of corrosion pits (1 mm diameter) acquired with real-time ultrasound camera (left). F-18 intake panel with corrosion (white areas) detected under paint using pulse thermography system (right).

The Department of Defense (DoD) has numerous high performance weapon platforms that require stringent monitoring of the structural integrity of the platforms owing to these structures' low tolerance for corrosion and/or cracks. The need to inspect the substrates of these platforms for corrosion, fatigue cracks, and other operationally induced damage is very time consuming and costly, often necessitating the removal and subsequent replacement of the coating system, not to mention the handling of the hazardous wastes associated with these materials and processes. The paint, stripping, and repainting process generates significant and costly pollutant streams such as volatile organic compounds (VOCs) and hazardous air pollutants (HAPs). Environmental regulations limit emissions of VOCs and HAPs, and DoD efforts to attain compliance have identified removal and reapplication of coatings as major contributors to the emissions problems at DoD facilities. Developing realistic and practical nondestructive evaluation (NDE) technologies for "inspection-through-paint" is considered to be one means by which the DoD can extend the service life of coatings systems, extend the life of aging weapons systems, meet the increasingly stringent environmental requirements, and increase operational capability with limited assets.

The objective of this project was to develop and evaluate three technologies for their viability as NDE tools for the detection of cracks and corrosion under surface coatings.