Abstract
Aircraft structural damage detection is becoming of increased importance. Technologies such as acousto-ultrasonic have been suggested for this application; however, an optimization strategy for sensor network design is required to ensure a high detection probability while minimizing sensor network mass. A methodology for optimizing acousto-ultrasonic transducer placement for adhesive disbond detection on metallic aerospace structures is presented. Experimental data sets were acquired using three-dimensional scanning laser vibrometry enabling in-plane and out-of-plane Lamb wave components to be considered. This approach employs a novel multi-sensor site strategy which is difficult to achieve with physical transducers. Different excitation frequencies and source–damage–sensor paths were considered. A fitness assessment criterion which compared baseline and damaged data sets using cross-correlation coefficients was developed empirically. Efficient sensor network optimization was achieved using a bespoke genetic algorithm for different network sizes with the effectiveness assessed and discussed. A comparable numerical data set was also produced using the local interaction simulation approach and optimized using the same methodology. Comparable results with those of the experimental data set indicated a good agreement. As such, the numerical approach demonstrates that acousto-ultrasonic sensor networks can be optimized using simulation (with some further refinement) during an aircraft design phase, being a useful tool to sensor network designers.
Highlights
There is increasing pressure on the aviation industry to reduce greenhouse emissions resulting from airline operations
Attenuation of the wave increases with excitation frequency resulting in a greater reduction of amplitude as the wave propagates which is an important consideration for sensor network design and selecting appropriate excitation frequencies. These results show that fitness increases as the number of sensors in the sensor network increases demonstrating that more sensors in the network improve damage sensitivity
It is evident that increasing the excitation frequency improves the fitness of the sensor networks for both the out-of-plane and three-component magnitude cases. 300 kHz delivered the fittest solutions due to experimental constraints, excitation frequencies greater than this were not considered so it is not possible to determine whether higher excitation frequencies would yield further improvements in fitness
Summary
There is increasing pressure on the aviation industry to reduce greenhouse emissions resulting from airline operations. Emissions can be lowered by reducing the mass of the primary structure leading to lower overall fuel burn throughout the aircraft’s operational lifecycle. This can be achieved using adhesive bonding techniques in place of traditional mechanical fastening methods which have increased strength to mass ratios while having improved structural performance and integrity.[3,4] Despite the mass, cost and manufacturing benefits of bonded joints,[5] there is lack of engineering confidence in their. International Journal of Distributed Sensor Networks use,[6] in the hostile environments that the bond will experience (i.e. varying temperatures, water ingress and high levels of humidity).[7,8,9] This has led to over engineered, heavy design solutions[10] typically using adhesives combined with arrestment fasteners.[11]
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