Context:

The current and future generations of aircrafts and helicopters are increasingly made of composite materials for structural weight savings. However the main drawback of replacing aluminum by composite is an important decrease of the electrical conductivity, which leads to serious consequences for the aircraft and the electronic systems lightning strike protection (LSP). A popular protection approach is to bond a copper mesh on the outer surface of the composite structure using a polymeric resin. This method provides a good LSP but this surface material is heavy, which counterbalances the utilization of composite materials to save weight in the first place. In this project, we propose to develop a lightweight surface material or coating for composite structures in order to improve their electrical conductivity for efficient lightning strike protection while featuring the desired characteristics: high electromagnetic protection, high mechanical resistance, good environmental protection, flexible manufacturability and moderate costs. The advanced material investigation will cover the design of nanocomposites (i.e. mixture of polymer with nanoscopic scale particles for enhanced electrical conductivity. These potential solutions will be electrically characterized with different non- and destructive tests including the testing under high currents using a custom-made screening setup. This multidisciplinary CRIAQ project will be in collaboration between an academic research team from three different institutions and three industrial partners (Bombardier Aerospace, Bell Helicopter Textron Canada Ltd and 3M). This project is directly related to the development of safer public transportation and environmentally friendly "greener" airplanes. It is supported by Canada and Quebec governments.

Projects: (2 masters)

The master's student will be in charge of building, testing and calibrating the 30-50 kA lightning stroke emulator test setup. He will base his realization on a design provided by other researchers and Ph.D. student. This project is relatively technical and will require a significant implication from the supervisor (F. Sirois). It is a key element for the success of the project.

Once the testing setup is ready, another master's student will undertake series of measurements on the various test samples proposed in the project, and will assist the Ph.D. student in the preliminary damage analysis of each sample tested, as well as with the characterization of the sample's damages.