Abstract
The aircraft electro-thermal anti-icing system that can guarantee flight safety may be affected by periodic heating and cyclic aerodynamic force during long-term flight missions, which seems to be a potential threat to ice protection. This paper aims to investigate the impacts of thermal and mechanical cycles on heating elements of the electro-thermal anti-icing system. Specimens were manufactured with CFRP (carbon fiber reinforced polymer) laminated composite, glass fiber prepreg and copper screen, in which sprayable metal film (SMF) was embedded as the heating element. The study focuses on electric resistance variation of SMF and functional fatigue life under the cycling load. Thermal cycling tests were carried out in an insulated chamber where the specimens were heated up to 80 °C and then cooled down to −55 °C for 1000 cycles. Mechanical cycling tests were conducted on a fatigue testing machine where the specimens were imposed on tension-compression loading for 106 cycles. Results showed that the electric resistance of SMF increased with the number of loading cycles. The resistance was increased by 20% and the heating power was decreased by 16.67% after 1000 thermal cycles. During the mechanical cycling tests, it was found that the heating element was destructed before the structural failure, which indicated that the fatigue life of function was lower than that of the structure.
Highlights
When an aircraft is flying through clouds with super-cooled water droplets, it has a great chance of icing
The hot-air anti-icing system with carbon fiber reinforced polymer (CFRP) composite requires a large amount of hot air bled from engines, which reduces the efficiency of the engines and adds weight as well as maintenance
The real-time electric resistance of sprayable metal film (SMF) along with the number of cycles was measured to find out the influence of cycling loads on the heating performance and fatigue life of the system
Summary
When an aircraft is flying through clouds with super-cooled water droplets, it has a great chance of icing. The application of composite materials on aircraft increased significantly due to their remarkable properties such as high strength-to-weight ratios, corrosion resistance, and excellent fatigue endurance. The hot-air anti-icing system with CFRP composite requires a large amount of hot air bled from engines, which reduces the efficiency of the engines and adds weight as well as maintenance. The electro-thermal anti-icing system with CFRP composite has the advantages of simple and clean installation, convenient controllability, and efficient thermal response [5], which has attracted considerable research interest. This combination becomes highly applicable to the development of future aircraft that demands lightweight and eco-efficient systems and structures [6]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
