Carbon Fibre-Reinforced Polymer Laminates with Film Cooling: Thermo-Mechanical Performance Under Moderate Heat Flux

Trista Yuting MA, Nam Kyeun KIM, Tom ALLEN

DOI Number: N/A

Conference number: HiSST-2025-361

Though carbon fibre-reinforced polymer (CFRP) composites have been extensively researched and used as structural components in aerospace applications, their relatively low thermal resistance has limited their adoption in high-speed vehicles. Integrating film cooling with CFRP structures has the potential to decrease thermal degradation, extending their use towards moderate heat flux zones in high-speed vehicles and pushing working temperatures beyond the conventional capabilities of CFRPs. However, no studies have been conducted to date on the coupled mechanical and thermal behaviour of film-cooled CFRPs under high temperatures, particularly over 500°C. This study investigates the mechanical
degradation of film-cooled CFRP laminates having diameter, smaller than 1 mm perforations, as well as quantifying their thermal response. The laminate is exposed to steady-state heat flux ranging from 11.6 kW/m2 to 30 kW/m2 for 255 seconds to obtain its film cooling effectiveness using eight type-K thermocouples. Preliminary experimental results indicate a surface temperature reduction up to 55% on a 3mm-thick CFRP laminate. A hole-diameter-to-thickness (d/t) ratio of equal to 0.1, corresponding to a hole diameter of 0.3mm demonstrated no reduction in tensile and compressive strength.

Read the full paper here

Carbon Fibre-Reinforced Polymer (CFRP), Film Cooling, Open-hole Structural Degradation, Thermal Protection System

In Categories: 1.Events, 1.HiSST 2025, Materials and Structures for vehicle and all subsystems

The paper above was part of proceedings of a CEAS event and as such the author has signed a publication agreement to have their paper published in the repository. In the case this paper is found somewhere else CEAS always links to the other source. CEAS takes great care in making the correct content available to the reader. If any mistakes are found in the listings please contact us directly at papers@aerospacerepository.org and we will correct the listing promptly. CEAS cannot be held liable either for mistakes in editorial or technical aspects, nor for omissions, nor for the correctness of the content. In particular, CEAS does not guarantee completeness or correctness of information contained in external websites which can be accessed via links from CEAS’s websites. Despite accurate research on the content of such linked external websites, CEAS cannot be held liable for their content. Only the content providers of such external sites are liable for their content. Should you notice any mistake in technical or editorial aspects of the CEAS site, please do not hesitate to inform us.