Abstract
Composite materials have increasingly become a high proportion of the structural weight of aircraft due to their excellent performances. Different types of damages may occur in the aircraft service period, which will bring potential safety risks to aircrafts. To investigate the defect damage detection and its spectral characteristics and imaging of carbon-fiber-reinforced polymer composite laminates, defects from the low-velocity impact damage in composites were measured by the THz time-domain reflection imaging system. Results show that there exists obvious THz spectral differences between the impact damaged defects and nondefect. The effective detection frequency band for the low-speed impact damaged defect is 0.12–2.0 THz. In the time domain, there are attenuations and delays in the spectra of defects relative to those of nondefects. In the frequency domain, with the increase of frequency, the power spectral density of the defect first increases and then decreases, and the absorption coefficient increases slowly. In general, the imaging results in time-domain imaging are better than those from the frequency-domain imaging, which not only is suitable for the qualitative detection of defects but also has great potential and application prospects in quantitative detection. This work shows an important guide for the application of THz technology to detect the composite material defects in civil aircraft.
Highlights
Composite materials have been widely used in the aviation field because of their high specific strength, stiffness, and good fatigue and corrosion resistances, and their proportion in the structural weight of aircraft has significantly increased [1, 2]
To our knowledge, there is no report of the detection and analysis of low-velocity impact damage defects of carbon-fiber-reinforced polymer (CFRP) composites by terahertz spectroscopy and imaging technology
The impact damage defects in CFRP composite laminates were investigated by terahertz time-domain spectroscopy and imaging technology. e maximum peak, minimum peak, maximum flight time, minimum flight time, and characteristic points of differences between peak and amplitude and between power spectral density and absorption coefficient of frequency-domain signals were applied. e time- and frequency-domain measurement data were compared and analyzed, and the imaging analyses of time-domain, power spectral density, and absorption coefficient data were carried out separately according to the spectral characteristics of the defects
Summary
Composite materials have been widely used in the aviation field because of their high specific strength, stiffness, and good fatigue and corrosion resistances, and their proportion in the structural weight of aircraft has significantly increased [1, 2]. Many nondestructive testing technologies for civil aircraft exist, including laser ultrasonic methods [8, 9], Journal of Spectroscopy infrared thermal imaging method [10,11,12], and electronic speckle pattern interferometry (ESPI) [13, 14]. To our knowledge, there is no report of the detection and analysis of low-velocity impact damage defects of carbon-fiber-reinforced polymer (CFRP) composites by terahertz spectroscopy and imaging technology. Terahertz time-domain spectroscopy and imaging technology were used to nondestructively detect low-velocity impact damage defects in CFRP composite laminates. Terahertz time-domain spectroscopy and imaging technology were used to nondestructively detect low-velocity impact damage defects in CFRP composite laminates. e terahertz spectra of defects were extracted, and their characteristics were systematically analyzed. e time- and frequency-domain imaging displays of defects were obtained, and the detection of these defects was discriminated and analyzed
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
