Acoustic Emission from Depressurization to Detect/Evaluate Significance of Impact Damage to Graphite/Epoxy Pressure Vessels

Autor:	Marvin A. Hamstad, K. S. Downs
Rok vydání:	1998
Předmět:	Materials science business.industry Mechanical Engineering Instrumentation 02 engineering and technology Epoxy 021001 nanoscience & nanotechnology Pressure vessel 020303 mechanical engineering & transports 0203 mechanical engineering Acoustic emission Cabin pressurization Mechanics of Materials Nondestructive testing visual_art Materials Chemistry Ceramics and Composites visual_art.visual_art_medium Graphite Proof test Composite material 0210 nano-technology business
Zdroj:	Journal of Composite Materials. 32:258-307
ISSN:	1530-793X 0021-9983
DOI:	10.1177/002199839803200304
Popis:	Six aerospace-type, filament-wound graphite/epoxy pressure vessels were studied. Four of these cylindrical vessels had each received a single, controlled impact; four had received thermal exposures including moderate heat and/or cryogenic cold. Acoustic emission (AE) was monitored during a proof test sequence (after the impact/thermal exposure), including the final depressurization from proof pressure (i.e., the second unload cycle). A single set of wideband AE sensors was used to simultaneously record parameter-based AE and waveform-based AE on two independent AE instrumentation systems. Some slight to moderately large differences in AE activity for impacted vs. non-impacted vessels were noted for AE from Felicity ramps and holds at pressure. However, dramatic differences were apparent in quantities of AE from the final depressurization cycle: impacted vessels experienced unload AE activity which was a minimum of an order of magnitude greater in quantity than the unload AE activity for non-impacted vessels. This difference provided a distinctive means of identifying those vessels with impact damage. A newly defined "Shelby ratio" was introduced as a means of quantitatively assessing the unload AE; correlations were obtained between vessels' residual strength and the unload "Shelby ratios." Refinements of the parameter-based data analysis approach were made possible by waveform information. Additionally, examination of the waveform data of the unload cycle revealed a significant quantity of "friction" type waveforms having a repeated, lower frequency character; similar "friction" waveforms were able to be artificially generated by rubbing a pencil lead across a composite vessel surface.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_________::92dc462051571ee54c4550b47c632ad5 https://doi.org/10.1177/002199839803200304 Zobrazit plný text záznamu