Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
The conducted research suggests possibility of replacing extruded polystyrene with a renewable cork-based material in laminated composite structures. Different fractions of the cork-based material of a composite laminate have been applied. The composites have been tested employing a hammer-focused vibration method. Conforming to obtained results, the cork-based material of smaller fraction has damping properties similar to those of the extruded polystyrene composite. Integrating cork into the structure of the composite has the opportunity to develop a more eco-friendlier and sustainable product and to improve the adaptive properties of passive control systems used for vibration damping applications operating in the middle and high frequency zones.
Słowa kluczowe
Czasopismo
Rocznik
Tom
Strony
593--602
Opis fizyczny
Bibliogr. 25 poz., rys.
Twórcy
autor
- Vilnius Gediminas Technical University, Department of Mobile Machinery and Railway Transport, Vilnius, Lithuania
autor
- Vilnius Gediminas Technical University, Antanas Gustaitis’ Aviation Institute, Vilnius, Lithuania
Bibliografia
- 1. A WWF Report, 2006, Cork Screwed? Environmental and Economic Impacts of the Cork Stoppers Market. Minnesota University, WWF Mediterranean Programme Office.
- 2. Alsahlani A., Rahulan T., 2017, Aerofoil design for unmanned high-altitude aft-swept flying wings, Journal of Aerospace Technology and Management, 9, 3, 335-345.
- 3. Bishay P., Aguilar C., 2021, Parametric study of a composite skin for a twist-morphing wing, Aerospace, 8, 9, 259.
- 4. Bogdevičius M., Karpenko M., Bogdevičius P., 2021, Determination of rheological model coefficients of pipeline composite material layers based on spectrum analysis and optimization, Journal of Theoretical and Applied Mechanics, 59, 2, 265-278.
- 5. Cascell® RS Machine Department. Material for an aviation, aerospace, sports equipment.
- 6. Chanzy Q., Keane A., 2018, Analysis and experimental validation of morphing UAV wings, The Aeronautical Journal, 122, 1249, 390-408.
- 7. De Breuker R., Werter N., 2016, On the importance of morphing deformation scheduling for actuation force and energy, Aerospace, 3, 4, 41.
- 8. Drescher O., Hörschgen-Eggers M., Pinaud G., Podeur M., 2017, Cork based thermal protection system for sounding rocket applications – development and flight testing, 23rd ESA PAC Symposium, Visby, Schweden.
- 9. Fernandes F., Alves de Sousa R.J., Ptak M., Migueis G., 2019, Helmet design based on the optimization of biocomposite energy-absorbing liners under multi-impact loading, Applied Sciences, 9, 4, 1-26.
- 10. George J., Vasudevan A., Mohanavel V., 2021, Vibration analysis of interplay hybrid composite for an aircraft wing structure, Materials Today: Proceedings, 37, 2, 2368-2374.
- 11. Gil L., 2014, Cork: a strategic material, Frontiers in Chemistry, 2, 16, 1-2.
- 12. Gürgen S., Sofuoğlu M., 2021, Smart polymer integrated cork composites for enhanced vibration damping properties, Composite Structures, 258, 113200.
- 13. Kaczynski P., Ptak M., Wilhelm J., Fernandes F., Alves de Sousa R.J., 2019, High-energy impact testing of agglomerated cork at extremely low and high temperatures, International Journal of Impact Engineering, 126, 109-116.
- 14. Lubecki M., Stosiak M., Bocian M., Urbanowicz K., 2021, Analysis of selected dynamic properties of the composite hydraulic microhose, Engineering Failure Analysis, 125, 105431.
- 15. Mestre A., Vogtlander J., 2013, Eco-efficient value creation of cork products: an LCA-based method for design intervention, Journal of Cleaner Production, 57, 101-114.
- 16. Naresh K., Krishnapillai S., Velmurugan R., 2017, Effect of fiber orientation on carbon/epoxy and glass/epoxy composites subjected to shear and bending, Solid State Phenomena, 267, 103-108.
- 17. NASA, 1969, Apollo 11 lunar landing mission, 69-83K, 254 p.
- 18. Petit S., Bouvet C., Bergerot A., Barrau J., 2007, Impact and compression after impact experimental study of a composite laminate with a cork thermal shield, Composites Science and Technology, 67, 15-16, 3286-3299.
- 19. Prabhakaran S., Krishnaraj V., Shankar K., Senthilkumar M., Zitoune R., 2019, Experimental investigation on impact, sound, and vibration response of natural-based composite sandwich made of flax and agglomerated cork, Journal of Composite Material, 54, 5, 669-680.
- 20. Reis P., Silva M., Santos P., Parente J., Bezazi A., 2020, Viscoelastic behaviour of composites with epoxy matrix filled by cork powder, Composite Structures, 234, 111669.
- 21. Sarasini F., Tirillò J., Lampani L., Barbero E., Sanchez-Saez S., Valente T., Gaudenzi P., Scarponi C., 2020, Impact behavior of sandwich structures made of flax/epoxy face sheets and agglomerated cork, Journal of Natural Fibers, 17, 2, 168-188.
- 22. Sekar K., Ramesh M., Naveen R., Prasath M., Vigneshmoorthy D., 2020, Aerodynamic design and structural optimization of a wing for an Unmanned Aerial Vehicle (UAV), IOP Conference Series Materials Science and Engineering, 764, 1, 012-058.
- 23. Silva F., de Moura M., Magalhães A., 2017, Low velocity impact behaviour of a hybrid carbon-epoxy/cork laminate, Strain, 53, 1-9.
- 24. Silva S., Sabino M., Fernandes E., Correlo V., Boesel L., Reis R., 2005, Cork: properties, capabilities and applications, International Materials Reviews, 50, 6, 345-365.
- 25. Yoshihara H., Maruta M., 2019, Mode I J-integral of extruded polystyrene measured by the four-point single-edge notched bending test, Engineering Fracture Mechanics, 222, 106716.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-54ac2d1e-2830-494a-a36a-a1fed20d190e