CFRP: Breakthroigh material in Vietnam’s construction industry
Abstract
As Vietnam’s construction industry accelerates modernization, carbon fiber-reinforced polymer (CFRP) emerges as a pivotal material for sustainable, high-performance infrastructure. With its lightweight, corrosion-resistant, and highly durable nature, CFRP enhances structural longevity, minimizes maintenance, and reduces environmental impact, aligning with global sustainability goals. Widely applied in bridges, high-rise buildings, and coastal structures, CFRP addresses Vietnam’s unique environmental challenges, providing resilience against humidity, chemical exposure, and seismic activity. However, high costs and limited expertise in CFRP application remain obstacles. Strategic investment in cost-reducing technologies and workforce training is crucial for widespread adoption. As CFRP’s benefits become increasingly recognized, Vietnam’s construction sector has the opportunity to lead in sustainable infrastructure, creating lasting, eco-friendly solutions that reflect the country’s commitment to both innovation and environmental responsibility.
References
[1]Bounjoum Y, Hamlaoui O, Hajji MK, et al. Exploring Damage Patterns in CFRP Reinforcements: Insights from Simulation and Experimentation. Polymers. 2024; 16(14).
[2]Okuma SO, Obaseki M, Ofuyekpone OD, et al. A Review Assessment of Fiber-Reinforced Polymers for Maritime Applications. Journal of Advanced Industrial Technology and Application. 2023; 4(1).
[3]Shubhangi K, Jaiswal D. Carbon fiber as construction material. International Journal of Engineering Applied Sciences and Technology. 2022; 7(1): 294–297.
[4]Thomson D, Sommer DE, Quino G, et al. Influence of fatigue damage on the impact performance of toughened-interleave carbon fibre epoxy composite laminates. Composite Structures. 2024; 345: 118345.
[5]Wu Y. Application of carbon fiber composite materials in aircraft. Applied and Computational Engineering. 2024; 61(1): 245–248.
[6]Agarwal N, Rangamani A, Bhavsar K, et al. An overview of carbon-carbon composite materials and their applications. Frontiers in Materials. 2024; 11.
[7]Spangenberg JH. Sustainable Development and Social, Ecological, and Economic Transformation in Vietnam: Insights for Policy. VNU Journal of Science: Policy and Management Studies. 2019; 35(2): 9–25.
[8]Gao Y, Li Z, Wei X, et al. Advanced lightweight composite shells: Manufacturing, mechanical characterizations and applications. Thin-Walled Structures. 2024; 204: 112286.
[9]Khorasani M, Muciaccia G, Mostofinejad D. Experimental study of fatigue behaviour of CFRP-to-concrete bonded joints employing the EBROG strengthening technique. Construction and Building Materials. 2024; 435: 136824.
[10]Ismael DM, Atyia TH. Comparative evaluation of speed control techniques for switched reluctance motors in industrial applications. Engineering Research Express. 2024; 6(3): 032304.
[11]Zhang J, Lin G, Vaidya U, et al. Past, present and future prospective of global carbon fibre composite developments and applications. Composites Part B: Engineering. 2023; 250: 110463.
[12]Available online: https://www.marketresearchfuture.com/reports/europe-carbon-fiber-composites-market-22127 (accessed on 2 June 2024).
[13]Available online: https://www.vietnam-briefing.com/news/construction-materials-vietnam-2024-sector-outlook.html/ (accessed on 2 June 2024).
[14]Kiser JD, Andrulonis R, Ashforth C, et al. Composite Materials Handbook-17. Ceramic Matrix Composites. 2022; 5: 1–25.
Copyright (c) 2024 Duong Thi Ha, Vu Hoa Ky, Trinh Van Cuong
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