Progress of Fiber-Reinforced Composites Design and Applications
Fiber-reinforced composite (FRC) materials are widely used in advanced structures and are often applied in order to replace traditional materials such as metal components, especially those used in corrosive environments. They have become essential materials for maintaining and strengthening existing...
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| Format: | Electronic Book Chapter |
| Language: | English |
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Basel
2022
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| Online Access: | DOAB: download the publication DOAB: description of the publication |
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| 041 | 0 | |a eng | |
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| 072 | 7 | |a TB |2 bicssc | |
| 100 | 1 | |a Kartsonakis, Ioannis |4 edt | |
| 700 | 1 | |a Kartsonakis, Ioannis |4 oth | |
| 245 | 1 | 0 | |a Progress of Fiber-Reinforced Composites |b Design and Applications |
| 260 | |a Basel |c 2022 | ||
| 300 | |a 1 electronic resource (228 p.) | ||
| 336 | |a text |b txt |2 rdacontent | ||
| 337 | |a computer |b c |2 rdamedia | ||
| 338 | |a online resource |b cr |2 rdacarrier | ||
| 506 | 0 | |a Open Access |2 star |f Unrestricted online access | |
| 520 | |a Fiber-reinforced composite (FRC) materials are widely used in advanced structures and are often applied in order to replace traditional materials such as metal components, especially those used in corrosive environments. They have become essential materials for maintaining and strengthening existing infrastructure due to the fact that they combine low weight and density with high strength, corrosion resistance, and high durability, providing many benefits in performance and durability. Modified fiber-based composites exhibit better mechanical properties, impact resistance, wear resistance, and fire resistance. Therefore, the FRC materials have reached a significant level of applications ranging from aerospace, aviation, and automotive systems to industrial, civil engineering, military, biomedical, marine facilities, and renewable energy. In order to update the field of design and development of composites with the use of organic or inorganic fibers, a Special Issue entitled "Progress of Fiber-Reinforced Composites: Design and Applications" has been introduced. This reprint gathers and reviews the collection of twelve article contributions, with authors from Europe, Asia and America accepted for publication in the aforementioned Special Issue of Applied Sciences. | ||
| 540 | |a Creative Commons |f https://creativecommons.org/licenses/by/4.0/ |2 cc |4 https://creativecommons.org/licenses/by/4.0/ | ||
| 546 | |a English | ||
| 650 | 7 | |a Technology: general issues |2 bicssc | |
| 653 | |a fiber-cement-treated subgrade soil | ||
| 653 | |a mechanical properties | ||
| 653 | |a triaxial test | ||
| 653 | |a brittleness index | ||
| 653 | |a failure angle | ||
| 653 | |a carbon fibers | ||
| 653 | |a lignin | ||
| 653 | |a melt spinning | ||
| 653 | |a carbonization | ||
| 653 | |a Raman | ||
| 653 | |a micro-CT | ||
| 653 | |a banana fiber | ||
| 653 | |a impact response | ||
| 653 | |a compression after impact | ||
| 653 | |a natural fiber | ||
| 653 | |a compression shear properties | ||
| 653 | |a bonded-bolted hybrid | ||
| 653 | |a C/C composites | ||
| 653 | |a high temperature | ||
| 653 | |a hybrid structures | ||
| 653 | |a metallic/composite joints | ||
| 653 | |a plasticity | ||
| 653 | |a damage propagation | ||
| 653 | |a FEM | ||
| 653 | |a crashworthiness | ||
| 653 | |a finite element analysis (FEA) | ||
| 653 | |a composites | ||
| 653 | |a progressive failure analysis (PFA) | ||
| 653 | |a cyclic hygrothermal aging | ||
| 653 | |a high strain rates | ||
| 653 | |a braided composites | ||
| 653 | |a compressive property | ||
| 653 | |a basalt fiber-reinforced polymer (BFRP) | ||
| 653 | |a thickness | ||
| 653 | |a durability | ||
| 653 | |a hygrothermal ageing | ||
| 653 | |a accelerated ageing method | ||
| 653 | |a GFRP composite structures | ||
| 653 | |a slip-critical connection | ||
| 653 | |a stainless-steel cover plates | ||
| 653 | |a surface treatment | ||
| 653 | |a prevailing torque | ||
| 653 | |a anchor | ||
| 653 | |a shear behavior | ||
| 653 | |a concrete edge breakout resistance | ||
| 653 | |a ultimate flexural strength | ||
| 653 | |a energy absorption capacity | ||
| 653 | |a steel fiber | ||
| 653 | |a multi-material design | ||
| 653 | |a thermoplastic composites | ||
| 653 | |a joining | ||
| 653 | |a resistance spot welding | ||
| 653 | |a metal inserts | ||
| 653 | |a tubular composites | ||
| 653 | |a finite element analysis | ||
| 653 | |a computational fluid dynamics | ||
| 653 | |a wireless communication | ||
| 653 | |a signal attenuation | ||
| 653 | |a n/a | ||
| 856 | 4 | 0 | |a www.oapen.org |u https://mdpi.com/books/pdfview/book/6028 |7 0 |z DOAB: download the publication |
| 856 | 4 | 0 | |a www.oapen.org |u https://directory.doabooks.org/handle/20.500.12854/92151 |7 0 |z DOAB: description of the publication |