Materias
Referencia: Código 11300
Noviembre de 2024 - Hota V.S. GangaRao, Woraphot Prachasaree - Refª 11300
Hota V.S. GangaRao, Woraphot Prachasaree
Noviembre de 2024 Páginas: 534 Edición en Rústica
Código 11300 ISBN/EAN: 9781032052526
The use of fiber-reinforced polymer (FRP) composites in infrastructure systems has grown considerably in recent years because of the durability of composite materials. New constituent materials, manufacturing techniques, design approaches, and construction methods are being developed and introduced in practice by the FRP composites community to cost-effectively build FRP structural systems. FRP Composite Structures: Theory, Fundamentals, and Design brings clarity to the analysis and design of these FRP composite structural systems to advance the field implementation of structural systems with enhanced durability and reduced maintenance costs. It develops simplified mathematical models representing the behavior of beams and plates under static loads, after introducing generalized Hooke’s Law for materials with anisotropic, orthotropic, transversely isotropic, and isotropic properties. Subsequently, the simplified models coupled with design methods including FRP composite material degradation factors are introduced by solving a wide range of practical design problems. This book:
This textbook is aimed at advanced undergraduate and graduate students and industry professionals focused on the analysis and design of FRP composite structural members. It features PowerPoint lecture slides and a solutions manual for adopting professors.
Chapter 1 Introduction
Chapter 2 Engineering Properties of Composite Materials
Chapter 3 Mechanics of FRP Composite Lamina
Chapter 4 Mechanics of FRP Composite Laminates
Chapter 5 Analysis of FRP Composite Beams
Chapter 6 Analysis of FRP Composite Plates
Chapter 7 Design Philosophy and Basis of FRP Composite Structural Members
Chapter 8 Design of Pultruded FRP Axial Tension Members
Chapter 9 Flexural Member Design
Chapter 10 Design of Pultruded FRP Axial Compression Members
Chapter 11 Design of Connections for FRP Members
Chapter 12 Design of Combined Loads for FRP Members
After joining West Virginia University in 1969 as an Assistant Professor, Dr. Hota attained the rank of Maurice & JoAnn Wadsworth Distinguished Professor in the Department of Civil and Environmental Engineering, Statler College of Engineering and Mineral Resources, and became a Fellow of ASCE and SEI. Dr. Hota has been directing the Constructed Facilities Center since 1988 (a Center of Excellence designated by the U.S. Congress in 2000), and also the Center for Integration of Composites into Infrastructure, both co-sponsored by the National Science Foundation. Through many interdisciplinary activities, he has worked to advance the state-of-the-art of fiber reinforced polymer (FRP) composite materials and their applications to infrastructure systems. Dr. Hota has demonstrated success by field-implementing his research findings and technical innovations for construction and rehabilitation of a wide spectrum of engineering systems in West Virginia, Ohio, Pennsylvania, Alaska, and other states. In addition to the application of FRPs for highway and railroad structures, he has utilized FRP composites for corrosion resistant storage buildings and economical modular housing. Recently, Dr. Hota has been involved with innovations of naval vessels, prefabricated pavements, utility poles, high pressure gas pipes, sheet piling, natural fiber reinforced composites and others. Dr. Hota has published over 400 technical papers on a wide range of subjects in refereed journals and proceedings, in addition to textbooks and book chapters. He has received fourteen patents and many national awards. He advised over 300 M.S. and Ph.D. students towards successful completion of their degree requirements. His pioneering accomplishments have been covered by CNN, ABC Evening News, KDKA-Pittsburgh, WV-PBS, and many others.
Woraphot Prachasaree received a B.Eng. degree in civil engineering from Prince of Songkla University, Thailand in 1997 and an M.Eng. degree in the field of structural engineering from Kasetsart University, Thailand in 2000. In 2001, he joined WVU’s Constructed Facilities Center (CFC) as a research assistant. He holds an M.S. degree and a Ph.D. degree in civil engineering, both from West Virginia University. In 2007, Woraphot became Lecturer at department of civil and environmental engineering, Prince of Songkla University, where he currently holds the position of assistant to the President. His present research interests cover several areas, including FRP composites, concrete structures, structural durability, and FE modeling. He has authored or coauthored over 40 publications in engineering journals. He is a registered professional engineer in Thailand. He has engaged in consulting work in the field of structural inspection, design and construction for many engineering and infrastructure projects.
El uso de compuestos de polímero reforzado con fibra (FRP) en sistemas de infraestructura ha crecido considerablemente en los últimos años debido a la durabilidad de los materiales compuestos. La comunidad de compuestos FRP está desarrollando e introduciendo en la práctica nuevos materiales constituyentes, técnicas de fabricación, enfoques de diseño y métodos de construcción para construir de manera rentable sistemas estructurales FRP. FRP Composite Structures: Theory, Fundamentals, and Design aporta claridad al análisis y diseño de estos sistemas estructurales compuestos FRP para avanzar en la implementación en campo de sistemas estructurales con mayor durabilidad y menores costos de mantenimiento. Desarrolla modelos matemáticos simplificados que representan el comportamiento de vigas y placas bajo cargas estáticas, después de introducir la Ley de Hooke generalizada para materiales con propiedades anisotrópicas, ortotrópicas, transversalmente isotrópicas e isotrópicas. Posteriormente, se introducen los modelos simplificados junto con métodos de diseño que incluyen factores de degradación de materiales compuestos FRP mediante la solución de una amplia gama de problemas prácticos de diseño. Este libro:
Este libro de texto está dirigido a estudiantes universitarios y de posgrado avanzados y a profesionales de la industria enfocados en el análisis y diseño de elementos estructurales compuestos de FRP. Incluye diapositivas de PowerPoint y un manual de soluciones para profesores que lo adopten.
Capítulo 1 Introducción
Capítulo 2 Propiedades de ingeniería de materiales compuestos
Capítulo 3 Mecánica de láminas compuestas de FRP
Capítulo 4 Mecánica de los laminados compuestos de FRP
Capítulo 5 Análisis de vigas compuestas de FRP
Capítulo 6 Análisis de placas compuestas de FRP
Capítulo 7 Filosofía de diseño y fundamentos de los elementos estructurales compuestos de FRP
Capítulo 8 Diseño de elementos de tensión axial de FRP pultruidos
Capítulo 9 Diseño de elementos flexionados
Capítulo 10 Diseño de elementos de compresión axial de FRP pultruidos
Capítulo 11 Diseño de conexiones para elementos de FRP
Capítulo 12 Diseño de cargas combinadas para elementos de FRP
Fecha de disponibilidad: