Composite Materials – serie

Developed from the author’s course on advanced mechanics of composite materials, Finite Element Analysis of Composite Materials with Abaqus® shows how powerful finite element tools tackle practical problems in the structural analysis of composites. This Second Edition includes two new chapters on "Fatigue" and "Abaqus Programmable Features" as well as a major update of chapter 10 "Delaminations" and significant updates throughout the remaining chapters. Furthermore, it updates all examples, sample code, and problems to Abaqus 2020. Unlike other texts, this one takes theory to a hands-on level by actually solving problems. It explains the concepts involved in the detailed analysis of composites, the mechanics needed to translate those concepts into a mathematical representation of the physical reality, and the solution of the resulting boundary value problems using Abaqus. The reader can follow a process to recreate every example using Abaqus graphical user interface (CAE) by following step-by-step directions in the form of pseudo-code or watching the solutions on YouTube. The first seven chapters provide material ideal for a one-semester course. Along with offering an introduction to finite element analysis for readers without prior knowledge of the finite element method, these chapters cover the elasticity and strength of laminates, buckling analysis, free edge stresses, computational micromechanics, and viscoelastic models for composites. Emphasizing hereditary phenomena, the book goes on to discuss continuum and discrete damage mechanics as well as delaminations and fatigue. The text also shows readers how to extend the capabilities of Abaqus via "user subroutines" and Python scripting.Aimed at advanced students and professional engineers, this textbook features 62 fully developed examples interspersed with the theory, 82 end-of-chapter exercises, and 50+ separate pieces of Abaqus pseudo-code that illustrate the solution of example problems. The author’s website offers the relevant Abaqus and MATLAB model files available for download, enabling readers to easily reproduce the examples and complete the exercises: https://barbero.cadec-online.com/feacm-abaqus/index.html. Video recording of solutions to examples are available on YouTube with multilingual captions.

Safely Design, Test, and Construct Products Made of Natural Fiber CompositesNatural fibers and their composites carry distinct advantages over industrial fibers. Some advantages—including renewability and availability of raw materials, and lower energy consumption—could help safeguard environmental resources and eventually replace synthetic composites and conventional materials. Natural Fiber Composites explores the growing use of natural fibers in composites and covers material properties, treatment and processing, modeling, applications, design, and other vital information on this subject.Improve the Strength of Manufactured Composites, and Determine the Best Processing TechniqueIncorporating independent pieces written by a team of international contributors, this book enables readers to analyze and design structural components using state-of-the-art information and methods. It provides an overview of natural fiber composites, details the superior specific mechanical properties of these materials, and presents development techniques and design case studies that can improve performance and enhance the process.Natural Fiber Composites evaluates the value of natural fibers in composite materials, and offers introductory knowledge on natural fiber composites backed by internationally recognized experts in the field.

Due to the increased use of composite materials in aerospace, energy, automobile, and civil infrastructure applications, concern over composite material failures has grown, creating a need for smart composite structures that are able to self-diagnose and self-heal.Structural Health Monitoring Technologies and Next-Generation Smart Composite Structures provides valuable insight into cutting-edge advances in SHM, smart materials, and smart structures. Comprised of chapters authored by leading researchers in their respective fields, this edited book showcases exciting developments in general embedded sensor technologies, general sensor technologies, sensor response interrogation and data communication, damage matrix formulation, damage mechanics and analysis, smart materials and structures, and SHM in aerospace applications. Each chapter makes a significant contribution to the prevention of structural failures by describing methods that increase safety and reduce maintenance costs in a variety of SHM applications.

This book provides an understanding of the mechanical response and failure of continuous fibre-reinforced polymer matrix composites. It brings together the state of knowledge on failure of composites, drawing on the author’s extensive experience and insights gained from researching the behaviour of these fascinating materials. It explains the principles governing them to help readers understand failures when they do occur and, more importantly, to avoid them by taking account of the key characteristics in design, underpinning greater exploitation of composites—truly the materials of the future.Systematically treats all the potential failure modes in unidirectional and laminated composites.Focuses on experimental observations and examples of failure and describes key failure theories in an accessible way.Provides fundamental understanding to underpin the successful application of composites.Gives insight into the differences in behaviour between composites and metals.Presents test methods to measure strength and the factors affecting it.Brings together the state of knowledge and references to the latest research findings in one place.Failure Mechanisms in Composites will be of interest to engineers and designers in industry already working with composites as well as those more familiar with metallic materials who would like to understand the differences in behaviour. It will also be relevant to a wide range of students and researchers including undergraduates undertaking projects or with a particular interest in the topic, master’s students in materials and structures, and doctoral students and specialists undertaking research in composites.

Smart Composites: Mechanics and Design addresses the current progress in the mechanics and design of smart composites and multifunctional structures. Divided into three parts, it covers characterization of properties, analyses, and design of various advanced composite material systems with an emphasis on the coupled mechanical and non-mechanical behaviors. Part one includes analyses of smart materials related to electrically conductive, magnetostrictive nanocomposites and design of active fiber composites. These discussions include several techniques and challenges in manufacturing smart composites and characterizing coupled properties, as well as the analyses of composite structures at various length and time scales undergoing coupled mechanical and non-mechanical stimuli considering elastic, viscoelastic (and/or viscoplastic), fatigue, and damage behaviors. Part two is dedicated to a higher-scale analysis of smart structures with topics such as piezoelectrically actuated bistable composites, wing morphing design using macrofiber composites, and multifunctional layered composite beams. The analytical expressions for characterization of the smart structures are presented with an attention to practical application.Finally, part three presents recent advances regarding sensing and structural health monitoring with a focus on how the sensing abilities can be integrated within the material and provide continuous sensing, recognizing that multifunctional materials can be designed to both improve and enhance the health-monitoring capabilities and also enable effective nondestructive evaluation. Smart Composites: Mechanics and Design is an essential text for those interested in materials that not only possess the classical properties of stiffness and strength, but also act as actuators under a variety of external stimuli, provide passive and active response to enable structural health monitoring, facilitate advanced nondestructive testing strategies, and enable shape-changing and morphing structures.

Fiber-reinforced polymer (FRP) decks have been increasingly used for new construction and rehabilitation projects worldwide. The benefits of using FRP bridge decks, such as durability, light weight, high strength, reduced maintenance costs, and rapid installation, outweigh their initial in-place material costs when implemented in highway bridge projects. FRP Deck and Steel Girder Bridge Systems: Analysis and Design compiles the necessary information to facilitate the development of the standards and guidelines needed to promote further adoption of composite sandwich panels in construction. It also, for the first time, proposes a complete set of design guidelines.Providing both experimental investigations and theoretical analyses, this book covers three complementary parts: FRP decks, shear connectors between the deck and steel girders, and the behavior of bridge systems. The text presents stiffness and strength evaluations for FRP deck panels and FRP deck-girder bridge systems. While the FRP deck studies focus on honeycomb FPR sandwich panels over steel girder bridge systems, they can be adapted to other sandwich configurations. Similarly, the shear connection and bridge system studies can be applied to other types of FRP decks. Chapters discuss skin effect, core configuration, facesheet laminates, out-of-plane compression and sheer, mechanical shear connectors, and FRP deck–steel girder bridge systems.Based on the findings described in the text, the authors propose design guidelines and present design examples to illustrate application of the guidelines. In the final chapter, they also provide a systematic analysis and design approach for single-span FRP deck-stringer bridges. This book presents new and improved theories and combines analytical models, numerical analyses, and experimental investigations to devise a practical analysis procedure, resulting in FRP deck design formulations.

The third edition of Introduction to Composite MaterialsDesign is a practical, design-oriented textbook aimed at students and practicing engineers learning analysis and design of composite materials and structures. Readers will find the third edition to be both highly streamlined for teaching, with new comprehensive examples and exercises emphasizing design, as well as complete with practical content relevant to current industry needs. Furthermore, the third edition is updated with the latest analysis techniques for the preliminary design of composite materials, including universal carpet plots, temperature dependent properties, and more. Significant additions provide the essential tools for mastering Design for Reliability as well as an expanded material property database.

Braiding is a very old textile manufacturing technology that traditionally has been used to produce items like ropes, shoe laces, and cables. Recently, braiding has gained attention in the medical, aerospace, transportation, and civil engineering communities, among others, due to its ability to produce structures that can fulfill the explicit demands imposed by these technical sectors.Braided Structures and Composites: Production, Properties, Mechanics, and Technical Applications provides a single source of cutting-edge information on braiding and its applications. Featuring chapters authored by leading experts in their respective fields, this first-of-its-kind book:Explains the basic principles of braiding technology for industrial textiles, composites, and productsIdentifies the key parameters that influence the braiding process and its produced structuresShows how to control these parameters to achieve the desired material characteristicsDiscusses braided structure modeling and analysis techniques and software toolsDescribes various application requirements and their design solutionsBraided Structures and Composites: Production, Properties, Mechanics, and Technical Applications supplies a critical understanding of braiding from concept to product design and application. This book is vital to the development of multifunctional products with highly specific features using braiding technology.

Fiber-reinforced polymer (FRP) decks have been increasingly used for new construction and rehabilitation projects worldwide. The benefits of using FRP bridge decks, such as durability, light weight, high strength, reduced maintenance costs, and rapid installation, outweigh their initial in-place material costs when implemented in highway bridge projects. FRP Deck and Steel Girder Bridge Systems: Analysis and Design compiles the necessary information to facilitate the development of the standards and guidelines needed to promote further adoption of composite sandwich panels in construction. It also, for the first time, proposes a complete set of design guidelines.Providing both experimental investigations and theoretical analyses, this book covers three complementary parts: FRP decks, shear connectors between the deck and steel girders, and the behavior of bridge systems. The text presents stiffness and strength evaluations for FRP deck panels and FRP deck-girder bridge systems. While the FRP deck studies focus on honeycomb FPR sandwich panels over steel girder bridge systems, they can be adapted to other sandwich configurations. Similarly, the shear connection and bridge system studies can be applied to other types of FRP decks. Chapters discuss skin effect, core configuration, facesheet laminates, out-of-plane compression and sheer, mechanical shear connectors, and FRP deck–steel girder bridge systems.Based on the findings described in the text, the authors propose design guidelines and present design examples to illustrate application of the guidelines. In the final chapter, they also provide a systematic analysis and design approach for single-span FRP deck-stringer bridges. This book presents new and improved theories and combines analytical models, numerical analyses, and experimental investigations to devise a practical analysis procedure, resulting in FRP deck design formulations.

Smart Composites: Mechanics and Design addresses the current progress in the mechanics and design of smart composites and multifunctional structures. Divided into three parts, it covers characterization of properties, analyses, and design of various advanced composite material systems with an emphasis on the coupled mechanical and non-mechanical behaviors. Part one includes analyses of smart materials related to electrically conductive, magnetostrictive nanocomposites and design of active fiber composites. These discussions include several techniques and challenges in manufacturing smart composites and characterizing coupled properties, as well as the analyses of composite structures at various length and time scales undergoing coupled mechanical and non-mechanical stimuli considering elastic, viscoelastic (and/or viscoplastic), fatigue, and damage behaviors. Part two is dedicated to a higher-scale analysis of smart structures with topics such as piezoelectrically actuated bistable composites, wing morphing design using macrofiber composites, and multifunctional layered composite beams. The analytical expressions for characterization of the smart structures are presented with an attention to practical application.Finally, part three presents recent advances regarding sensing and structural health monitoring with a focus on how the sensing abilities can be integrated within the material and provide continuous sensing, recognizing that multifunctional materials can be designed to both improve and enhance the health-monitoring capabilities and also enable effective nondestructive evaluation. Smart Composites: Mechanics and Design is an essential text for those interested in materials that not only possess the classical properties of stiffness and strength, but also act as actuators under a variety of external stimuli, provide passive and active response to enable structural health monitoring, facilitate advanced nondestructive testing strategies, and enable shape-changing and morphing structures.

Designing structures using composite materials poses unique challenges, especially due to the need for concurrent design of both material and structure. Students are faced with two options: textbooks that teach the theory of advanced mechanics of composites, but lack computational examples of advanced analysis, and books on finite element analysis that may or may not demonstrate very limited applications to composites. But there is a third option that makes the other two obsolete: Ever J. Barbero's Finite Element Analysis of Composite Materials Using ANSYS®, Second Edition.The Only Finite Element Analysis Book on the Market Using ANSYS to Analyze Composite Materials.By layering detailed theoretical and conceptual discussions with fully developed examples, this text supplies the missing link between theory and implementation. In-depth discussions cover all of the major aspects of advanced analysis, including three-dimensional effects, viscoelasticity, edge effects, elastic instability, damage, and delamination. This second edition of the bestseller has been completely revised to incorporate advances in the state of the art in such areas as modeling of damage in composites. In addition, all 50+ worked examples have been updated to reflect the newest version of ANSYS. Including some use of MATLAB®, these examples demonstrate how to use the concepts to formulate and execute finite element analyses and how to interpret the results in engineering terms. Additionally, the source code for each example is available to students for download online via a companion website featuring a special area reserved for instructors. Plus a solutions manual is available for qualifying course adoptions.Cementing applied computational and analytical experience to a firm foundation of basic concepts and theory, Finite Element Analysis of Composite Materials Using ANSYS, Second Edition offers a modern, practical, and versatile classroom tool for today's engineering classroom.

Due to the increased use of composite materials in aerospace, energy, automobile, and civil infrastructure applications, concern over composite material failures has grown, creating a need for smart composite structures that are able to self-diagnose and self-heal.Structural Health Monitoring Technologies and Next-Generation Smart Composite Structures provides valuable insight into cutting-edge advances in SHM, smart materials, and smart structures. Comprised of chapters authored by leading researchers in their respective fields, this edited book showcases exciting developments in general embedded sensor technologies, general sensor technologies, sensor response interrogation and data communication, damage matrix formulation, damage mechanics and analysis, smart materials and structures, and SHM in aerospace applications. Each chapter makes a significant contribution to the prevention of structural failures by describing methods that increase safety and reduce maintenance costs in a variety of SHM applications.

Strengthening Design of Reinforced Concrete with FRP establishes the art and science of strengthening design of reinforced concrete with fiber-reinforced polymer (FRP) beyond the abstract nature of the design guidelines from Canada (ISIS Canada 2001), Europe (FIB Task Group 9.3 2001), and the United States (ACI 440.2R-08). Evolved from thorough class notes used to teach a graduate course at Kansas State University, this comprehensive textbook:Addresses material characterization, flexural strengthening of beams and slabs, shear strengthening of beams, and confinement strengthening of columnsDiscusses the installation and inspection of FRP as externally bonded (EB) or near-surface-mounted (NSM) composite systems for concrete membersContains shear design examples and design examples for each flexural failure mode independently, with comparisons to actual experimental capacityPresents innovative design aids based on ACI 440 code provisions and hand calculations for confinement design interaction diagrams of columnsIncludes extensive end-of-chapter questions, references for further study, and a solutions manual with qualifying course adoptionDelivering a detailed introduction to FRP strengthening design, Strengthening Design of Reinforced Concrete with FRP offers a depth of coverage ideal for senior-level undergraduate, master’s-level, and doctoral-level graduate civil engineering courses.

Safely Design, Test, and Construct Products Made of Natural Fiber CompositesNatural fibers and their composites carry distinct advantages over industrial fibers. Some advantages—including renewability and availability of raw materials, and lower energy consumption—could help safeguard environmental resources and eventually replace synthetic composites and conventional materials. Natural Fiber Composites explores the growing use of natural fibers in composites and covers material properties, treatment and processing, modeling, applications, design, and other vital information on this subject.Improve the Strength of Manufactured Composites, and Determine the Best Processing TechniqueIncorporating independent pieces written by a team of international contributors, this book enables readers to analyze and design structural components using state-of-the-art information and methods. It provides an overview of natural fiber composites, details the superior specific mechanical properties of these materials, and presents development techniques and design case studies that can improve performance and enhance the process.Natural Fiber Composites evaluates the value of natural fibers in composite materials, and offers introductory knowledge on natural fiber composites backed by internationally recognized experts in the field.