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Advancements in Powder Metallurgy: Processing, Applications, and Properties addresses a critical issue in academic scholarship by providing a comprehensive resource that has been lacking in the field. Existing books often fall short by merely covering the basics of powder preparation, sintering methods, and general applications, leaving scholars with a limited understanding of the subject. This knowledge gap has hindered innovative research and slowed the progress of metallurgy and mechanical engineering. However, with this groundbreaking book, the tide is turning. The book brings together twenty-one chapters authored by renowned pioneers in the field, delving deep into the realm of mechanical alloying. It covers the evolution of this technique, various alloy preparation methods, their advantages and limitations, and the synthesis of nanostructured materials. Unlike other resources, this volume goes beyond the basics and comprehensively covers the fabrication of a wide range of alloys, including biomaterials, hybrid nanomaterials, smart materials, super alloys, and ceramic materials, all achieved through the transformative process of mechanical alloying. By consolidating essential information in one resource, Advancements in Powder Metallurgy: Processing, Applications, and Properties fills a significant gap in the existing literature. It equips academic scholars and engineering students with the necessary knowledge to unlock the full potential of mechanical alloying and make meaningful contributions to the field. With its emphasis on simplicity and accessibility, this book promises to inspire a new wave of research, reignite interest in metallurgy and mechanical engineering, and empower scholars to explore novel applications and contribute to the advancements in this field.
Powder metallurgy (PM) is a popular metal forming technology used to produce dense and precision components. Different powder and component forming routes can be used to create an end product with specific properties for a particular application or industry. Advances in powder metallurgy explores a range of materials and techniques used for powder metallurgy and the use of this technology across a variety of application areas. Part one discusses the forming and shaping of metal powders and includes chapters on atomisation techniques, electrolysis and plasma synthesis of metallic nanopowders. Part two goes on to highlight specific materials and their properties including advanced powdered steel alloys, porous metals and titanium alloys. Part three reviews the manufacture and densification of PM components and explores joining techniques, process optimisation in powder component manufacturing and non-destructive evaluation of PM parts. Finally, part four focusses on the applications of PM in the automotive industry and the use of PM in the production of cutting tools and biomaterials. Advances in powder metallurgy is a standard reference for structural engineers and component manufacturers in the metal forming industry, professionals working in industries that use PM components and academics with a research interest in the field. Discusses the forming and shaping of metal powders and includes chapters on atomisation techniques Highlights specific materials and their properties including advanced powdered steel alloys, porous metals and titanium alloys Reviews the manufacture and densification of PM components and explores joining techniques
This book addresses methods used in the synthesis of light alloys and composites for industrial applications. It begins with a broad introduction to virtually all aspects of the technology of light alloys and composite materials for aircraft and aerospace applications. The basic theory of fiber and particle reinforcements; light metallic material characteristics and composite systems; components forms, and manufacturing techniques and processes are discussed. The book then progresses to describe the production of alloys and composites by unconventional techniques, such as powder metallurgy, sandwich technique, severe plastic deformation, additive manufacturing, and thermal spray, making it appropriate for researchers in both academia and industry. It will be of special interest to aerospace engineers. Provides a broad introduction to the technology used in manufacturing light alloys and composite materials; Describes the current technologies employed in synthesizing light alloys made from advanced materials; Focuses on unconventional techniques used to produce light alloys and composites in aerospace applications.
Engineered cementitious composites (ECC) is a new type of fiber-reinforced bendable cementitious composite that is used in various civil engineering applications instead of conventional and fiber-reinforced concrete due to its high mechanical and durable properties. In the macro and micro mechanic systems of ECC, the incorporation of different materials plays a vital role in enhancing the properties of ECC. Conventional concrete and fiber-reinforced concrete have a brittle nature and crack easily under environmental and mechanical loads, affecting the durability of structures. The usage of alternative materials in the ECC modifies the brittle nature and offers environmentally sustainable construction with low embodied energy and a negative carbon footprint. Production, Properties, and Applications of Engineered Cementitious Composites highlights the new and innovative ways of production, properties, and various applications of engineered cementitious composites. The main focus of the book is on the latest advancements, technical knowledge, tools, and solutions for engineered cementitious composites manufacturing, design, and technologies for construction from various perspectives. Covering key topics such as alternative materials, mineral admixtures, and testing of engineered cementitious composites, this premier reference source is ideal for engineers, industry professionals, researchers, academicians, scholars, practitioners, instructors, and students.
The demand for sustainable energy solutions in rapidly evolving academic and industrial environments is at an all-time high. Challenges faced by those championing sustainability and energy solutions include the integration of green hydrogen, a clean and renewable energy carrier, into hybrid energy systems. Ensuring its traceability, certification, and efficient utilization creates an issue that academics, industry experts, and policymakers are struggling to solve. With the increasing importance of green hydrogen in reducing carbon emissions and addressing climate change, the need for a comprehensive guide to navigate this intricate territory is more pressing than ever. The Handbook of Research on Digitalization and Green Hydrogen Production is a groundbreaking book that provides a holistic and innovative approach to the challenges surrounding green hydrogen integration. It serves as a roadmap for academic scholars and industry professionals, providing deep insights into the various facets of green hydrogen, from production and storage to transportation and utilization. This book tackles the safety concerns associated with transporting green hydrogen and explores innovative technologies like Power-to-Gas-to-Power (P2G2P) and the conversion of hydrogen into ammonia. It also highlights the crucial role of standards and security regulations in ensuring the reliability of green hydrogen processes.
The book presents the fundamentals and the role of powder metallurgy in contemporary technologies and the state of the art of classical powder metallurgy technologies and a general description of new variants and special and hybrid technologies used in powder metallurgy. The next part includes over a dozen case studies provided in the following chapters, comprehensively describing authors' accomplishments of numerous teams from different countries across the world in advanced research areas relating to powder metallurgy and to special and hybrid technologies. The detailed information, largely deriving from own and original research and R
Academic scholars are increasingly confronted with the complex challenges of understanding and optimizing heat transfer processes, particularly in the areas of cavities and Phase Change Materials (PCM). These issues are central to a range of crucial applications, including building systems, electronic equipment, and the harnessing of solar energy. The need for innovative solutions to enhance heat transfer efficiency is more pressing than ever, and a comprehensive resource to guide scholars through these complexities is essential. FlexPDE and Finite Element Method Applications in Thermal Energy Storage and Cavities is research book specifically designed to provide scholars with the knowledge and expertise necessary to navigate the complexities of heat transfer issues. With a strong emphasis on practical application, the book leverages the capabilities of the Finite Element Method (FEM) through the FLEXPDE software, making it a valuable resource for those seeking innovative solutions to problems in heat transfer.
In the automotive industry, the need to reduce vehicle weight has given rise to extensive research efforts to develop aluminum and magnesium alloys for structural car body parts. In aerospace, the move toward composite airframe structures urged an increased use of formable titanium alloys. In steel research, there are ongoing efforts to design novel damage-controlled forming processes for a new generation of efficient and reliable lightweight steel components. All these materials, and more, constitute today’s research mission for lightweight structures. They provide a fertile materials science research field aiming to achieve a better understanding of the interplay between industrial processing, microstructure development, and the resulting material properties. The Handbook of Research on Advancements in the Processing, Characterization, and Application of Lightweight Materials provides the recent advancements in the lightweight mat materials processing, manufacturing, and characterization. This book identifies the need for modern tools and techniques for designing lightweight materials and addresses multidisciplinary approaches for applying their use. Covering topics such as numerical optimization, fatigue characterization, and process evaluation, this text is an essential resource for materials engineers, manufacturers, practitioners, engineers, academicians, chief research officers, researchers, students, and vice presidents of research in government, industry, and academia.
In the evolving world of industrial materials, conventional choices have proved to be insufficient to meet the demands of contemporary applications. With the introduction of Nanoscience and Nanotechnology, groundbreaking synthesis approaches are crafting nanocomposites with unprecedented versatility. Smart and Sustainable Applications of Nanocomposites delves into this research, exploring the bioinspired synthesis of nanocomposites and their multi-dimensional applications across diverse industries. This book addresses the escalating challenges faced by the nano-industry, such as the widening application window requiring additional properties like high modulus, flame retardation, UV resistance, and more. The book champions the development of environmentally friendly nanocomposites, ushering in the next generation of nanomaterials by reinforcing fibers, whiskers, or nano clays. Unique substitutes like ceramic, agricultural waste, and polymer–layered silicate nanocomposites are thoroughly examined for their exceptional physical, chemical, and physicochemical properties. From triobiological applications to the synthesis of bio-nanocoating, the book spans an array of subjects, each chapter revealing the potential applications of nanotechnology and nanocoatings in diverse fields. It highlights the ethical and environmental implications of this burgeoning technology, making it a crucial resource for students, researchers, academicians, and industry professionals.
In the midst of our contemporary and swiftly evolving technological landscape, the pressing issue lies in the need for multifunctional materials that can transcend traditional boundaries and fuel innovation across diverse industries. This demand arises from the relentless pursuit of greater performance, efficiency, and adaptability in sectors ranging from electronics to aerospace, energy, and biomedical engineering. Academic scholars grapple with the challenge of comprehending and harnessing the untapped potential of nanomaterials with hybrid reinforcements, which represent a frontier in technological advancement. Technological Applications of Nano-Hybrid Composites comprehensively addresses this increasingly critical issue. Within its pages, this meticulously curated book embarks on a journey to explore the multifaceted aspects of nanocomposites, their hybrid reinforcements, and their significance in revolutionizing various technological domains. From the fundamental principles underpinning their design to the latest fabrication techniques and comprehensive characterization methods, this book offers a comprehensive roadmap to understanding and harnessing the unparalleled potential of these materials.