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Titanium alloys, due to unique physical and chemical properties (mainly high relative strength combined with very good corrosion resistance), are considered as an important structural metallic material used in hi-tech industries (e.g. aerospace, space technology). This book provides information on new manufacturing and processing methods of single- and two-phase titanium alloys. The eight chapters of this book are distributed over four sections. The first section (Introduction) indicates the main factors determining application areas of titanium and its alloys. The second section (Manufacturing, two chapters) concerns modern production methods for titanium and its alloys. The third section (Thermomechanical and surface treatment, three chapters) covers problems of thermomechanical processing and surface treatment used for single- and two-phase titanium alloys. The fourth section (Machining, two chapters) describes the recent results of high speed machining of Ti-6Al-4V alloy and the possibility of application of sustainable machining for titanium alloys.
At just half the weight of steel and nickel-based superalloys, titanium and its alloys stand out primarily due to their excellent corrosion resistance, high strength, and low density. Such distinctive properties make titanium attractive for a variety of applications, including aerospace, sports and leisure, and industrial uses.The book aims to cover important aspects of titanium metallurgy, from the basic characteristics of titanium to its advanced applications.The introductory chapter introduces the metallurgical background, physical and mechanical properties of titanium, with insights into specialty titanium alloys and titanium matrix composites. The book also discusses the correlation between microstructure and properties of titanium and its alloys along with various heat-treatment opportunities that exist for tailoring the properties to achieve excellent performance in a variety of products. Additionally, the variety of applications of titanium and its alloys in aerospace and non-aerospace markets are documented in detail.Serving an updated account of recent developments with respect to titanium and its alloys, this book is an excellent, timely, and comprehensive reference for materials scientist and engineers who wish to gain knowledge about these engineering materials.
Titanium Alloys for Biomedical Development and Applications: Design, Microstructure, Properties and Application systematically introduces basic theories and progress in the research of biomedical ß-Ti alloys achieved by researchers from different fields. It focuses on a high-strength and low elastic modulus biomedical ß-Ti alloy (TLM), etc. designed by the authors. The alloy design methods, microstructural characteristics, mechanical properties, surface treatment methods and biocompatibility of the TLM alloy are discussed in detail, along with a concise description of the medical devices made from this alloy and the application examples. This book will appeal to researchers as well as students from different disciplines, including materials science, biology, medicine and engineering fields. - Fills the knowledge gap in the current research and application of newly developed biomedical ß-Ti alloys - Discusses the selection principles used for proper biomedical Ti alloys for medical and dental devices - Includes details on the technological data basis for the application of biomedical ß-Ti alloys with a focus on the TLM ß-Ti alloy
The book contains six chapters and covers topics dealing with biomedical applications of titanium alloys, surface treatment, relationships between microstructure and mechanical and technological properties, and the effect of radiation on the structure of the titanium alloys.
This handbook is an excellent reference for materials scientists and engineers needing to gain more knowledge about these engineering materials. Following introductory chapters on the fundamental materials properties of titanium, readers will find comprehensive descriptions of the development, processing and properties of modern titanium alloys. There then follows detailed discussion of the applications of titanium and its alloys in aerospace, medicine, energy and automotive technology.
This report supplies information on joining processes applicable to titanium and its alloys in sheet metal applications, primarily related directly to airframe construction. Although the material presented here does not cover all titanium joining processes, and omits such processes as plasma-arc, submerged-arc, electroslag, flash, and high-frequency resistance welding, the data presented cover materials up to 2-inches thick in some cases and the report should be useful to anyone seeking titanium joining information. The joining processes covered fall into five categories: welding, brazing, metallurgical bonding (diffusion and deformation bonding), adhesive bonding, and mechanical fastening. The fusion welding processes that are discussed in detail include gas tungsten arc, gas metal arc, arc spot, and electron beam. The resistance processes give extended coverage are spot, roll spot, and seam welding. (Author).
This book provides an in-depth exploration of ferrous and non-ferrous alloys including various methods of preparation and production, their mechanical properties, and applications. The advantages of the mechanical alloying processing approach over other traditional powder metallurgical techniques is explained as are which alloys are best suited for this technique. Preparation steps, microstructures, properties, and applications for ferrous and non-ferrous alloys are compared, with insight on which alloys are best suited for preparation by alloying. The advantages and disadvantages of wet and dry milling are outlined. Processing, properties, and applications of high entropy alloys, ODS stainless steel, shape memory alloys, cermets, iron, copper, zinc, tungsten, aluminum, titanium, magnesium, and ceramic-based alloys are also covered, as are different powder preparation techniques and sintering methods. - Outlines the different types of mechanical alloying used to prepare powders, their mechanisms, factors affecting the process, and more - Covers the manufacturing, characteristics, and applications of high entropy alloys, ODS stainless steel, shape memory alloys, magnesium, ceramic-based alloys, and more - Compares preparation of ferrous and non-ferrous alloys, their microstructures, and properties - Discusses the advantages and disadvantages of wet and dry milling