This chapter will study the material base-surface multilayer system for various types of depositions (increasing the wear resistance of Fe-C alloy parts) whose compatibility with the substrate provides high-quality parts. Thus, this system of layers can be applied on both the new and worn parts, being able to recondition and reintroduce in an intensive exploitation regime any parts with complex configuration operating in dynamic conditions. Deposited layers will be obtained using electro-spark deposition (ESD) process, which is a technology that uses electrical energy stored in a capacitor to initialize an electrical spark between the cathode and the anode. The high temperature generated by the electrical spark leads to partial melting of substrate and mixing of it with the material of the electrode. Between the two electric sparks, the amount of the molten metal solidifies to form the surface layer. The ESD is a very well used process for materials manufacturing in many industrial sectors.
Part of the book: Advanced Surface Engineering Research
Bioactive glasses are very attractive materials, used for tissue engineering materials, usually to fill and restore bone defects. This category of biomaterials, show considerable potential for orthopaedic surgery because they can promote bone tissue regeneration. Many trace elements have been incorporated in the glass network, an example is metallic glasses to obtain the desired properties. Because of tolerable mechanical properties, and because they are able to bond to living bone and stimulate its regeneration, this bioactive glasses have a particular interest and are in a continuous research and improvement. The chapter presents the history of bioactive glasses, classification, include a summary of common fabrication methods, applications, surface coatings, applications and future trends in relation to human bone. This review highlight new trends and areas of future research for bioactive glasses.
Part of the book: Current Concepts in Dental Implantology
The solar furnace works by using the electric energy produced by a photovoltaic system, which converts solar energy, solar radiation, into electric energy. The performances of the solar furnace used in various applications from industry are influenced by various factors. One of these factors imposes the acquisitions of certain large densities of the radiant power, and it requires a geometric form of the concentrator. The research is based on the behavior of some metallic alloys at elevated temperatures, for purifying some materials and for the achievement of some chemical synthesis. An important technological condition is a temperature which is achieved by concentrating solar radiation. This temperature is necessary to produce metallic material in the crucible, without other complementary energy for the thermal process. Steel or aluminum production requires very high quantities of thermal energy. Usually, this energy is given by electric power, natural gases, or conventional fuels. The solar furnace uses the energy given by the sun. For the manufacturing of the electrothermal furnaces, a series of specific materials are used, which are necessary for the obtaining of the furnace chamber, for the heating elements, as well as for the measurement systems of the temperature.
Part of the book: Latest Research on Energy Recovery
Titanium, a considerable metal renowned for its exceptional properties, has found its way into numerous industrial, medical, and aerospace applications. This chapter provides an overview of titanium’s unique characteristics, which include high strength-to-weight ratio, excellent corrosion resistance, and biocompatibility, making it an ideal choice for diverse engineering and medical purposes. In the aerospace industry, titanium’s low density and remarkable strength make it an essential material for aircraft components, from engine components to structural parts. Its resistance to corrosion in aggressive environments also renders it invaluable for marine applications. Medical fields have accepted titanium for orthopedic implants, dental fixtures, and surgical instruments due to its biocompatibility and ability to integrate seamlessly with living tissues. In addition to its medical and aerospace applications, titanium is used in the automotive industry for lightweight components that enhance fuel efficiency and reduce emissions.
Part of the book: Titanium-Based Alloys - Characteristics and Applications [Working title]