Titanium as a new material, developed in the field of the pharmaceutical industry, medical equipment, human implants, etc., but the use of the past two decades. However, it was a great success and has made significant social and economic benefits, shortening the gap between China and the world's advanced countries.
Another notable feature of titanium is biocompatible, they have been selected as the best human implant material. More than a decade, the world and many of our research department, medical, hospital, also made a lot of basic work and clinical studies confirm that titanium wire is the best material from human implant depth, breadth, all these years with titanium material for the femoral head, artificial wrist, knee, dental Implants, cranioplasty, pacemakers have documented thousands of cases, these years of research, track, compare, titanium is reported so far the best human implant material.
Medical equipment, surgical instruments is one area of rapid development in recent years, due to the titanium used as a surgical instrument has special advantages, which won the surgery, ophthalmology, cardiothoracic surgeon welcome, but also one of the development of today's surgical instruments.
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Refractory elements are important alloying additions in both nickel-base and ironnickel-base superalloys. They are responsible for the increased high temperature mechanical properties present in current superalloy systems.
These precipitates are formed by the precipitation reaction of Ni with Al and Ti or, in the case of the iron-nickel-base superalloy, Nb and Ti. The refractory elements, Nb and Ta, perform strengthening functions in both the y and the precipitating y’ and y” phases.
These elements can behave somewhat differently as carbide formers. They are also known to affect corrosion resistance and alloy stability. Both elements are bee metals, and are highly misfitting in the fee Ni lattice; consequently giving rise to their well deserved reputation as potent solid-solution strengthening elements in the y as well as in the precipitating phases. Tantalum and niobium sheet are known to partition into the strengthening phases, and are also MC- type carbide formers.
The detailed roles of refractory elements in superalloys are not well understood. In particular, the science-based technology for substituting one refractory element for another does not exist. For example, it is not known whether Ta and Nb are better strengtheners than other refractory elements W and molybdenum tubing.
Furthermore, to varying degrees these elements increase incipient melting and solidus temperatures. This results in not only a higher and broader temperature range for solutionization and homogenization, but also in segregation problems during the primary vacuum refining and melting process (VIM) and during such secondary structures refining melt processes as VAR and ESR. However, Ta is known to decrease the tendency for freckling during the directional solidification of turbine blades.
In addition, it is not known whether the large degree of misfit between the y and precipitating phases, due to refractory element additions, affects such properties as strain strengthening and y and r coarsening kinetics, which is an issue with respect to long term applications.
In order to design and develop more enhanced superalloys, as well as to conserve on the more expensive and less abundant alloying elements, a better understanding on the role of these refractory elements on the mechanical and microstructural properties in superalloys is necessary.