Examples of 'austenite phase' in a sentence
Meaning of "austenite phase"
Austenite phase refers to a phase in metallurgy where a solid solution of carbon and other elements is formed in iron at high temperatures. This phase is important in steelmaking and can affect the properties of the final material, such as its strength and toughness
How to use "austenite phase" in a sentence
Basic
Advanced
austenite phase
Nitinol can be cooled to a martensite phase or warmed to an austenite phase.
The Austenite phase is the high temperature phase.
C is effective in stabilizing an austenite phase.
The Ni content is higher in the austenite phase in comparison with the ferrite phase.
Co acts as a substitute for nickel to stabilize the austenite phase.
The residual austenite phase is unstable, and the stretch flangeability is poor.
The steel may be hot rolled whilst in an austenite phase.
C acts to stabilize the austenite phase and inhibits deformation-induced martensitic transformation.
Examples of the other phases include an austenite phase and a σ phase.
The austenite phase is nitinol 's stronger, higher-temperature phase, with a simple cubic crystalline structure.
It should be noted that iron has a ferrite and austenite phase.
The volume percentage of the residual austenite phase is measured by X-ray diffraction.
Approximately the entire region of this metal microstructure is formed as an austenite phase.
Carbon ( C ) partitions to the austenite phase and has a strong effect on austenite stability.
Mn has the effect of improving the toughness by increasing the austenite phase.
See also
Manganese ( Mn ) stabilizes the austenite phase and decreases the Ms temperature in the steel alloy.
As a result, an extremely stable residual austenite phase is obtained.
The austenite phase ( A ) and the martensite phase ( M ) are present respectively at high and low temperature.
C is an element added for stabilizing the austenite phase of the steel sheet.
An appropriate austenite phase fraction at the annealing temperature is 5 % or more and 95 % or less.
The remainder is substantially a carbon-enriched austenite phase steel.
With a retained austenite phase of less than 3 %, high elongation ( El ) can not be obtained.
Upon release of the stress, the alloy returns to the austenite phase.
In the 1,5 % Cu alloy a great deal of the austenite phase exists between the ferrite grains.
In addition, Si is necessary for forming a retained austenite phase.
C, up to 0.20 % C acts to stabilize the austenite phase and inhibits deformation-induced martensitic transformation.
Accordingly, workability deteriorates, and the corrosion resistance of the austenite phase deteriorates.
The residual austenite phase has an Msr point of -60°C or less.
During plastic deformation and straining, the retained austenite phase is transformed into martensite.
In austenitic stainless steel, Ni is a very important alloy element for stabilizing an austenite phase.
The larger the Ypre is, the easier an austenite phase is formed.
Furthermore, the steel sheet structure may contain 2 to 25 % of a retained austenite phase.
The transition temperature between the ferrite and austenite phase is approximately 727°C.
The Mn has a similar effect as Ni, i.e. it stabilizes the austenite phase.
The solid solution carbon amount in the retained austenite phase is 1.00 % or less.
In Fig . 7, a black part indicates a bainite phase, a martensite phase, or a residual austenite phase.
However, Cr suppresses the generation of the austenite phase.
However, Ti and Nb suppress the generation of the austenite phase.
Also, Mn is an austenite forming element, and stabilizes an austenite phase.
Nitrogen ( N ) is an element effective in stabilizing the austenite phase.
Co, up to 1.0 % Co acts as a substitute for nickel to stabilize the austenite phase.
You'll also be interested in:
Examples of using Phase
Show more
The first phase evolved over millennia
Review of the execution of the design phase
The results of phase two have been amazing
Examples of using Austenite
Show more
It is formed by the transformation of austenite by a nondiffusional mechanism
Austenite is in equilibrium with ferrite and cementite
C carbon content of austenite at the peritectic pe temperature
