New matchable conductive ceramic material Ti3AlC2

What’s the purpose of Ti3AlC2 and how does it work? Ti3AlC2 Has oxidation resistance and self-lubrication. It also has high room temperature fracture toughness. You can use it as a high-temperature structural material, an electrode brush material, chemical anticorrosion and high temperature heating body. They are used primarily in MXene precursor and high-temperature coating.

MAX Phase Material, Aluminium titanium carbide
Aluminum titanium carbide (MAX) is the phase. MAX phase materials have many benefits that combine ceramic and metal, such as low density and high modulus. Because of its crystal structure, the MAX phase has an enhanced elastic modulus and greater strength due to the covalent bonding between the MX and A atomic surfaces. Contrary to this, the weak binding of the MX lamelayer with the A atomic surface results in a lower shear moduleus. Continuous thickening occurs in the MAX phase. A MAX phase ceramic materials with higher modulus can be obtained through the thicknesses of MX sheets layers. The material should be high-temperature-stable and have excellent mechanical properties. A material’s ability to form dense protective oxide films in high temperature oxidation (e.g. silica) will greatly impact its antioxidant potential. Due to selective oxidation, Al can create a continuous Al2O3 protective coating during the oxidation procedure of aluminium titan carbide (Ti3AlC2). Experimental results show that Aluminium titanium carbide, Ti3AlC2, has excellent anti-thermal cycling ability. The oxide film created is very dense, and it combines well with the matrix. It does not peel off. Ti3SiC2’s oxide film of titanium silicon carbide is broken into two layers. One layer is TiO2, the other is TiO2 mixed with SiO2. Good matrix adhesion and tightness of the oxide film. MAX Phase’s appearance primarily includes block, powder and film. Its appearance and morphology are affected by the preparation process. You can prepare the powdered MAX Phase in a vacuum at high temperatures. The bulk MAX Phase material can also be obtained with thermal pressure (HP) or thermal isostatic (HIP). PVD is used to produce the thin-film MAX Phase material. It has been demonstrated that the MAX Phase can be produced in industrial settings. For large industrial scale production, however, pressure-free Sintering of pure Powder is better.


The cost of Ti3AlC2
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Ti3AlC2 Supplier
Advanc3dmaterials (aka. With 12 years experience, Advanc3dmaterials (aka. Our company currently has a number of powder materials. You can also order OEM. Please call us or click on the required products to submit an inquiry.

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Co-V Fe-Fe Elements

Co-V Fe-Fe is a chemical compound consisting of two molecules of iron atoms joined together with vanadium. This alloy is used for electrical generators in aircraft. The magnetic properties of the alloy depend on the grain size and distribution of precipitates.

Typical Fe-Co-V alloys contain 0.4-1.4% Ti, 0.5-1% Al, and 0-10% Ni. These alloys have long range order, high strength, and good to excellent ductility at room temperature. They also have a high energy efficiency under fluctuating DC conditions. In addition, they exhibit high resistance to oxidation.

Fe-Co-V alloys are commonly used in applications with high saturation magnetization. However, they are prone to undesirable DC magnetic properties when the base metal exceeds 2 wt. %. Adding vanadium to the alloy reduces eddy current losses and increases the resistivity of the alloy.

Unlike conventional soft magnetic alloys, Fe-Co-V alloys have a high yield strength. Their high resistance to oxidation and low eddy current loss make them an ideal choice for applications with high saturation magnetization.

Fe-Co-V alloys have been shown to have superior room temperature ductility in an ordered state. This feature has led to their use in pole tips of high field magnets. A variety of applications have been successfully performed on Fe-Co-V alloys, including electric motors, aircraft electrical generators, and magnetostatic coils.

The invention describes a series of experimental variations on prior art Fe-Co-V alloys. Each sample exhibits a different effect on the microstructure and/or the mechanical properties.


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