Zirconium Carbide

Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis

Zirconium Carbide embodies the pinnacle of advanced ceramic materials technology, combining extreme hardness, thermal stability, and remarkable resistance to wear and corrosion.

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Overview of XXX

Zirconium Carbide (ZrC) is an extremely hard and refractory ceramic material composed of zirconium and carbon atoms. It belongs to the family of transition metal carbides, known for their high melting points, exceptional hardness, and impressive chemical stability. Zirconium carbide offers unique properties that make it suitable for demanding environments where high temperatures, wear resistance, and corrosion are significant concerns.

Features of Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis

  1. High Melting Point: Zirconium carbide has an incredibly high melting point of approximately 3530°C, making it one of the most heat-resistant materials.

  2. Exceptional Hardness: With a Vickers hardness rating around 2200 Hv, ZrC is harder than most steels and many other ceramic materials, providing excellent wear resistance.

  3. Oxidation Resistance: Forms a protective oxide layer when exposed to oxygen, which prevents further oxidation, enhancing its high-temperature performance.

  4. Chemical Stability: Resistant to most acids, except for hydrofluoric acid, and shows excellent resistance to corrosion from alkalis and salt solutions.

  5. Thermal Conductivity: Exhibits good thermal conductivity, which aids in heat dissipation and is beneficial for applications involving high heat loads.

  6. Nuclear Application Suitability: Zirconium carbide’s low neutron absorption cross-section makes it attractive for use in nuclear reactor components.

Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis

(Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis)

Parameters of Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis

The product you’re referring to is called a crucible and is used in thermal analysis for a variety of purposes, such as measuring the heat of combustion of fuels or analyzing the composition of materials.
The parameters that may be relevant to this crucible include:

* Material: This refers to the specific type of ceramic used in the crucible, which will affect its properties such as thermal conductivity, electrical resistivity, and chemical reactivity.
* Composition: This refers to the overall ratio of elements in the crucible, including the concentration of zirconium oxide and magnesium oxide, as well as any other additives or fillers.
* Temperature range: The temperature range at which the crucible will operate, which can affect its effectiveness in measuring heat of combustion.
* Porosity: The degree of porosity of the crucible, which can affect its ability to hold and contain a large amount of material during the thermal analysis process.
* Dimensions: The dimensions of the crucible, including its height, width, and depth, which can affect its stability and usability.

It’s also worth noting that these are general parameters and the actual performance of the crucible will depend on various factors such as the operating conditions and the specific requirements of the thermal analysis application.

Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis

(Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis)

Applications of Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis

  1. Nuclear Industry: Used in fuel element cladding, control rods, and other reactor core components due to its high-temperature stability and low neutron absorption.

  2. Ceramic Cutting Tools: Incorporated into cutting tool materials to enhance their wear resistance and performance in machining hard materials.

  3. Heat Exchangers and Furnace Components: Ideal for high-temperature applications due to its thermal stability and corrosion resistance.

  4. Wear-Resistant Coatings: Applied as coatings on metal parts subject to severe wear or erosion, such as pump impellers and valve components.

  5. Aerospace: In high-temperature and high-stress applications within jet engines and spacecraft due to its thermal and mechanical properties.

  6. Chemical Processing Equipment: Components in contact with corrosive chemicals where resistance to both wear and chemical attack is crucial.

Company Profile

MyCarbides is a trusted global chemical material supplier & manufacturer with over 12-year-experience in providing super high-quality carbides and relative products.

The company has a professional technical department and Quality Supervision Department, a well-equipped laboratory, and equipped with advanced testing equipment and after-sales customer service center.

If you are looking for high-quality carbide materials and relative products, please feel free to contact us or click on the needed products to send an inquiry.

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It could be shipped by sea, by air, or by reveal ASAP as soon as repayment receipt.

FAQs of Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis

Q: How is Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis produced?
A: Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis is typically synthesized through carbothermal reduction of zirconium dioxide (ZrO2) with carbon at very high temperatures.

Q: Is Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis biocompatible?
A: While zirconium itself has good biocompatibility, specific studies are needed to determine the biocompatibility of zirconium carbide for medical applications.

Q: How does Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis compare to tungsten carbide in terms of hardness and thermal properties?
A: Tungsten carbide (WC) is slightly harder than zirconium carbide and has a higher melting point, making WC more commonly used for applications requiring extreme hardness and heat resistance.

Q: Can Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis be machined or shaped easily?
A: Due to its extreme hardness, zirconium carbide is challenging to machine using conventional methods. It is typically formed through powder metallurgy techniques, sintering, or used as a coating applied by thermal spray or CVD/PECVD processes.

Q: What is the main advantage of using Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis in nuclear applications?
A: Its low neutron absorption cross-section and high-temperature stability make it an ideal material for components in nuclear reactors, minimizing interference with nuclear reactions while maintaining integrity under extreme conditions.

Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis

(Alsint C799 Yttria Stabilized ZrO2 Zirconium Oxide Ceramic Crucible Magnesium Oxide Combustion Boat For Thermal Analysis)

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