titanium-niobium superconductor rod

Overview of titanium-niobium superconductor rod

Niobium Carbide (NbC) is a refractory ceramic compound composed of niobium and carbon elements, known for its exceptional hardness, high melting point, and excellent thermal and electrical conductivity. It belongs to the family of transition metal carbides, which are valued for their remarkable mechanical properties and resistance to extreme environments. Niobium carbide is a dark gray, extremely hard material that finds application in areas requiring wear resistance, high-temperature stability, and corrosion resistance.

Features of titanium-niobium superconductor rod

1. High Melting Point: Niobium carbide has a melting point of approximately 3,400 to 3,500°C, making it suitable for high-temperature applications.

2. Hardness and Wear Resistance: With a Vickers hardness in the range of 2000-2500 Hv, NbC is one of the hardest materials, providing excellent wear resistance in abrasive environments.

3. Thermal Conductivity: It exhibits good thermal conductivity, facilitating heat dissipation and making it useful in high-heat-load applications.

4. Chemical Stability: Niobium carbide is resistant to corrosion from most acids and alkalis, excluding hydrofluoric acid, and is stable under oxidizing conditions.

5. Electrical Conductivity: Although a ceramic, niobium carbide demonstrates moderate electrical conductivity, contributing to its use in some electronic applications.

6. Density: Despite its hardness, niobium carbide has a relatively high density of about 8.53 g/cm³, adding to its mass efficiency in wear-resistant coatings.

(titanium-niobium superconductor rod)

Parameters of titanium-niobium superconductor rod

The parameter “niobium thickness” is used to describe the thickness of a niobium layer that makes up the surface of a titanium-niobium superconductor rod. This parameter is typically expressed in nanometers (nm) and refers to the depth of the niobium layer at which the critical temperature for electrical conductivity changes from absolute zero (0 K) to room temperature.
A higher niobium thickness generally results in stronger magnetic fields and better conductor performance, but it also increases the cost and complexity of the device. Therefore, the optimal niobium thickness for a particular application will depend on factors such as the required voltage, current density, and desired magnetic field strength.
It’s worth noting that this parameter is just one aspect of the overall performance of a titanium-niobium superconductor rod. Other important parameters include the material composition, geometry, and operating conditions, all of which can influence the device’s efficiency and reliability.

(titanium-niobium superconductor rod)

Applications of titanium-niobium superconductor rod

1. Cutting Tools and Tool Inserts: In the manufacturing of cutting and machining tools due to its wear resistance and ability to maintain sharp edges at high temperatures.

2. Wear-Resistant Coatings: As a coating on metal parts exposed to severe wear conditions, such as drill bits, mining equipment, and pump components.

3. Heat Shields and Furnace Components: In high-temperature furnaces and kilns due to its excellent thermal stability and resistance to oxidation.

4. Electrode Materials: In some specialized electrodes for electrical discharge machining (EDM) and electrochemical processes.

5. Cemented Carbides: As a component in cemented carbide composites, enhancing their toughness and wear resistance.

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.

Payment Methods

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Shipment

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

FAQs of titanium-niobium superconductor rod

Q: How is titanium-niobium superconductor rod produced?
A: titanium-niobium superconductor rod is typically synthesized through the carburization of niobium metal powder or oxide at high temperatures in a reducing atmosphere or via direct reaction of niobium with carbon.

Q: Can titanium-niobium superconductor rod be machined?
A: Due to its extreme hardness, machining niobium carbide directly is challenging. It is often fabricated using powder metallurgy techniques, sintering, or applied as a coating through processes like chemical vapor deposition (CVD) or physical vapor deposition (PVD).

Q: Is titanium-niobium superconductor rod biocompatible?
A: While not extensively studied for biomedical applications, niobium-based materials generally exhibit good biocompatibility. Specific studies would be required to assess NbC’s suitability for biomedical implants.

Q: How does titanium-niobium superconductor rod compare to tungsten carbide in terms of hardness?
A: Both are hard materials, but tungsten carbide (WC) is slightly harder, with a typical Vickers hardness of around 2200 Hv, whereas niobium carbide ranges from 2000 to 2500 Hv.

Q: What are the main advantages of using titanium-niobium superconductor rod in tooling applications?
A: The advantages include increased tool life due to high hardness and wear resistance, improved heat resistance allowing for faster machining speeds, and retention of cutting edge sharpness even under high loads.

(titanium-niobium superconductor rod)