Overview of aluminum nitride ceramics

Aluminum Nitride Ceramic is an advanced ceramic material with aluminum nitride as the main component. It has been widely used in electronics, optics, and mechanics due to its unique properties.

Features of aluminum nitride ceramics

High thermal conductivity: Aluminum nitride ceramics have relatively high thermal conductivity, usually between 170-260 W/m·K, which makes it an excellent heat dissipation material. It is especially suitable for electronic devices that require efficient heat dissipation, such as substrate materials for power semiconductor devices.

Good electrical insulation: Despite its high thermal conductivity, aluminum nitride ceramics are excellent insulators of electricity, which can effectively prevent current leakage and ensure the safe operation of electronic components.

Low dielectric constant and dielectric loss: These characteristics make aluminum nitride ceramics very suitable for use in high-frequency circuits because it can reduce energy loss during signal transmission.

High temperature resistance: Aluminum nitride ceramics can maintain structural stability and strength at extremely high temperatures. Its melting point is about 2800°C, so it is suitable for applications in high temperature environments.

Low thermal expansion coefficient: Compared with semiconductor materials such as silicon, aluminum nitride has a lower thermal expansion coefficient, which means it has better dimensional stability when the temperature changes, which helps improve packaging reliability.

Corrosion resistance: Aluminum nitride ceramics have good chemical stability to most molten metals and are not easily oxidized or corroded, allowing them to perform well in harsh environments.

High mechanical strength: Although not as hard as some other types of ceramic materials, aluminum nitride ceramics still provide enough mechanical strength to allow them to be used in many structural applications.

(Customized AlN-BN Aluminum Nitride Composite Boron Nitride Ceramic Crucible)

Specifications of Customized AlN-BN Aluminum Nitride Composite Boron Nitride Ceramic Crucible

The Customized AlN-BN Aluminum Nitride Composite Boron Nitride Porcelain Crucible is designed for high-performance industrial applications. It combines aluminum nitride (AlN) and boron nitride (BN) to develop a product with exceptional thermal and chemical stability. The crucible runs effectively in temperature levels approximately 1800 ° C in inert ambiences. It stands up to thermal shock, making it suitable for rapid heating or cooling down processes. The composite structure ensures reduced thermal development, reducing the threat of fracturing under severe conditions.

The material provides excellent electric insulation, suitable for semiconductor manufacturing or electronic part handling. Its non-wetting surface prevents adhesion to molten metals, streamlining product removal and decreasing contamination. The crucible’s high pureness (over 99.5%) ensures minimal communication with delicate products like unusual planet steels or high-purity alloys. It stands up to rust from acids, antacid, and molten salts, extending its lifespan in rough environments.

Mechanical toughness is improved through precise sintering techniques, guaranteeing resilience under repeated thermal biking. The crucible’s thickness exceeds 3.2 g/cm TWO, providing structural integrity while keeping light-weight homes. Personalized dimensions are offered, with resistances as limited as ± 0.1 mm for specialized applications. Options consist of cylindrical, rectangle-shaped, or custom-shaped styles to fit certain furnace configurations. Surface finishes range from conventional machined structures to polished finishes for reduced product sticking.

The item sustains lab-scale research study and massive commercial manufacturing. It works with vacuum cleaner settings and controlled environments like argon or nitrogen. Thermal conductivity is enhanced for uniform heat circulation, important for processes needing precise temperature level control. Optional finishes like silicon carbide (SiC) or yttrium oxide (Y TWO O THREE) can be looked for boosted performance in responsive atmospheres.

Applications consist of metal smelting, crystal development, and advanced ceramics sintering. It offers the aerospace, electronics, and power fields, particularly in taking care of high-purity products or extreme thermal demands. Preparations for custom orders vary by complexity, with conventional layouts delivering within 10-14 service days. Technical support is offered for product compatibility checks or design optimization. Product packaging includes protective cushioning to avoid transit damages, with choices for expedited shipping.

(Customized AlN-BN Aluminum Nitride Composite Boron Nitride Ceramic Crucible)

Applications of Customized AlN-BN Aluminum Nitride Composite Boron Nitride Ceramic Crucible

Customized AlN-BN aluminum nitride composite boron nitride ceramic crucibles are utilized widely in high-temperature industrial processes. These crucibles integrate light weight aluminum nitride and boron nitride, creating products that handle extreme warm well. They stand up to chemicals properly and last longer than traditional options. Industries like metallurgy and semiconductor production depend on them for demanding tasks.

These crucibles work best in metal processing. They melt steels like light weight aluminum, copper, and alloys without damaging down. Their high thermal stability keeps them undamaged also under quick temperature changes. This reduces downtime in assembly line. Semiconductor manufacturers use them for expanding crystals and handling silicon. The crucibles’ pureness protects against contamination, guaranteeing high-grade electronic components.

Aerospace and energy markets benefit as well. The crucibles handle innovative materials like titanium and ceramics. Their reduced thermal development suggests they remain secure in extreme environments. Photovoltaic panel makers utilize them to generate solar batteries. The crucibles’ resistance to thaw salts and harsh gases improves effectiveness in energy storage systems.

Study labs and specialized material manufacturers depend on these crucibles. They refine rare planet components and superconductors securely. The composite framework prevents reactions with delicate materials. Custom-made shapes and sizes fit specific equipment requirements. This adaptability sustains innovation in nanotechnology and advanced ceramics.

The crucibles’ longevity cuts costs gradually. They require less replacements contrasted to graphite or quartz choices. Their efficiency in vacuum or inert gas setups matches high-precision applications. Business gain reliability and consistency in high-stakes procedures.

Custom-made AlN-BN crucibles meet stringent industry standards. They are tested for thermal shock resistance and mechanical toughness. Designers readjust make-ups to match special functional demands. This adaptability makes them crucial for sophisticated industrial and scientific work.

Company Introduction

Advanced Ceramics founded on October 17, 2014, is a high-tech enterprise committed to the research and development, production, processing, sales and technical services of ceramic relative materials and products.. Since its establishment in 2014, the company has been committed to providing customers with the best products and services, and has become a leader in the industry through continuous technological innovation and strict quality management.

Our products includes but not limited to Silicon carbide ceramic products, Boron Carbide Ceramic Products, Boron Nitride Ceramic Products, Silicon Carbide Ceramic Products, Silicon Nitride Ceramic Products, Zirconium Dioxide Ceramic Products, Quartz Products, etc. Please feel free to contact us.(nanotrun@yahoo.com)

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T/T, Western Union, Paypal, Credit Card etc.

Shipment Methods

By air, by sea, by express, as customers request.

5 FAQs of Customized AlN-BN Aluminum Nitride Composite Boron Nitride Ceramic Crucible

What is a Customized AlN-BN ceramic crucible made of? The crucible combines aluminum nitride (AlN) and boron nitride (BN). This mix creates a material with high thermal conductivity and excellent heat resistance. It works well in extreme temperatures and harsh chemical environments. The composite structure balances strength and thermal stability better than single-material options.

What industries use these crucibles? They are common in semiconductor manufacturing, metal melting, and high-temperature research labs. The crucibles handle molten metals, advanced ceramics, and chemical vapor deposition processes. Custom shapes and sizes fit specific equipment or experimental needs. They are ideal for applications requiring precise temperature control and minimal contamination.

How do AlN-BN crucibles compare to traditional ones? Standard crucibles like quartz or graphite crack under rapid temperature changes. AlN-BN resists thermal shock due to low expansion rates. It lasts longer in cyclic heating and cooling. The material resists corrosion from acids and molten metals. This reduces downtime and replacement costs.

Can these crucibles handle custom specifications? Yes. Manufacturers adjust dimensions, wall thickness, and purity levels based on client needs. Special coatings or surface treatments improve performance for specific tasks. Custom designs match unique furnace setups or experimental setups. Production times vary depending on complexity.

How should AlN-BN crucibles be maintained? Avoid sudden temperature shifts to prevent stress fractures. Clean residues with non-abrasive tools and compatible solvents. Store in dry conditions to prevent moisture absorption. Inspect for cracks or wear before each use. Follow the manufacturer’s heating and cooling guidelines to extend lifespan.

(Customized AlN-BN Aluminum Nitride Composite Boron Nitride Ceramic Crucible)