Boron Carbide

Looking for a reliable supplier of Boron Carbide on demand? Great Abrasive is your solution.

Premium Boron Carbide Supplier in China

Boron Carbide is one of the hardest man-made materials available in commercial quantities that has a finite melting point low enough to permit its relatively easy fabrication into shapes.

We can provide you with boron carbide for various fields and customize the products according to different applications.

Boron Carbide

Why Choose Boron Carbide from GREAT Abrasive?

Choosing Boron Carbide from GREAT Abrasive offers significant advantages for your industrial needs:

Strong Supply Capacity

With an annual production of 5,000 tons, we ensure consistent supply and delivery.

Broad Product Range

Our Boron Carbide is available in particle sizes down to a median diameter of 0.5 microns, catering to diverse specifications.

Advanced Smelting Technology

We operate five 4000KVA high-power furnaces, leading in domestic smelting capabilities.

Strict Quality Control

We maintain rigorous standards by using only top-quality boric acid imported from the USA, ensuring superior product quality from the source.

Customization and Expertise

We provide tailored solutions and expert consultations to meet specific industrial requirements.

Wide Range of Applications

Our Boron Carbide is essential in industries requiring high-precision grinding, defense, nuclear industry, refractory materials, and engineering ceramics.

FAQ About Boron Carbide

Boron Carbide is an extremely hard ceramic material, second only to diamond and cubic boron nitride in hardness. It is extensively used in abrasive materials, cutting tools, and grinding media, as well as in military armor and bulletproof vests due to its exceptional hardness and lightweight properties.

Boron Carbide boasts a Mohs hardness of about 9.3, making it one of the hardest materials available. This exceptional hardness allows it to outperform other abrasives like Boron Carbide and aluminum oxide in terms of abrasion resistance and lifespan in rigorous applications.

Yes, Boron Carbide maintains its strength and thermal stability up to approximately 400°C. It has a melting point of about 2,450°C, which makes it suitable for high-temperature environments, though its oxidation resistance limits its performance at temperatures exceeding 500°C.

Boron Carbide's incredible hardness and chemical inertness make it ideal for abrasive blasting operations, especially for the treatment of hard metals and materials that require a fine, polished finish. Its angular particle shape provides a very aggressive cutting action that is highly effective at removing tough surfaces.

Boron Carbide is typically manufactured through the reduction of boric acid or boron oxide with carbon in an electric arc furnace. This process results in a hard, crystalline structure that is then crushed and milled to the desired particle size for various applications.

The quality of Boron Carbide is primarily determined by the purity of the raw materials and the precision of the manufacturing process. Impurities can significantly affect its hardness and structural integrity, while consistent particle size distribution is crucial for specific industrial applications.

Boron Carbide is available in various grades, typically categorized by grit size ranging from very fine powders used for polishing to coarser grains used in abrasive blasting and cutting tools. The specific grade needed depends on the application's requirements for surface finish and material removal rate.

While Boron Carbide is more expensive than other common abrasives like Boron Carbide and aluminum oxide, its longevity and effectiveness in aggressive environments can lead to lower overall costs in terms of replacement and downtime.

Despite its chemical inertness, Boron Carbide dust can be harmful if inhaled, and it should be handled with appropriate safety measures including wearing respiratory protection, protective clothing, and ensuring adequate ventilation in the working environment.

Boron Carbide is considered environmentally benign as it is a non-toxic material and does not emit harmful gases during application. However, like all mining and manufacturing processes, its production must be managed to minimize environmental impacts.

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The Ultimate Buyer’s Guide: How to Purchase Boron Carbide

Are you in the market for Boron Carbide? Look no further.

This all-inclusive buyer’s guide provides you with crucial insights into Boron Carbide, which find applications in diverse industry, from abrasives to blasting and refractories. Whether you’re contemplating importing them for your projects or planning local distribution, this guide furnishes invaluable information to guide your decision-making process.

Table of contents

Chapter 1

What is Boron Carbide?

Boron Carbide is a very hard and durable ceramic material with the chemical formula B4C. It’s one of the hardest materials known, ranking third after diamond and cubic boron nitride. This exceptional hardness makes it a prime candidate for use in various industrial applications where wear and tear resistance is crucial.

Chapter 2

Property of Boron Carbide
  • Hardness
    It has a Mohs hardness of about 9.3, making it incredibly resistant to scratching and wear.
  • Lightweight
    Boron Carbide is also remarkably lightweight, which makes it especially valuable in applications where weight reduction is essential, such as in ballistic armor.
  • Thermal Stability
    It can withstand high temperatures, maintaining its strength up to about 400°C, with a melting point of approximately 2450°C.
  • Chemical Inertness
    It exhibits resistance to attack by most acids and alkalis.
  • Low Density
    Its low density compared to other hard materials makes it ideal for more weight-sensitive applications.

These properties make Boron Carbide an excellent material for abrasive powders, body armor, tank armor, and various other applications requiring materials that can endure extreme conditions and environments.

Chapter 3

Specification of Boron Carbide
Chemical Property (%)
B4C 96.75
Free Boron 0.27
B2O3 0.3
Free Carbon 1.02
Fe2O3 0.18
Physical Property
Color Black
Crystal Structure Rhoombohedral
Moleclar Formula B4C
Melting Point 2450℃
Boiling Point 3500℃
Mohs Hardness 9.3
True Density 2.52 g/cm3

Chapter 4

How is Boron Carbide Produced?

Boron Carbide is produced primarily through a high-temperature reduction process using boron oxide (B2O3) and carbon as starting materials. Here’s a detailed explanation of the production process:

  • Raw Material Preparation
    The initial step in producing Boron Carbide involves preparing the raw materials. Boron oxide (B2O3), derived from boric acid or borax, is mixed with a carbon source. The carbon source can be petroleum coke, graphite, or another form of carbon with high purity.
  • Carbothermal Reduction
    The mixture of boron oxide and carbon is subjected to carbothermal reduction in an electric arc furnace. This process typically occurs at temperatures ranging from 1400°C to 2500°C. During carbothermal reduction, the carbon reduces the boron oxide to Boron Carbide, according to the following chemical reaction: 2B2O3+7C→B4C+6CO
    This reaction releases carbon monoxide (CO) as a byproduct, which escapes as gas.
  • Synthesis at High Temperature
    The high temperature required for the reaction is achieved using an electric arc furnace, where an electric arc is struck between carbon electrodes immersed in the mixture. The intense heat generated by the arc facilitates the reaction to produce Boron Carbide powder.
  • Cooling and Collection
    Once the reaction is complete, the material is allowed to cool slowly inside the furnace. As it cools, the Boron Carbide crystallizes into a solid mass. This mass is then crushed and milled into a fine powder, which is the form commonly used for most applications.
  • Purification and Sizing
    The Boron Carbide powder is further processed to remove impurities and achieve the desired particle size. This may involve additional milling, washing, and sieving processes. The powder’s purity and particle size are critical factors that determine its suitability for specific applications, such as abrasives or ceramics.
  •  Quality Control
    Throughout the production process, quality control measures are implemented to ensure the product meets specific standards. This includes testing for purity, particle size distribution, and other relevant properties.
  • Packaging
    Finally, the processed Boron Carbide powder is packaged in appropriate containers to protect it from contamination and moisture, ensuring it remains effective for industrial use.

This detailed production process underscores the complexities involved in producing Boron Carbide, a material valued for its extreme hardness and chemical stability in harsh environments.

Chapter 5

What is Boron Carbide Used For?

Boron Carbide (B4C) is a highly versatile and extremely hard ceramic material, utilized across various industries for its unique properties. Here’s a detailed look at its primary uses:

Abrasive Applications

Due to its high hardness (Mohs hardness of about 9.3), Boron Carbide is an excellent material for abrasive applications. It is used in abrasive grits and powders for processes such as water jet cutting, lapping, and grinding of hard materials. These abrasives are ideal for use on hard metals, ceramics, and glasses where precision and minimal material damage are critical.

Body Armor and Armored Vehicles

Boron Carbide’s low density combined with its high hardness makes it ideal for ballistic armor. It is one of the preferred materials for personal body armor plates, as well as armor plating in military vehicles. It absorbs the impact energy of projectiles effectively, thereby providing protection against high-velocity bullets and shrapnel.

Nuclear Applications

Boron Carbide is also utilized in nuclear reactors as a neutron absorber due to its high cross-section for neutron capture. It plays a critical role in controlling nuclear reactions and ensuring safety by absorbing excess neutrons that are produced during fission processes.

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High-Temperature Thermoelectric Materials

Because of its ability to withstand extremely high temperatures, Boron Carbide is used in thermoelectric materials that convert heat to electricity. These applications are particularly useful in power generation where waste heat recovery is crucial, such as in aerospace and automotive industries.

Refractory Materials

Its high melting point (about 2450°C) and chemical inertness make Boron Carbide an excellent material for refractory applications. It is used in the linings of furnaces and reactors that operate at high temperatures, especially in the metallurgy of metals like iron and steel.

Nozzles for Abrasive Water Jets and Sandblasting

Boron Carbide’s resistance to abrasion and its hardness are exploited in the manufacture of nozzles for abrasive water jets and sandblasting equipment. These nozzles need to withstand the erosive action of high-speed, abrasive-laden water or air streams used in cutting and cleaning operations.

Cutting Tools and Dies

The hardness and wear resistance of Boron Carbide make it suitable for manufacturing cutting tools and dies, particularly for applications that require maintaining sharp edges and tolerances at high temperatures.

Antioxidant Additive in Refractory Materials

Boron Carbide is also added as an antioxidant to other refractory materials to improve their oxidation resistance, enhancing their lifespan and performance in harsh environments.

Wear Parts

It is used in the production of wear-resistant parts, which are crucial in machinery and equipment subjected to severe wear conditions, ensuring longevity and reliability.

Through these applications, Boron Carbide serves critical roles in modern technology and industrial processes, leveraging its unique phyB4Cal and chemical properties to meet demanding performance requirements.

Chapter 6

Boron Carbide (B4C) and Silicon Carbide (SiC) are both advanced ceramic materials known for their hardness and durability. However, they possess distinct properties that make them suitable for different applications. Here’s a comparative overview presented in a table format:

Item Boron Carbide (B4C) Silicon Carbide (SiC)
Hardness Extremely hard, about 9.3 on the Mohs scale Slightly less hard than boron carbide, about 9-9.5 on the Mohs scale
Toughness Relatively brittle compared to silicon carbide Generally tougher and more resistant to fracture
Thermal Conductivity Lower thermal conductivity, around 30 W/mK Higher thermal conductivity, up to 490 W/mK
Melting Point Higher melting point at approximately 2450°C Lower melting point, about 2730°C
Density Lower, around 2.52 g/cm³ Higher, around 3.21 g/cm³
Chemical Stability Good chemical resistance but less oxidation resistance at high temperatures Excellent chemical and oxidation resistance
Electrical Conductivity Insulating properties Varies from semi-conductive to conductive depending on purity and doping
Cost Typically more expensive due to production complexity Generally less expensive and more widely available
Color Typically black Generally black or green, depending on the purity and crystalline form
Applications Ideal for abrasive applications, body armor, and neutron absorbers in nuclear reactors Widely used in abrasive applications, electronic substrates, refractories, and as structural materials in high-temperature applications

This comparison shows that while both materials are extremely hard ceramics, their differences in toughness, thermal properties, and electrical conductivity tailor them for specific uses across various high-performance environments.

What's the difference between Boron Carbide and Silicon Carbide?

Chapter 7

Key Considerations When Buying Boron Carbide

When purchasing boron carbide, it’s crucial to consider several factors to ensure the material meets your specific application requirements effectively. Here’s a consolidated list of these factors, blending their importance and considerations:

Purity

Ensure the boron carbide has minimal impurities, as its performance, particularly in terms of hardness and abrasion resistance, is significantly influenced by purity. Check the supplier’s specifications for levels of unwanted elements like silicon and carbon.

Grain Size and Distribution

The size and uniformity of boron carbide grains are critical for consistency and the quality of the final product. Ensure that the grain size distribution matches the precision required for your specific application, especially in abrasive settings.

Hardness and Toughness

While the primary attribute of boron carbide is its hardness, the material’s toughness is crucial in applications involving dynamic stresses, such as body armor. Verify both hardness and toughness to ensure they meet the specific requirements of your application.

Thermal Stability

For high-temperature applications, the thermal stability of boron carbide is essential. Check the material’s maximum operating temperature and thermal shock resistance to ensure it aligns with the thermal demands of your process.

Chemical Compatibility

Considering boron carbide’s chemical inertness, it’s vital to ensure that it is compatible with any chemicals it may encounter in your process, particularly at elevated temperatures. Verify its resistance to the specific environments it will face.

Supplier Reliability and Certifications

The quality and consistency of boron carbide can vary significantly between suppliers. Opt for suppliers with reliable track records, robust customer service, and necessary industry certifications such as ISO standards. References or case studies relevant to your industry are also valuable.

Cost-Effectiveness

Evaluate not only the initial price of boron carbide but also consider the longevity and performance improvements it may offer over other materials. Boron carbide is typically more expensive but can be more cost-effective in the long run due to its durability.

Customization Options

Certain applications may require customized forms of boron carbide. Check if the supplier can provide custom formulations, shapes, or composites that combine boron carbide with other materials to meet specific needs.

Environmental and Safety Aspects

Handling, storage, and disposal of boron carbide should comply with local environmental and safety regulations. Familiarize yourself with the material safety data sheets (MSDS) for proper management practices.

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By carefully evaluating these integrated aspects, you can select a boron carbide product that delivers optimal performance, safety, and value for your particular industrial applications.

Chapter 8

Boron Carbide Packaging and Transportation Tips

Purchasing Boron Carbide (B4C) necessitates careful packaging and transportation to maintain its quality. Here are streamlined tips for effectively handling B4C:

Packaging Tips
  • Moisture Barrier: Choose materials with excellent moisture resistance. Moisture-proof films or sealed bags are essential.
  • Durability: Select strong, durable packaging to endure transportation pressures.
  • Size Appropriateness: Ensure packaging is correctly sized for the volume, optimizing protection and efficiency.
  • Pallet Corner Smoothing: Smooth pallet corners to prevent packaging damage.
  • Strapping Protection: Use protective boards under straps to avoid bag damage.
Transportation Tips
  • Container Organization: Arrange packages neatly in containers to prevent damage.
  • Transit Protection: Secure goods well for factory-to-port transit, protecting against road hazards.
  • Mixed Loading Care: When combining pallets and bulk bags, use cushioning to reduce movement and prevent damage.
  • Weather Prep: In humid or rainy weather, increase packaging’s moisture protection and consider container desiccants.

Efficient packaging and transportation are critical for preserving Boron Carbide quality. By focusing on moisture prevention, packaging integrity, and careful transit handling, you can ensure your B4C arrives in excellent condition. Partnering with a supplier knowledgeable in these areas is key to minimizing transit risks and maintaining product standards.

Chapter 9

In Summary

Welcome to Great Abrasive, where we specialize in the provision of top-tier Boron Carbide (B4C) abrasives, renowned for their superior hardness and exceptional performance across a broad range of applications. As a leader in the abrasive industry with over three decades of experience, we understand the complexities involved in selecting the perfect abrasive material.

Choose Great Abrasive as your trusted partner and leverage our expertise to secure premium Boron Carbide products that cater precisely to your needs for grinding, cutting, and finishing. Our commitment to quality and customer-centric approach ensures that you receive not only the best products but also customized solutions designed to overcome your specific operational challenges.

Embark on a journey with Great Abrasive and allow us to enhance your projects with Boron Carbide abrasives. Our dedication to guiding you through the intricacies of abrasive technology guarantees that you achieve outstanding surface treatment results, propelling your project to new heights of success.

Unleash Cutting-Edge Performance with Our Boron Carbide!

Elevate your abrasive applications with Boron Carbide from GREAT Abrasive, the ultimate choice for unmatched hardness and lightweight performance. Customized to meet your specific needs, it excels in aggressive material removal while providing outstanding durability and efficiency in your most demanding projects.

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