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Guangzhou Zhongli Technology Co., Ltd

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City:guangzhou

Country/Region:china

Contact Person:MrsAin Qiu

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China Custom Mining Tungsten Carbide Grinding Media 3/32 Balls For Ore Pulverization wholesale

Custom Mining Tungsten Carbide Grinding Media 3/32 Balls For Ore Pulverization

Name: Custom Mining Tungsten Carbide Grinding Media 332 Balls For Ore Pulverization
Brand: Zhongli
Price: 1 USD

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Brand Name :Zhongli

Model Number :ZWC-01

Certification :ISO CE

Place of Origin :China

MOQ :1kg

Payment Terms :L/C,T/T,Western Union

Supply Ability :40-200 ton per month

Delivery Time :within 15 days

Packaging Details :plastic+barrel

Wear Resistance :Excellent

Density :14.95 g/cm3

Shape :Spherical

Corrosion Resistance :Good

Size :1mm-20mm

Crushing Load :≥ 2000 N

Abrasion Resistance :High

Application :Grinding and milling of hard materials

Material :Tungsten Carbide

Heat Resistance :Up to 1000°C

Chemical Composition :WC-Co

Product Type :Grinding Media

Co Content :6-10%

Surface Finish :Polished

Hardness :HRA 90-92

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Product Description

Mining’s Best-Kept Secret: Tungsten Carbide for Ore Pulverization

In the world of mining, where efficiency and durability are paramount, tungsten carbide emerges as a best-kept secret for ore pulverization. Known for its exceptional hardness and wear resistance, this compound plays a crucial role in modern mining techniques. Whether it's high-pressure grinding rolls (HPGR) or mining tips, tungsten carbide stands as a testament to innovation in ore processing.

Understanding Tungsten Carbide

Tungsten carbide is a compound formed from tungsten and carbon atoms. Its unique properties, including extreme hardness, high melting point, and excellent wear resistance, make it an indispensable material in mining and ore processing. This compound is particularly vital in high-pressure grinding rolls (HPGR), a technology that has revolutionized ore processing and cement production.

The Role of Tungsten Carbide in HPGR

High-pressure grinding rolls (HPGR) are a cutting-edge technology used in mining and cement industries to crush and grind ore and raw materials. These machines leverage a combination of pressure and rotation to break down materials, offering a more efficient and effective process compared to traditional grinding methods. Tungsten carbide is essential in this process, providing the durability needed to withstand the intense pressure and friction generated.

Benefits of HPGR in Ore Processing

Energy Efficiency: HPGRs can significantly reduce energy consumption compared to traditional grinding methods, leading to lower operating costs.
Improved Particle Size Distribution: They produce a more uniform particle size, enhancing the efficiency of downstream processes like flotation and leaching.
Increased Fines Production: HPGRs can generate a higher proportion of fines, beneficial in applications such as heap leaching.

Tungsten Carbide Mining Tips

Aside from HPGR, tungsten carbide is also utilized in mining tips, which are crucial for efficient drilling operations. These tips are known for their abrasion resistance and impact resistance, making them ideal for the harsh environments of mining operations.

Characteristics of Tungsten Carbide Mining Tips

Hardness: With a hardness range of HRA 88-92, tungsten carbide mining tips can easily handle the rigors of mining.
Abrasion Resistance: They perform exceptionally well in frequent drilling operations, outlasting traditional materials.
Impact Resistance: The tips maintain structural integrity under high-impact conditions, prolonging their service life.

Mining and Refining Tungsten

Tungsten, the primary component of tungsten carbide, is a rare metal with a high melting point and density. It is typically mined from ores like scheelite and wolframite. The mining process involves crushing and grinding the ore, followed by a series of purification steps to extract tungsten.

The Refining Process

Crushing and Grinding: The ore is crushed and ground into a fine powder.
Beneficiation: This involves separating the tungsten from the waste rock through chemical reactions.
Purification: The resulting compound is purified to produce ammonium paratungstate (APT), which is then reduced to produce metallic tungsten.

The Future of Tungsten Carbide in Mining

As technology advances, the use of tungsten carbide in mining continues to evolve. Future developments in HPGR technology include the integration of sensors and automation to optimize performance. Research is also underway to explore alternative materials for wear protection, such as ceramics or diamond coatings.

Innovations in Tungsten Carbide

Sensor Integration: Real-time monitoring of wear and tear can enhance the efficiency of HPGR technology.
Alternative Materials: Exploring new materials for wear protection could further extend the lifespan of mining equipment.

1. Mechanical & Physical Properties

Property	Tungsten Carbide (WC-6%Co)	Alumina (99%)	Zirconia (YTZP)	Steel (440C)
Density (g/cm³)	14.6–15.0	3.9	6.0	7.8
Hardness (HRA)	90–92	80–85	88–90	60–65
Fracture Toughness (MPa·m½)	10–12	4–5	7–10	15–20
Compressive Strength (GPa)	4.5–6.0	2.5	2.0	2.0
Elastic Modulus (GPa)	550–650	380	200	200

Key Takeaways:

2× Harder than alumina, 3× harder than steel – Minimal wear in abrasive environments.
Highest density – Delivers superior kinetic energy for efficient grinding.
Exceptional compressive strength – Withstands high-load milling.

2. Wear & Durability Performance

Media Type	Relative Wear Rate	Lifespan (vs. Steel)	Cost Efficiency
Tungsten Carbide	1× (Benchmark)	20–50× longer	Best long-term
Zirconia	1.5–2×	10–15× longer	High upfront
Alumina	3–5×	5–8× longer	Moderate
Steel	50–100×	Baseline	Low initial cost

Real-World Example:

In cement ball mills, WC media lasts 2+ years vs. steel’s 1–2 months.

3. Chemical & Thermal Resistance

Property	Tungsten Carbide	Performance Impact
Corrosion Resistance	Good (pH 4–12)	Cobalt-bound grades sensitive to acids; nickel-bound resists pH 1–14.
Oxidation Resistance	Stable to 500°C	Avoid >600°C (cobalt binder oxidizes).
Thermal Shock	Moderate	Avoid rapid quenching (>150°C/min).

Best For:

Wet grinding of abrasive slurries (e.g., mining ores).
Organic solvents (no chemical reaction).

4. Grinding Efficiency Metrics

Particle Size Reduction: Achieves nanoscale fineness (D90 < 100nm) in high-energy mills.
Throughput: 30–50% faster than alumina/zirconia due to higher density.
Contamination Risk: Near-zero (critical for battery materials, electronics).

Optimal Applications:

Mining: Ore pulverization (gold, copper).
Ceramics: Nano-powder production.
Paints/Inks: Color-intensive grinding.

5. Industry-Specific Advantages

Industry	Benefit of WC Grinding Media
Mining	50× lifespan vs. steel in gold ore processing.
Aerospace	No Fe/Ni contamination in Ti alloy powders.
Electronics	Ultra-pure grinding for semiconductor materials.
Oil & Gas	Drilling mud additives with minimal wear.

Performance Summary: Why Choose Tungsten Carbide?

✅ Unmatched Hardness – Lowest wear rate in extreme abrasion.
✅ High Density – Faster grinding with less energy.
✅ Chemical Stability – Resists most solvents/slurries.
✅ Longest Lifespan – ROI justified in 6–12 months.

YG8 polishing WC balls

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FAQ

1. What is tungsten carbide grinding media?

Tungsten carbide grinding media consists of WC (tungsten carbide) particles bonded with cobalt (Co) or nickel (Ni). It is the hardest and most wear-resistant grinding material available, ideal for abrasive and high-impact milling.

2. What are the advantages over steel, alumina, or zirconia media?

Hardness (HRA 90+): 3× harder than steel, 2× harder than alumina.
Density (14–15 g/cm³): Higher kinetic energy for faster grinding.
Wear Resistance: Lasts 20–50× longer than steel in abrasive slurries.
Contamination-Free: No iron/nickel leaching (critical for batteries, electronics).

3. What grades/binders are available?

Cobalt-Bonded (WC-Co): 6%, 8%, 10% Co (standard for toughness).
Nickel-Bonded (WC-Ni): Better corrosion resistance (pH 1–14).
Ultra-Fine Grain: Sub-micron WC for nano-grinding.

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