Detailed Description: Alumina (Corundum) Ceramic Ball Mill Jars for Planetary Ball Mills
Alumina ceramic jars, often marketed as "corundum jars," are a premium-grade grinding medium designed for applications where minimal contamination and high wear resistance are paramount. They represent a critical solution for advanced material processing where stainless steel jars are unsuitable.
Physical Parameters
|
Composition
%
|
Specific Gravity
g/cm3
|
Hardness
Mho’s
|
Bending strength (Mpa)
|
Water absorption rate
%
|
|
Al2O3 ≥ 99
|
≥3.8
|
9
|
> 350
|
≤0.005
|
Specification Parameters
|
Volume of Jar
|
Inner Diameter
(mm)
|
External Diameter
(mm)
|
Inner Depth
(mm)
|
Height of without lid
(mm)
|
Total Height
(mm)
|
|
50ml
|
38
|
55
|
52
|
60
|
67
|
|
100ml
|
50
|
65
|
58
|
66
|
75
|
|
250ml
|
74
|
92
|
70
|
78
|
88
|
|
500ml
|
84
|
100
|
100
|
108
|
118
|
|
1L
|
108
|
128
|
128
|
138
|
148
|
|
2L
|
138
|
158
|
140
|
150
|
162
|
|
3L
|
138
|
158
|
198
|
208
|
220
|
1. Core Characteristics & Composition
Material: Manufactured from high-purity (≥99%) aluminum oxide (Al₂O₃), also known as alumina. The term "corundum" refers to the natural crystalline form of aluminum oxide (sapphire, ruby), indicating a very hard and dense sintered ceramic.
Manufacturing: These jars are precision-sintered at extremely high temperatures. This process creates a polycrystalline structure that is very dense, hard, and mechanically strong.
Design: Similar to other jars, they are engineered to fit standard planetary mill mounting systems. They feature a cylindrical body with a mechanically sealed lid, often using a silicone or rubber O-ring to ensure an airtight seal for grinding under inert or vacuum conditions.
Surface: The interior surface is exceptionally smooth and vitrified (glass-like), which minimizes adhesion of sample material and allows for easy cleaning.
2. The "Super Wear-Resistant" & "Special" Claim
The "special" nature of alumina jars lies in their unique combination of properties, making them superior to metals and polymers for specific high-end applications.
Extreme Hardness: Alumina ceramic has a Mohs hardness of 9 (on a scale where diamond is 10). This makes it harder than stainless steel and most other common jar materials. This hardness directly translates to exceptionally low wear rates, even when using highly abrasive materials or hard grinding media like zirconia balls.
Wear Mechanism: While some wear still occurs, the amount of material abraded from the jar wall is orders of magnitude lower than from stainless steel. Furthermore, the contaminant introduced (aluminum) is often less problematic than iron, chromium, and nickel in many research fields.
3. Advantages
- Extremely Low Contamination (Primary Advantage): This is the main reason for choosing alumina jars. They introduce only trace amounts of aluminum oxide into the sample, which is often acceptable or even undetectable in many analytical methods. This makes them ideal for:
- Preparing samples for elemental analysis techniques like ICP-MS, ICP-OES, and XRF.
- Processing advanced ceramic powders (e.g., for electronics, batteries, catalysts) where metallic iron contamination would ruin material properties.
- Grinding pharmaceutical and biological materials where metal ions could act as catalysts or impurities.
- High Wear Resistance: They offer the best wear resistance among all practical and relatively affordable ceramic jar options, significantly outperforming agate and PTFE. Their lifespan is very long when used correctly.
- High Compressive Strength: They excel under the compressive forces generated by the grinding balls in a planetary mill.
- Chemical Inertness: Highly resistant to acids, solvents, and other chemicals. They will not rust or corrode, making them perfect for wet grinding with a wide range of solvents.
- Non-magnetic: Essential for processing materials where magnetic impurities must be avoided.
4. Disadvantages and Important Considerations
- Brittleness (The Biggest Drawback): Unlike stainless steel, alumina is a ceramic and is susceptible to chipping, cracking, or catastrophic breakage from impact shock. This can happen if the jar is dropped, struck against a hard surface, or if an improper grinding media-to-sample load is used.
- Lower Impact Toughness: They cannot withstand the same level of sharp, point-impact forces that stainless steel can. Using very large grinding balls or running the mill without any sample ("dry milling") can easily damage the jar.
- Potential for Alumina Contamination: While vastly superior to metal jars, they are not 100% contamination-free. For applications where any aluminum contamination is unacceptable (e.g., some semiconductor research), zirconia (YSZ) jars are the next step up, albeit at a much higher cost.
- Thermal Shock Sensitivity: Rapid temperature changes (e.g., taking a hot jar and placing it in cold water) can cause cracking due to differential expansion.
- Weight: They are heavier than polymer jars but typically lighter than stainless steel jars of the same volume.
- Cost: They are more expensive than stainless steel jars but generally less expensive than zirconia jars.
5. Comparison within the Ceramic Jar Family
| Material |
Contamination |
Wear Resistance |
Toughness |
Best Use Case |
| Agate (SiO₂) |
Lowest (Si, O) |
Good |
Low (Most Brittle) |
Ultimate purity for geochemistry, ICP-MS. Small volumes. |
| Alumina (Al₂O₃) |
Very Low (Al, O) |
Excellent |
Medium |
The best all-around high-purity jar. General ceramics, batteries. |
| Zirconia (YSZ) |
Low (Zr, Y) |
Ultra-High (The Best) |
High (Toughest Ceramic) |
Extreme wear applications, nano-grinding, mechanical alloying. |
6. Typical Applications
- Advanced Ceramics: Grinding and mixing of zirconia, silicon carbide, aluminum nitride, and other technical ceramics.
- Battery Materials: Preparation of cathode and anode materials (e.g., LFP, NMC, graphite) where iron contamination would severely impact electrochemical performance.
- Pigments and Dyes: Size reduction where color must not be affected by metallic stains.
- Geological Sample Preparation: For analysis where the introduction of Fe, Cr, Ni must be avoided.
- Pharmaceutical Research: Size reduction of active pharmaceutical ingredients (APIs) without metal catalyst contamination.
- Electronic Materials: Processing of ferrites, dielectrics, and other precursor powders.
Summary
Alumina (corundum) ball mill jars are the premier choice for high-purity, wear-resistant grinding. They masterfully balance the critical need for minimal contamination with outstanding mechanical durability against abrasive wear. While their brittle nature requires careful handling and operation, their advantages make them an indispensable tool in modern materials science, chemistry, and geology laboratories where the integrity of the sample is the highest priority. They are the logical and most cost-effective step up from stainless steel when contamination becomes a concern.
Ship to South Korea
Ship to Indonesia
Your message must be between 20-3,000 characters!
