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High Energy Planetary Mill
VBCC's HIGH ENERGY PLANETARY MILL
Description:
Planetary ball mills indeed sound like marvels of engineering! By leveraging the dynamic interplay of centrifugal and Coriolis forces, they achieve impressive feats of pulverization. In VBCC's high energy planetary mill, the stationary jar filled with grinding balls becomes the center of attention. The rotation of the sun wheel sets the stage for an energetic ballet in a planetary orbit, as the grinding balls accelerate and collide with the sample material. These high-energy collisions facilitate swift and efficient size reduction, a vital process in both research endeavors and industrial applications.
The versatility and efficacy of planetary ball mills make them indispensable tools in laboratories and industrial settings alike. Whether in the pursuit of groundbreaking discoveries or the optimization of industrial processes, these mills stand as stalwart allies, enabling the transformation of raw materials into finely pulverized powders with remarkable efficiency.
VBCC's dedication to optimizing their planetary ball mills for researchers is commendable, especially considering the critical factors that influence grinding efficiency. Let's delve into some key aspects:
1. Jar Selection: The choice of jar material is crucial, as it determines factors like chemical compatibility, wear resistance, and contamination risk. Depending on the application, researchers may opt for materials like stainless steel, zirconia, or tungsten carbide.
2. L/D Ratio: The length-to-diameter ratio (L/D) of the jar plays a significant role in the milling process. It influences the trajectory and impact energy of the grinding balls, affecting the efficiency and effectiveness of size reduction. Optimizing this ratio can lead to better performance.
3. Ball Selection: Selecting the appropriate grinding balls is essential for achieving the desired particle size and milling efficiency. Factors such as material composition, size, and shape impact the grinding process. Different materials (e.g., steel, ceramic, or Tungsten carbide) offer varying levels of abrasion resistance and compatibility with the sample material.
4. Jar Weight: The weight of the jar affects the overall dynamics of the milling process. A heavier jar can provide more stability and better energy transfer during grinding, leading to enhanced efficiency. However, it's essential to find a balance to avoid excessive strain on the mill's motor and components.
VBCC's emphasis on research and development reflects their commitment to meeting the diverse needs of researchers. By fine-tuning these critical parameters and leveraging innovative design features, VBCC has succeeded in delivering a mill capable of producing ultra-fine (nano-sized) particles in record time. This capability is invaluable for researchers working in fields where precise control over particle size is paramount, such as nanotechnology, materials science, and pharmaceuticals.
Key Features: High Pulverization Energy: Enabled by centrifugal and Coriolis forces, resulting in rapid size reduction. Versatility: Suited for mechano chemistry, ultra fine colloidal grinding, mixing, and homogenizing. Customization: Available with different numbers of grinding stations, and jars and balls in various sizes and materials. Material Selection: Critical for preventing contamination and optimizing grinding efficiency. Energy Input and Hardness: Factors influencing the selection of jar and ball materials based on sample properties. Grinding System: Hard Tungsten Carbide grinding jar with stainless steel casing, Tungsten Carbide grinding media (10 mm diameter spherical balls), and a maximum load capacity of approximately from 200 grams to 2000 grams. Control System: 0.5 HP/230V/50Hz motor with variable frequency drive, adjustable digital RPM speed display, programmable timer, and safety features including input and output fuses. Operation: Planetary rotation principle with the jar rotating in a planetary orbit, offering a maximum speed of 300 to 600 RPM and continuous operation capability for up to 10 hours. Precision: Achieves final fineness of less than 100 nanometers, providing exceptional control and accuracy for a wide range of grinding applications. Conclusion:
VBCC's Planetary ball mills offer a powerful solution for pulverizing soft, hard, brittle, and fibrous materials in both dry and wet modes. Their versatility, coupled with the ability to customize jar and ball materials, makes them indispensable tools in research laboratories, particularly for mechanochemistry and ultrafine grinding applications. Careful consideration of material properties is essential for achieving optimal grinding efficiency and preventing contamination.
Please contact VB CERAMIC CONSULTANTS at vbceramic@yahoo.com or call us at
9444012468 to learn more. Elevate your research and production with VBCC's High energy Planetary ball mill.
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