This refers to a high-efficiency, compact laboratory planetary ball mill characterized by its unique semi-circular (or arc-shaped) grinding jar design. It is engineered to be a small and fast machine capable of achieving nano-scale fineness for a wide range of sample materials.
Technical Specifications
| Model No. |
ZLXQM-0.4
|
| Volume of each matched Jar |
100ml
|
| Voltage |
220V - 50Hz
|
| Machine Size |
500*300*340mm
|
| Machine Weight |
100 Kg without mill jar
|
| Work mode |
4 jars working together
|
| Mill mode |
Dry / wet milling
|
| Speed Frequency |
Adjusting
|
| Drive Mode |
Gear drive
|
| Rotational Speed |
90-870 r/min, adjusting
|
| revolution: rotation |
1:2.14
|
| Material Capacity |
Material + mill balls < 2/3 volume
|
| Input Granularity Size |
< 10mm for soft material,
< 3mm for hard material
|
| Output Granularity Size |
Minimum 0.1μm
|
| Field of application |
Geology, Mining, Metallurgy, Electronics, Construction Material, Ceramics, Chemical Engineering, Light
Industry Medicine, Environmental Protection etc.
|
| Feed material |
Soft, hard, brittle, fibrous, cellulose, herb, glass, soil,ore, pharmacy, chemical, fluorescent, pigment etc.
|
| Type of grinding jars |
Stainless steel, zirconia, alumina, nylon, PU, tungsten,PTFE etc., vacuum jars are available as well.
|
| Type of grinding medium |
Stainless steel balls, zirconia balls, alumina balls, PU balls, steel carbon balls, tungsten balls, etc.
|
| Max. continuous operating time (full-load) |
72 hours
|
| Interval operation |
With direction reversal
|
| Certificate |
ISO 9001. CE certificate
|
1. Core Innovation: The Semi-Circular Grinding Jar
The most distinctive feature of this mill is the shape of its grinding jar. Unlike traditional cylindrical jars, the jar is designed in a semi-circle or arc.
Enhanced Grinding Efficiency:
This shape creates a more dynamic and chaotic grinding ball movement. The absence of a flat end wall reduces "dead zones" where material can remain stationary. The balls are constantly being redirected, leading to more impacts and friction in a shorter time.
Improved Energy Transfer:
The geometry allows for a more efficient transfer of the planetary motion's kinetic energy to the grinding balls, contributing to the "fast" grinding performance.
Optimal Volume Utilization:
The design often allows for better utilization of the jar's volume, ensuring the entire sample is actively engaged in the grinding process.
2. Key Characteristics
A) Nano-Scale Laboratory Planetary Grinding Machine
Principle: Achieves nano-particles through the high-energy impact and friction generated by the planetary motion. The semi-circular jar enhances this by ensuring more consistent and thorough processing of the entire sample batch.
Critical Factors:
Grinding Media: Uses very small (e.g., 0.1mm - 3mm) grinding balls made of high-density materials like Yttria-Stabilized Zirconia (YSZ) to maximize the number of contact points.
Wet Grinding Capability: For true nano-dispersion, wet grinding is essential. The semi-circular jar is equally effective with liquid solvents, preventing particle re-agglomeration.
Speed Control: Precise digital control over RPM is vital to provide the exact energy needed to break down particles to the nanoscale without degrading the sample.
B) Small and Fast Ball Mill
Small:
Compact Design: The machine itself has a small benchtop footprint, saving valuable lab space.
Small Batch Size: It is designed for small sample quantities, typically in jars with volumes from 50 ml to 250 ml. This is ideal for research and development where materials are precious or expensive.
Fast:
High Efficiency: The combined effect of the planetary movement and the optimized semi-circular jar geometry leads to significantly shorter processing times compared to conventional ball mills to achieve the same fineness.
High-Speed Operation: These mills are capable of operating at very high relative centrifugal forces, rapidly imparting energy to the sample.
3. Technical Workflow
Sample Loading: A small quantity of the sample (and a grinding liquid for wet milling) is placed into the semi-circular jar along with the appropriate grinding balls.
Parameter Setting: The user sets the rotational speed (RPM) and the grinding time on the digital controller. For sensitive materials, a program with intermittent pauses can be set to prevent overheating.
High-Energy Milling: The jar is secured on the rotating planetary disk. The dual rotation begins, creating intense centrifugal forces that accelerate the grinding balls.
Nano-Pulverization: The balls impact and shear the sample particles against the curved walls of the jar, reducing their size through repeated collisions.
Result: After the programmed time, the mill stops. The result is an ultra-fine, homogeneous powder or nano-suspension ready for analysis.
4. Advantages Summary
Superior Grinding Efficiency: The semi-circular jar design minimizes dead zones and maximizes energy transfer, leading to faster and more uniform grinding.
Rapid Processing: Achieves desired fineness in a shorter time compared to traditional mills, boosting laboratory productivity.
Exceptional Fineness: Capable of reducing particle size down to the nanometer range (<100 nm).
Minimal Sample Requirement: Ideal for R&D with scarce, expensive, or unique materials.
Versatility: Suitable for dry grinding (for brittle materials) and wet grinding (for nano-dispersion and ductile materials).
5. Typical Applications
This type of mill is perfect for advanced applications where speed, efficiency, and ultimate fineness are critical:
Materials Science: Preparation of nano-powders, graphene dispersion, mechanical alloying.
Pharmaceuticals: Nano-sizing of active pharmaceutical ingredients (APIs) to enhance solubility and bioavailability.
Electronics: Grinding of electronic ceramics, phosphors, and battery materials (cathodes/anodes).
Geology: Ultra-fine pulverization of geological samples for highly sensitive analysis (e.g., ICP-MS).
Chemistry: Mechanochemical synthesis and catalyst preparation.
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