Product Description
Battery Material Grinders: Low-Metallic Contamination for Li-ion
Production
In the rapidly evolving landscape of lithium-ion battery
production, the quality and efficiency of battery materials are
paramount. As the demand for high-performance batteries surges,
driven by advancements in electric vehicles and portable
electronics, manufacturers are increasingly focusing on optimizing
their processes. One critical aspect of this optimization is the
use of advanced battery material grinders that ensure low-metallic
contamination, thereby enhancing the performance and safety of
lithium-ion batteries.
Lithium-ion batteries are composed of several key components: the
anode, cathode, and separator membrane. The quality of these
components significantly influences the battery's performance,
safety, and longevity. Low-metallic contamination in battery
materials is crucial because metallic impurities can lead to short
circuits, reduced battery life, and even safety hazards like
thermal runaway.
Precision Grinding: Advanced grinders offer precise control over particle size
distribution, ensuring uniformity in the battery materials. This
uniformity is critical for the consistent performance of
lithium-ion batteries.
Low-Metallic Contamination: Utilizing materials and technologies that minimize metallic
contamination is essential.
Efficiency and Scalability: Modern grinding solutions are designed to be efficient and
scalable, accommodating the growing demands of the lithium-ion
battery market.
Nanoparticle Processing: The ability to process nanoparticles is a significant advantage,
as it enhances the performance of electrode active materials. This
capability is crucial for producing high-performance lithium-ion
batteries.
The latest advancements in grinding technology offer comprehensive
solutions for lithium-ion battery production. Companies are
integrating automated systems for feeding, premixing, dispersion,
and intelligent batching. These systems not only improve efficiency
but also ensure the digital, standardized, and intelligent
management of production processes.
Wet grinding is a critical process in the preparation of battery
slurries. It involves mixing binders, active materials, and
additives to create a homogeneous slurry. The quality of this
slurry directly impacts the performance of the battery.
Physical Parameters
Technical Parameters of 304 Stainless Steel Mill Balls |
Items | Data |
Tensile Strength | 100,000-180,000 psi |
Yield Strength | 50,000-150,000 psi |
Tensibility | 55%-60% |
Modulus of Elasticity | 29,000,000 psi |
Chemical Composition Content of 304 Stainless Steel Mill Balls |
Chemical Element | Percentage of Content (%) |
Fe | 67.4-70.6 |
C | 0.1 |
Si | 1 |
Mn | 2 |
P | 0.045 |
Features
1. Anti-erosion and corrosion resistance.
2. No magnetic and demagnetization character, HRC≤26.
3. It applies to grinding of various materials.
4. Good shape of ball with Smooth and gloss surface.
5. Its one of the most Cost- effective ball mill media.
Factory equipment
Exhibition & Partner
Case
Ship to Poland
Ship to France
FAQ
1. What are stainless steel mill balls?
Stainless steel mill balls are spherical components made from
stainless steel, used primarily in grinding, milling, and mixing
applications. They are known for their durability, corrosion
resistance, and ability to withstand high-stress environments.
2. What materials are stainless steel mill balls made from?
Common materials include:
304 Stainless Steel: General-purpose, corrosion-resistant.
316 Stainless Steel: Higher corrosion resistance, ideal for harsh
environments.
420 Stainless Steel: Harder and more wear-resistant.
440C Stainless Steel: High hardness and wear resistance, suitable
for heavy-duty applications.
3. What are the primary uses of stainless steel mill balls?
Grinding and milling media in industries like mining, chemicals,
and pharmaceuticals.
Mixing and dispersing in paint, ink, and food production.
Precision components in bearings, valves, and pumps.
Decorative or functional elements in furniture and art.
