Preventing coarse particle contamination: Technical guarantee of Nano Calcium Deagglomeration Machine

During the production process, nano calcium is prone to agglomeration due to its small primary particle size and high surface energy. If the agglomerates are not completely dispersed during the deagglomeration process, larger particles may be formed. These coarse particles often cannot be further deagglomerated, thus contaminating the final product. These coarse particles not only affect the dispersibility of the material, but may also have a serious impact on the application performance, especially in the demanding fields such as coatings, plastics, and rubber. The presence of coarse particles will cause fluctuations in material performance and even fail to meet industry standards.

Therefore, preventing coarse particle contamination is the key to ensuring the high performance of nano calcium. Nano Calcium Deagglomeration Machine avoids the generation of coarse particles and improves the stability and consistency of the material by precisely controlling the deagglomeration process.

Nano Calcium Deagglomeration Machine's technology to prevent coarse particle contamination
Nano Calcium Deagglomeration Machine has many advantages in design and technology, which can effectively prevent coarse particle contamination and ensure the high purity and dispersibility of nano calcium particles. The following are its core technologies and anti-pollution methods.

1. Precise particle size control
To prevent coarse particle contamination during the deagglomeration process, the Nano Calcium Deagglomeration Machine is equipped with a precise particle size control system. The system monitors the size, distribution and morphology of the particles in real time to ensure that the particles do not exceed the preset size range during the deagglomeration process

2. Efficient shear force dispersion technology
Efficient shear force dispersion technology is one of the core technologies of the Nano Calcium Deagglomeration Machine. This technology breaks the attraction between nano calcium particles by applying high-intensity shear force during the deagglomeration process and effectively disperses them into individual particles. Compared with traditional deagglomeration methods, efficient shear force can more accurately control the dispersion state of particles, ensuring that the particles will not become too small due to excessive shearing, nor will large agglomerated particles remain due to insufficient shearing

3. Optimized fluid dynamics design
Nano Calcium Deagglomeration Machine also adopts an optimized fluid dynamics design to further improve the efficiency of particle dispersion through the movement of fluids. In the deagglomeration chamber, the nano calcium particles are subjected to uniform fluid dynamics to ensure that the particles will not form new coarse particles due to collision or adhesion during high-speed movement.

4. Closed deagglomeration environment
In order to further prevent the external environment from interfering with the deagglomeration process, the Nano Calcium Deagglomeration Machine adopts a closed deagglomeration environment design. The deagglomeration chamber is well sealed, effectively preventing external pollutants from entering the deagglomeration process. At the same time, the equipment is made of highly wear-resistant materials, which can prevent particle contamination caused by mechanical wear inside the equipment.

5. Intelligent operation and process control
The intelligent operating system of the Nano Calcium Deagglomeration Machine provides a guarantee for preventing coarse particle contamination. Through advanced algorithms and automatic control, the equipment can adjust the deagglomeration force, speed and other parameters in real time to ensure the stability of particle size. The system can automatically identify and optimize the operating conditions during the deagglomeration process according to the characteristics of different batches of nano calcium particles to avoid unstable or uneven particle size.