Insufficient Fine Sand Removal Rate, Multicyclone Multi-Stage Separation Improves Starch Purity

In cassava starch processing, common single-stage cyclones often suffer from low fine sand removal rate and difficulty in separating tiny silt, resulting in incomplete slurry purification.

Residual fine sand directly leads to high ash content, insufficient whiteness and rough taste of starch, which cannot meet the high standards of food, modified starch, pharmaceutical and other high-end applications. At the same time, tiny hard particles continuously abrade equipment and affect production line stability. For starch enterprises pursuing high purity and high added value, improving fine sand removal efficiency is the key to quality upgrading.

Multicyclone adopts multi-stage centrifugal separation and multi-pipe parallel structure, specially designed for high-demand starch purification scenarios, which can significantly increase fine sand removal rate and achieve deep purification.

Through simultaneous operation of multiple cyclone units, the fluid distribution is more uniform and centrifugal separation is more sufficient. Its removal effect on fine sand, sludge and other heavy impurities is far better than ordinary single-stage equipment. The multi-stage separation design further reduces sand content in slurry, improves starch purity at the source, and makes whiteness, purity and ash content fully meet standards.

The whole unit runs continuously and stably, with no filter screen, no clogging and no manual cleaning, supporting 24-hour operation for large-scale production lines. Made of wear-resistant lining materials, it features long service life and low maintenance cost. While improving starch quality, it effectively protects downstream equipment and achieves dual benefits of quality improvement and cost reduction.

1. Choose multi-stage separation structure Multicyclone for higher fine sand removal rate and more stable purification.
2. Focus on uniform multi-pipe flow distribution design to ensure separation efficiency does not decline under large flow.
3. Select high wear-resistant lining materials to adapt to long-term high-load continuous operation.
4. Match the number of cyclone pipes according to processing capacity to ensure both output and separation effect.
5. Prioritize modular structure for easy installation, maintenance and future capacity expansion.