More Stable Sand Removal with Multi-Pipe Structure, Multicyclone Adapted to Large-Scale Starch Production Lines

Large-scale cassava starch production lines are generally characterized by large processing capacity, large fluctuations in slurry concentration, and high requirements for continuous operation.

Common single-pipe hydrocyclones tend to suffer from reduced separation efficiency, unstable sand removal, and partial blockages under high-flow conditions, making it difficult to maintain stable performance throughout the day. Fluctuations in sand content of the slurry directly lead to inconsistent starch purity and increased equipment wear, failing to meet the high-yield, stable, and high-standard production needs of large factories, and becoming a key link restricting capacity release.

Multicyclone adopts a parallel design with multiple cyclone cores, specially optimized for large-flow and high-load starch production lines. It outperforms single-pipe hydrocyclones significantly in capacity, stability and separation effect.

With uniform flow distribution through multiple tubes, each cyclone works under optimal conditions, featuring higher fine sand removal rate, more stable operation, and stronger resistance to flow impact. It supports 24-hour continuous and stable operation, fully matching the production rhythm of large starch plants.

The whole unit is made of wear-resistant and corrosion-resistant materials with high structural strength, no wearing parts, and no manual cleaning required. It can deeply purify slurry, improve starch quality, and fully protect pumps, screens and grinding equipment, greatly reducing maintenance costs and downtime risks of large production lines.

1. Choose parallel multi-pipe Multicyclone for large processing capacity, suitable for large-scale starch production lines.
2. Pay attention to the uniform flow distribution structure to ensure stable operation and consistent sand removal effect of each cyclone.
3. Select models with high wear-resistant liners to adapt to long-term high-load and large-flow working conditions.
4. Choose the number of tubes and model according to actual processing flow to ensure separation efficiency matches capacity.
5. Prioritize modular, easy-to-install and easy-maintain models for convenient later inspection and capacity expansion.