Enhancing Particle Breakage and Energy Utilization in Ball Mills: An Integrated DEM and SPH Approach

Enhancing Particle Breakage and Energy Utilization in Ball Mills: An Integrated DEM and SPH Approach

Blog Article

This study examines the conversion of an overflow ball mill into a new discharge system via Discrete Element Method (DEM) and Smoothed Particle Hydrodynamics (SPH) simulations, demonstrating significant performance improvements.The methodology integrates SPH to assess the effects of the slurry on energy dissipation, power loss, breakage rates, and material transport.The findings highlight significant operational inefficiencies in the overflow setup, extensive dead zones, and excessive charge volume that hinder milling efficiency by limiting grinding media interaction with the ore and reducing energy for comminution.Additionally, slurry pooling shifts emtek 2113 the center of gravity, causing torque losses and direct material bypass to the discharge zone.Our simulations replicate these challenges and benchmark them against industrial-scale operations, identifying critical charge excesses that constrain throughput and elevate power consumption.

The new proposed discharge system decouples the filling charge from the evacuation mechanism, releasing the effective volume in the mill, in addition to tackling common issues in the traditional grate discharge setups like backflow and carry-over.This arrangement substantially improved grinding efficiency, as demonstrated by enhanced breakage rates and diminished specific energy consumption.The results provide read more a robust framework for mill design and operational optimization, underscoring the value of integrated slurry behavior analysis in mill performance enhancement.