Calculation of Evaluation Variables for High Gradient Magnetic Separation with an Idealized Capture Model

This paper regards feed mine as a mixture of intergrowths and pure non-magnetic mineral particles, presents a method to calculate the evaluation variables such as grade and recovery in high gradient magnetic separation (HGMS). A idealized capture model is constructed in which the interaction between particles is not taken into account and only for the initial aggregation condition that the separator has the highest capture efficiency. In the model we adopt the functions that use nominal particle radius and magnetic mineral content as independent variables to describe volume fraction distribution and capture efficiency of intergrowths respectively. Through adding multi-wire magnetic fields and setting periodic boundary conditions in flow field analysis, we modify the computational domain of the single-wire capture theory to a element domain that periodically appears in the multi-wire matrix. By means of finite element software, particle trajectories, flow field and magnetic field are clearly exhibited, and then capture efficiency function is obtained by interpolation method. The calculated evaluation variables theoretically represent the best performance of magnetic separator for a given feed. They can assist mineral engineers to evaluate or compare the effects of different magnetic separation systems in advance. We use removal of iron impurity from kaolin as an example to illustrate the presented calculation method. The results quantitatively compare the evaluation variables of the separation at different magnetic fields and show that the advantage of higher magnetic field in separation efficiency decreases with the increase of saturation magnetization of magnetic mineral.