- Article
Capture Radius of Rod-Shaped Matrix: Characteristics and Influencing Factors in Low-Intensity Gradient Magnetic Fields
- Hongliang Shang,
- Tiange Wang and
- Guoping Li
- + 1 author
In magnetic separation processes, the capture radius Rc of magnetic particles achieved by the magnetic matrix constitutes a critical parameter governing the separation efficiency and operational performance of magnetic separation equipment. Through a systematic study of the characteristics of Rc and the factors influencing it, the application capability of separation systems can be notably improved. To address the lack of systematic research on Rc under low magnetic field intensities (<0.6 T), a key gap compared to conventional high gradient magnetic separation (HGMS) operating at ≥0.6 T, the motion trajectories of magnetic particles adjacent to a rod-shaped matrix, as well as their final capture or repulsion behaviors, were observed via a high-speed camera. Concurrently, these processes were accurately reproduced using the finite element method (FEM). This study innovatively integrates experimental validation and FEM simulation, achieving mutual verification that single-method studies cannot provide. Based on the experimentally validated FEM model, the effects of magnetic field intensity H, rod-shaped matrix diameter Φ, magnetic particle diameter d, and fluid viscosity η on the motion of magnetic particles were methodically investigated. The velocity characteristics of particles at critical positions between the capture and repulsion zones were analyzed to determine the capture radius of the rod-shaped matrix under specified conditions. Drawing on the identified parametric effects, the developed capture radius prediction model fills the research gap in low-intensity HGMS and serves as a theoretical reference for optimizing both the spacing design of industrial-scale rod-shaped matrix arrays and their matching with relevant operating parameters, and the development of energy-efficient magnetic separation equipment.
21 January 2026


![(a) Schematic of the experimental setup. (b) When a current of 9.53 A is input into the Helmholtz coil, a magnetic field is generated. The generated magnetic field has a relatively uniform region, which is defined by x, y, z ∈ [−20 mm, +20 mm]. (c) Mass magnetization curves of the rod-shaped matrix and spherical particles.](https://mdpi-res.com/minerals/minerals-16-00109/article_deploy/html/images/minerals-16-00109-ag-550.jpg)

