Mechanical processing of rare-earth ore types typically requires very high-energy consuming steps such as grinding to liberate valuable minerals. In addition, occasionally harmful reagents are used in processes such as flotation to separate the contained minerals. Sensor-based sorting (SBS), a technology used for coarse particle separation (ca. +10–20 mm), can play a key role in reducing mass flows and increase valuable contents at an early stage of the process chain, with positive effects on the following processes. One sensor-technology used in SBS is dual-energy X-ray transmission (DE-XRT) sorting. The principle is known from luggage safety inspections at airports and has already been adapted to the sorting of numerous commodities in the raw materials sector, such as coal, gold ore and tungsten ores. The technical applicability of DE-XRT sorting is limited to ore types for which differences in the valuable/metal contents are detectable, based on an interpretation of recorded X-ray images. Since variations in ore characteristics such as mineralogy, valuable content, and grain sizes of valuable minerals are typical, each ore has to be tested individually for the technical applicability of DE-XRT sorting. In a fundamental research project, influences of specific parameters on the detectability of rare-earth minerals were investigated based on practical test works with artificial samples of defined, simplified composition, followed by an interpretation of recorded X-ray images. Influences such as rare-earth concentrations, grain sizes and spatial distribution of valuable minerals on the average X-ray attenuation were investigated. Limits and potentials of this fundamental approach are presented. Besides the above, the ability to simulate X-ray absorption characteristics, based on a Monte Carlo simulation approach was tested. X-ray absorption features of defined particle compositions were calculated, and virtual X-ray images were produced. Results of both measurement approaches were compared to assess the general technical feasibility of the computer-based simulation.
[1]
Hermann Wotruba,et al.
Anwendung der sensorgestützten Sortierung für die Aufbereitung mineralischer Rohstoffe
,
2014
.
[2]
Hermann Wotruba,et al.
Recent developments in dry coal sorting with X-Ray transmission
,
2012
.
[3]
Christopher Kleine.
New Developments in Sensor-Based Sorting for Minerals
,
2016
.
[4]
Adam Jordens,et al.
A review of the beneficiation of rare earth element bearing minerals
,
2013
.
[5]
Hermann Wotruba,et al.
Sorting of disseminted sulphide ore by X-ray transmission and electromagnetic sensors
,
2006
.
[6]
Hermann Wotruba,et al.
Sensor-based sorting of metal ores
,
2013
.
[7]
Hermann Wotruba,et al.
Sensor‐Based Sorting
,
2010
.
[8]
Manuel Warcholik,et al.
Principles of X-ray transmission
,
2014
.
[9]
N. Krishnamurthy,et al.
Extractive metallurgy of rare earths
,
2004
.
[10]
H. Wotruba,et al.
Sensor-based sorting of metalliferous ores - an overview
,
2006
.
[11]
Hermann Wotruba,et al.
Viable Applications of Sensor-Based Sorting for the Processing of Mineral Resources†
,
2014
.