Abstract
The depletion of ore deposits, the increasing demand for raw materials, the need to process low-grade, complex and finely disseminated ores, and the reprocessing of tailings are challenges especially for froth flotation separation technologies. Even though they are capable of handling relatively fine grain sizes, the flotation separation of very fine and ultrafine particles faces many problems still. Further, the flotation of low-contrast semi-soluble salt-type minerals with very similar surface properties, many complex interactions between minerals, reagents and dissolved species often result in poor selectivity. This study investigates the flotation beneficiation of ultrafine magnesite rich in dolomite from desliming, currently reported to the tailings. The paper especially focuses on the impact of the depressant sodium hexametaphosphate (SHMP) on the following: (i) the froth properties using dynamic froth analysis (DFA), (ii) the separation between magnesite and dolomite/calcite, and (iii) its effect on the entrainment. As a depressant/dispersant, SHMP has a beneficial impact on the flotation separation between magnesite and dolomite. However, there is a trade-off between grade and recovery, and as well as the dewatering process which needs to be considered. When the SHMP increases from 200 g/t to 700 g/t, the magnesite grade increases from 67% to 77%, while recovery decreases massively, from 80% to 40%. The open circuit with four cleaning stages obtained a concentrate assaying 77.5% magnesite at a recovery of 45.5%. The dolomite content in the concentrate is about 20%, where 80% of dolomite was removed and importantly 98% of the quartz was removed, with only 0.3% of the quartz in the final concentrate. Furthermore, the application of 1-hydroxyethylene-1,1-diphosphonic acid (HEDP) as a more environmentally friendly and low-cost alternative to SHMP is presented and discussed. Using only 350 g/t of HEDP can achieve a similar grade (76.3%), like 700 g/t of SHMP (76.9%), while obtaining a 17% higher magnesite recovery as compared to 700 g/t of SHMP. Interestingly, the proportion of hydrophilic quartz minerals ending up in the concentrate is lower for HEDP, with only 1.9% quartz at a recovery of 21.5% compared to the 2.7% of quartz at a recovery of 24.9% when using SHMP. The paper contributes in general to understanding the complexity of the depressant responses in froth flotation.
Highlights
IntroductionDecreasing ore grades and the ever-increasing demand for raw materials by a more sustainable means requires exploration and the processing of low-grade and complex ores with a fine-grained composition, the reprocessing of tailings and the beneficiation of fine-grained particles in the processing plants
HEDP as a depressant in single-phase minerals displayed a very selective depression in dolomite due to the HEDP strongly adsorbing onto the dolomite with a higher calcium site density [14], whereas it had only slightly shown to depress magnesite. This present study investigates the effect of sodium hexametaphosphate (SHMP) on the flotation separation of ultrafine magnesite rich in dolomite from desliming tailings in the lab batch scale
Ultrafine hydrophilic quartz is another issue affecting the entrainment in the case of the direct flotation of magnesite
Summary
Decreasing ore grades and the ever-increasing demand for raw materials by a more sustainable means requires exploration and the processing of low-grade and complex ores with a fine-grained composition, the reprocessing of tailings and the beneficiation of fine-grained particles in the processing plants. The flotation of semi-soluble salt-type minerals, which contain a significant amount of CO3 −2 along with Mg2+ /Ca2+ ions [2,3,4], is generally challenging. These dissolved ions and in consequence their solution species will interact with various minerals changing their surface properties, which interferes with the added reagents, affecting the collector–
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