versión On-line ISSN 2411-9717
versión impresa ISSN 0038-223X
J. S. Afr. Inst. Min. Metall. vol.114 no.4 Johannesburg abr. 2014
S.J. BaumgartnerI; D.R. GrootII
IPalabora Copper Ltd, South Africa
IIDepartment of Materials Science and Metallurgical Engineering, University of Pretoria, Pretoria, South Africa
The ferromanganese industry is under pressure to deal with the slag arising from the production of ferromanganese, which is discarded in landfills or slag heaps. This material poses an environmental and health risk to surrounding ecosystems and communities, and disposal costs are increasing. Ferromanganese slag contains an appreciable amount of residual manganese metal, which can be exploited. Previous work has shown that the slag can be leached fully, while rejecting the silica to a residue. The methods that were investigated to recover manganese from the leach solution included hydroxide precipitation to upgrade the leach solution followed by manganese carbonate precipitation to produce a pure manganese carbonate product or a manganese carbonate furnace feed material, which would be recycled to increase manganese recoveries in the production of ferromanganese. In addition, electrowinning of electrolytic manganese dioxide from the leach solution was studied. The methods were compared in terms of selectivity, costs, and product quality. Co-recovery of the leach residue, which is a potential cement additive, is discussed.
Among the methods investigated to upgrade the pregnant leach solution, hydroxide precipitation utilizing ammonia to adjust the pH appears to be the most effective in removing major impurities such as iron, aluminium, and silica to less than 1 ppm. The manganese carbonate and impure manganese carbonate furnace feed products met quality specifications. However, although the production of these materials was technically viable, the large amounts of base reagent that were required to raise the pH, and the associated high operating costs, rendered the process uneconomic.
An optimization study was therefore carried out with the primary objective to determine the ideal acid amount to be utilized in the water-starved digestion stage, thereby decreasing acid and base consumption while optimizing the quality of the pregnant leach solution, and producing a leach residue that contained <1% Mn. The outcome was an economically viable process. Additional benefits included an increase in the manganese content of the impure manganese carbonate furnace feed material, and a substantial reduction in the dilution of the pregnant leach solution, thereby maintaining high manganese concentrations that rendered the solution viable for electrowinning of electrolytic manganese dioxide, the production of which yielded a current efficiency of 74%.
Keywords: environment, ferromanganese slag, manganese products, water-starved digestion, precipitation.
A high manganese recovery is vital in rendering the ferromanganese production process economically viable. It is particularly crucial in recovering manganese products from secondary sources such as ferromanganese slag. This industrial waste material contains an appreciable amount of residual manganese that can be economically exploited. Ferromanganese slag is a waste product from the production of ferromanganese metal in blast furnaces and submerged arc furnaces. There is an estimated 53 Mt of slag dumped in South Africa (Parker and Loveday, 2006). Discarding the slag not only entails disposal costs, but also poses an environmental and health threat, mainly due to the leaching of mobile manganese in the slag.
The slag can be fed back into the furnace. This option, however, is not favoured due to the build-up of alkali metals and zinc in the smelting process. The slag can also be crushed and ground to produce cement aggregate or slag cement. The disadvantage to this, however, is that there is a danger that manganese can leach out, and only freshly tapped slag can be utilized. A hydrometallurgical route that can be adopted to recycle both the discarded and freshly tapped slag would be advantageous. The slag would be subjected to a water-starved digestion and leached to produce a pregnant leach solution from which manganese could be recovered using various methods, including precipitation and electrowinning, and a residue that can be sold as an additive for Portland cement.
The research focus was therefore aimed at developing economically and technically viable processes to produce a pregnant leach solution with a high manganese content and low impurity concentration. The pregnant leach solution could be utilized to produce saleable products that meet the quality requirements, or products containing manganese in a low oxidation state that could be fed back into the ferromanganese production process as a sweetener, thus circumventing the environmental and health impacts of processing ferromanganese slag. In addition, a saleable byproduct such as a cement additive would be produced.
Leaching of ferromanganese slag
Various authors have undertaken prior investigations into the leaching of ferromanganese slag. The leaching processes discussed include ferric chloride in the presence of sucrose, carbamate leaching, and the quick leach (also known as the water starved digestion method) with concentrated sulphuric acid (98-99%).
Naganoor et al. (2000) used the ferric chloride route to leach slag. It was deduced that roasting prior to leaching was essential to ensure that the manganese was converted into a soluble form. A manganese recovery of 82% was achieved in 2 hours at a temperature of 80°C. The oxidation of sucrose, however, increased the rate of leaching, yielding an 86% recovery in 1 hour. The pregnant leach solution can be further treated to produce electrolytic manganese dioxide (EMD) and electrolytic manganese metal (EMM). Mcintosh and Baglin (1992) investigated the feasibility of using ammonium carbamate as a reagent to recover manganese from slag. A recovery of 99% was achieved in 3 hours at a temperature of 65°C. The manganese carbamate can be added as a sweetener in the steelmaking industry or can be further purified.
The slag that was used to produce the pregnant leach solution in previous investigations was first crushed and milled, then premixed with deionized water followed by water starving (digesting) the slurry in concentrated sulphuric acid (98%) (Groot et al., 2013). A solidified cake was produced, which was left to age for 24 hours; this resulted in an increase in manganese recovery. Thereafter, the cake was water-leached in a 1-3 stage water leach, recovering between 75-95% of the manganese into solution. These results, however, were dependent on the number of leaching stages.
Recovery of manganese as manganese carbonate
Zhang et al. (2010) investigated carbonate precipitation of manganese from a pregnant leach solution at 60°C using sodium carbonate (Na2CO3) at different pH values. The experiments were conducted under ambient conditions, but with slow agitation to reduce oxidation by air. It was observed that at pH>7.5 a 90% manganese recovery was obtained with co-precipitation of calcium and magnesium at recoveries of 43% and 13%, respectively. At pH>8.5, 99.5% of the manganese was recovered, with co-precipitation of 97% of the calcium. According to Zhang et al. (2010) the precipitation of manganese carbonate is thermodynamically favoured over magnesium carbonate and (but to a lesser degree) calcium carbonate. This is attributed to the smaller log K(Ca/Mn) value measured in comparison to the theoretical K value. This is an important consideration when attempting to recover manganese carbonate that meets specifications from a solution that contains high magnesium and low calcium concentrations. The results obtained by Zhang et al. suggested that the recovery of manganese via a carbonate precipitation yielded a good quality product. This, however, was dependent on the manganese to magnesium ratio.
An alternative process to produce manganese carbonate (MnCO3) from a manganese solution was developed by INCO for the recovery of metal values from ocean-floor nodules in the presence of 3-8% NH3 and 1-6% CO2. The reagent acts both as a lixiviant and as a precipitant for manganese as MnCO3, which is recovered in the residue; nickel, cobalt, and copper are solubilized as stable ammines (Illis and Brandt, 1975; Zhang and Cheng., 2007). Kono et al. (1986) conducted similar studies into the recovery of manganese from nodules using a sulphurous acid leach, with precipitation of manganese as MnCO3 in the presence of (NH4)2CO3 while copper, nickel, and cobalt remained in the solution as ammine complexes.
Production of electrolytic manganese dioxide (EMD)
Electrolytic manganese dioxide (EMD) is a vital ingredient in Leclanche-type dry cells. Owing to modern advances in the electronics industry, which have necessitated a greater capacity for manganese dioxide production, natural manganese dioxide (NMD) has been replaced by electrolytic manganese dioxide (EMD) (Rethinaraj and Visvanathan, 1993).
The half-cell reactions are given below:
The current efficiency at the anode is affected by the following parasitic reactions (Te Riele, 1983): The evolution of oxygen:
The oxidation of Mn2+ to Mn3+, which diffuses into the electrolyte solution:
Mn3+ is an unstable ion that disproportionates to produce Mn2+ and MnO2, which forms sludge:
An additional parasitic reaction that can occur if there is an appreciable amount of iron in solution, and which is responsible for decreasing current efficiencies and contaminating the final EMD product, is given by:
Table I shows the effect that different concentrations of iron in solution have on the final product (Te Riele, 1983).
There are several factors that affect the quality of EMD produced, one of which is the acid concentration of the electrolyte. A high acid concentration (>50 g H2SO4 per litre) has a detrimental effect on the amount of battery-active EMD plated. In addition, the morphology is affected, resulting in a less compact deposit, and current efficiency is decreased by the formation of Mn3+ which is promoted by the higher acid concentration (Te Riele, 1983). Temperature is another critical factor. A temperature above 90°C results in a desirable current efficiency, which ranges between 90-97%, provided the system is operated at 100 A/m2 (Te Riele, 1983; Rethinaraj and Visvanathan, 1992). At lower temperatures, however, the current efficiency will be variable depending on the type of materials utilized for the electrodes, and the cell voltage will increase, thereby increasing energy consumption. In addition, lower temperatures result in shorter discharge times on the EMD battery cell (Te Riele, 1983).
The flow diagram in Figure 1 summarizes the experimental routes that were investigated to determine the most technically and economically viable methods of producing various manganese products.
Materials and methods
A South African ferromanganese producer in KwaZulu-Natal supplied the ferromanganese slag utilized in previous investigations. The chemical and phase compositions of the slag were determined using X-ray fluorescence spectrometry (XRF) and X-ray diffraction spectrometry (XRD), which were performed by Scrooby's Laboratory Service and the Department of Geology at the University of Pretoria.
Chemical composition of the ferromanganese slag
The typical composition of the slag, determined by XRF analysis, is given in Table II.
The major elements were manganese, silicon, and calcium. The iron content was low, which was ideal as iron results in difficulties in the downstream purification stages. The major phases present in the material included glaucochroite, manganosite, and gehlenite as shown in Table III.
The manganese content of the slag (approx. 30%) was sufficient for the investigation to proceed further.
All reagents were of analytical grade, and supplied by Merck Millipore, and distilled water was used throughout. All glass and metal ware was decontaminated with detergent and rinsed thoroughly with distilled water.
The work was performed on 100 g ferromanganese slag samples that had been pre-crushed to 45 mm. The material was further reduced in size using a gyratory crusher, then milled to a cut size of 600 µm utilizing ball milling, and dry-screened.
Purification of the manganese pregnant leach solution
The objective of the purification stage was to obtain a pregnant leach solution (PLS) that contained high manganese and low impurities concentrations, from which manganese products that meet the quality specifications could be produced.
The reagents used to increase the pH for impurity removal included sodium hydroxide (NaOH) or ammonia (NH3), which were employed in separate purification investigations. The oxidant was hydrogen peroxide (34% H2O2), to oxidize Fe2+ to Fe3+ so that iron was precipitated within a pH window of 3-5.5.
A PLS sample size of 100 ml was used throughout experimental runs. Before base reagent was added, 34% H2O2 was added dropwise until the solution turned from pink to a mustard colour. For purification using NaOH, 24 g of NaOH pellets were weighed, and dissolved in 200 ml distilled water to obtain a solution of 120 g/l of NaOH, which was added dropwise to the solution to increase the pH from less than 0 to approximately 5.6. The solution was kept at room temperature and continuously stirred.
A similar procedure was followed for the experiments that involved the upgrading of the PLS using 25% ammonia solution, which was added dropwise to increase the pH to approximately 5.6.
The upgraded PLS was analysed for major elements by inductively coupled plasma - optical emission spectrometry (ICP-OES).
Production of manganese products
Precipitation of manganese carbonate
A 100 ml sample of PLS was used for the investigations utilizing Na2CO3 or (NH4)2CO3 as base reagents. The Na2CO3, at 150 g/l, was added dropwise to the PLS; the (NH4)2CO3 was added to the PLS in its solid form. Approximately 15 g of (NH4)2CO3 was added to adjust the pH from approximately 5.5 to 8.5, the pH range in which >99% of the manganese was recovered. The system was open to the atmosphere, and the procedure was conducted at room temperature (approx. 25°C) while the solution was agitated. Once precipitation was complete, the product was filtered, washed with distilled water, and dried at 30°C.
The manganese and impurities contents of the barren solution obtained after precipitation were determined by ICP-OES. The precipitate was analysed using XRF and XRD.
Production of a furnace feed material (impure MnCO3)
The apparatus and reagents used to produce the furnace feed material were the same as for the purification of the PLS and the pure MnCO3 product, except no filtration step was included. The product was dried in an oven at 30°C.
Electrowinning of electrolytic manganese dioxide (EMD)
The electrodes were graphite rods with a diameter of 7.5 mm. A current density of 100 A/m2 was adopted, with a plating time of 72 hours to allow a deposit thickness of approximately 2.4 mm, which would produce a mass of EMD >3 g, and a temperature of 90°C. The electrolyte volume was 1.1 litres.
The set-up of the electrowinning experiment for the production of EMD is shown in Figure 2.
The EMD was analysed for gamma and alpha manganese dioxide (MnO2) by XRD, and an elemental analysis was carried out by XRF. The manganese content of the solution after electrowinning was analysed using ICP-OES.
Results and discussion
Pregnant leach solution and residue
To produce the pregnant leach solution and residue the milled slag material was subjected to a water starved digestion and thereafter water-leached for two hours. Table IV shows a mass balance giving the general recoveries of manganese and impurity elements to the PLS and residue respectively. The mass balance was based on a 200 g slag sample.
The discrepancies in the percentage recovery of elements were probably due to the inhomogeneity of the ferromanganese slag sample. It was assumed that the chemical composition of the slag was as given in Table IV.
Purification of the pregnant leach solution (PLS)
It was essential to obtain a purified PLS in order to produce MnCO3 and EMD that adhered to the chemical specifications. The PLS had to contain >25 g/l Mn for the production of MnCO3, and 27-66 g/l Mn for the production of EMD (Te Riele, 1983). In addition, the PLS should adhere to the specifications in Table V.
During the addition of the base reagent, oxygen was bubbled through the solution at 60°C to oxidize iron from the Fe2+ to the Fe3+ state, thus allowing iron to precipitate as a hydroxide below a pH of approximately 5.6. However, this was ineffective due to the slow kinetics of dissolution of oxygen in the leach solution, and was further hindered by the solution pH < 3 (Zhang and Cheng, 2007). The oxygen was replaced with hydrogen peroxide, which was effective in oxidizing iron to the ferric state; therefore, all test work was carried out using hydrogen peroxide as the oxidant at room temperature where applicable.
A window of optimal precipitation of the major impurities, including Fe, Al, and Si, lay in a pH range of 2.5 and 5.6-6. Complete precipitation of impurities occurred between pH 5.5-6. From the results in Table VI, both NaOH and NH3 were effective reagents in removing impurities from solution. However, NH3 appeared to be the more effective, resulting in a purified PLS with Fe, Al, and Si contents of less than 1 ppm, in contrast to NaOH where the solution contained 604 ppm Fe, 8 ppm Si, and 140 ppm Al after precipitation.
Precipitation of manganese carbonate
Manganese precipitated from the purified PLS at pH >6, and manganese recovery reached 99.8% and 98.9% using (NH4)2CO3 and Na2CO3, respectively, at a pH >8.5. The results of the ICP-OES analyses before and after carbonate precipitation are given in Table VII. The results agreed with those obtained by Zhang et al. (2010), who achieved a manganese recovery of >99.5% pH >8.5.
The results in Table VIII indicate that using either (NH4)2CO3 or Na2CO3 as the precipitating reagent resulted in a MnCO3 product that meets the quality specifications, with the exception of the calcium content, which exceeded the maximum allowable amount. This finding is in agreement with Zhang et al. (2010), who argued that carbonate precipitation is more selective for magnesium than calcium, due to the thermodynamics favouring the co-precipitation of calcium, which is attributed to the low log K(Ca/Mn) value determined in comparison to the theoretical K value.
The lower MnCO3 yields from Tests 1, 3, and 5 were due to the co-precipitation of additional phases such as Na2CO3 and (NH4)2Mg(SO4)2.6H2O. These phases, however, are water-soluble; therefore the product was washed with water to yield products that contained >92% MnCO3.
A disadvantage of using Na2CO3 as a base reagent in this system was that between pH 7.3-7.5 buffering appeared to have occurred, due to the buffering action of the bicarbonate that formed from the dissociation of carbonic acid. To overcome this, a stoichiometric amount of NaOH was added to increase the pH to approximately 8.5.
After the addition of the NaOH the pH was raised to >8.5, resulting in 98.9% Mn recovery, in comparison to 96% Mn recovery at pH 7.5.
Furnace feed material
The production of the MnCO3 furnace feed material involved the precipitation of impurities followed by the precipitation of manganese as MnCO3, without a filtration step.
These results suggest that using NaOH and Na2CO3 or NH3 and (NH4)2CO3 resulted in a product that can potentially be fed into a furnace (>35% Mn), as shown in Tests 1 and 3 in Table X. The MnCO3 furnace feed produced by the NaOH and Na2CO3 precipitation method contained appreciable amounts of sodium (approx. 13 %), which would be detrimental to furnace operations because of the build-up of alkali metals in the furnace, which may lead to explosions and refractory attack. With the use of NH3 and (NH4)2CO3, approximately 45% of the product contained ammonium phases, which would pose a problem to furnace operations owing to the dissociation of the ammonium phases to NH3 and the further dissociation of ammonia to H2 and N2 at temperatures above 400°C.
The ammonium and sodium phases are water-soluble; to rid the material of these phases a water wash step was employed in order to render the product viable as a furnace feed.
To determine the net present values (NPVs), it was decided to utilize past and present production and plant history of the supplier of the slag. In addition, the capex and opex values were calculated based on 2013 expenditures. The NPVs for the products investigated were negative, due to the high acid content of the PLS, which required a large base reagent input to neutralize the solution which in turn increased the operating costs.
An optimization study was undertaken with the primary objective of decreasing the base reagent addition required to neutralize the PLS by investigating the ideal acid amount to be used. The benefits of this included a reduced acid and base reagent consumption, which resulted in a reduction in operating costs, thereby resulting in a positive net profit value and rendering the production processes economically viable. In addition, the technical viability was improved as the amounts of impurities in the leach solution were reduced, as most were precipitated and reported to the residue. This was beneficial for the production of the impure MnCO3 furnace feed material, which had a higher manganese content and lower impurities, thereby yielding a product with a high Mn:Fe mass ratio, which was ideal. In addition, due to the reduction in base reagent consumption, dilution of the PLS was reduced and a high manganese concentration was maintained. This was beneficial for the electrowinning of EMD, since high manganese concentrations (>27 g/l) were required. The results of the study are summarized in Figures 3 and 4.
From the results the ideal acid addition to produce a PLS with high manganese and low impurities content appears to be 40 ml; the pH at this amount is approximately 4.3 and an appreciable amount of impurities had precipitated out, as is evident in Figure 4. The concentrations of Al, Fe, and Si obtained were 5 ppm, 684 ppm, and 39 ppm respectively, in contrast to an acid addition of 100 ml, which resulted in Al, Fe, and Si concentrations of 4 g/l, 1.6 g/l, and 157 ppm. This reduced the Al, Fe, and Si contents of the PLS by 99.88%, 42.8% and 75%, respectively, compared with the original water-starved digestion acid amount of 100 ml. The manganese concentrations at 40 ml acid addition were > 29 g/l, which rendered the leach solution amenable to the production of quality manganese products and was suited for the electrowinning of EMD.
The manganese concentration appeared to decrease with acid additions of less than 50 ml. This was attributed to incomplete reaction of the slag, as less than 50 ml is below the stoichiometric amount, and thus the silicate matrices could not be completely destroyed. The slight decrease in manganese concentration between 40-60 ml acid was probably due to material variance; this is further substantiated by the results given in Table XI, which clearly illustrate the difference between the tests conducted with 50 ml acid under identical conditions and with the same slag sample. The manganese concentrations obtained in test 1 and test 2 differed by 6 g/l, and variances existed between the major impurity elements also.
A countercurrent three-stage water wash was employed on the material produced after the slag material was digested using a 40 ml acid addition. It was vital that the manganese content of the residue was brought below 1% for it to be a viable cement additive. Figure 7 illustrates the extent to which manganese was leached from the material using 40 ml of acid.
From the results in Figure 5 it is evident that the three-stage water wash was able to reduce the manganese content of the residue to approximately 2.7 %, which did not meet the specification of < 1% manganese, thus a 40 ml acid addition was not ideal. A further study was therefore carried out to determine the optimum acid addition required to render the residue suitable for a quality cement additive containing < 1% Mn.
From the results in Figure 6 it appears that an acid addition of 50-55 ml would be ideal, and would yield a manganese content of less than 1% in the residue while still producing a pregnant leach solution of pH 3.5-4 (Figure 3), from which products with a high manganese content can be produced.
Production of a furnace feed material
The pH of the PLS utilized to produce the impure manganese carbonate furnace feed product was approximately 4.3. The manganese and impurities contents are given in Table XII.
Since reducing the acid amount from 100 ml to 40 ml resulted in an increase in pH to 4.3, it was decided to add Na2CO3 or (NH4)2CO3 to increase the pH to >8 in order to precipitate manganese as MnCO3. However, phases such as (NH4)2Mg(SO4)2.6H2O and Na2SO4 co-precipitated and contaminated the product, rendering it unsuitable as a furnace feed. The product was therefore subjected to a washing step with distilled water, as these phases are water-soluble, in an attempt to produce a viable furnace feed. A pure manganese carbonate (>92%) resulted; the XRF analysis is given in Table XIII. The resulting manganese carbonate precipitates yielded >95% MnCO3, with >45% Mn content, and contained less than 9% impurities, of which iron constituted 1-1.2%. Manganese and iron co-precipitated at a pH of approximately 7 when iron was not oxidized and carbonate was added to the PLS (Pakarinen, 2011). As shown by Figure 7, the formation of FeCO3 is impossible due to the high redox potential; however, iron will most likely precipitate as ferric oxohydroxide (FeO(OH)).
It is evident from the results that the composition of the furnace feed material was improved by increasing the pH. Furthermore, the water-soluble phases were effectively removed by washing with water. It can be concluded that the process conditions resulted in a technically viable product.
The XRF analyses in Table XIII indicate that a product with high manganese content and high Mn:Fe ratio of approximately 48:1 was obtained, which acceptable as an additive in ferromanganese production.
To render the production of the various manganese products viable, changes were made to the water starved digestion process after an optimization study had been undertaken to determine the ideal acid amount that would be required to decrease the base consumption. It was determined that an acid amount of 50 ml would be ideal to achieve this. The economic outcome of this alteration is that it rendered the NPVs of the various manganese products positive.
In addition, the change to acid amount yielded an impure MnCO3 furnace feed material with a manganese content of > 45%, which was higher than the ideal manganese content of between 35-40%, which is sought after by the ferroalloy industry. The benefits of the feed material produced via the hydrometallurgical route include a high quality feed material which will result in an increase in the production of ferromanganese metal per day as the recoveries of manganese will be increased, and thereby industry will have the option of purchasing lower grade ore (high Fe ore) at a reduced cost (Steenkamp, 2013).
Electrowinning of EMD
We decided to electrowin electrolytic manganese dioxide (EMD) from the PLS by water-starved digestion of the slag with 40 ml of sulphuric acid. The cake was then water-leached with 350 ml of distilled water to ensure that the manganese concentration in the leach solution was >27 g/l, allowing it to be amenable to electrowinning of the EMD product. This method was employed due to the chemical variance of the slag sample, and to ensure that the recovery of manganese to the leach solution was >27 g/l. The concentrations of the manganese and impurity elements in the leach solution before and after purification with ammonia solution are given in Table XIV.
The mass of EMD produced over a 72 hour period was 8.3 g, thus yielding a current efficiency of approximately 74%. A current density of 100 A/m2 should result in current efficiencies that typically lie between 90-97%, as was achieved by by Te Riele (1983). The current efficiency in this investigation, however, may have been affected by the increase in acid concentration, which promoted the formation of Mn3+. This can be overcome by increasing the pH by adding a base reagent such as ammonia, in order to increase the pH to 5-6, thereby maintaining an ideal current efficiency.
The results in Table XV indicate that a product that meets specifications can be produced. The iron content was high; however, this result is not in agreement with the ICP-OES analysis of < 1 ppm Fe (Table XIV). According to Te Riele (1983) a pregnant leach solution containing < 1 ppm Fe should yield a product with only 0.021 % Fe. Furthermore, SEM-EDS analysis of the material did not detect iron.
The micrograph in Figure 8 clearly show slight pitting of the surface of the EMD.
Figure 9 is considered to show the typical morphology of EMD. The morphology appears to be similar to that obtained by Liu et al. (2007). Thus, good quality EMD can be produced from the leaching of ferromanganese slag.
Conclusions and recommendations
The manganese content of the slag (>30%) rendered the material attractive for further processing. A pregnant leach solution with typical manganese concentration of 25-35 g/l and low impurities content was obtained. Impurities were effectively removed using ammonia or sodium hydroxide. Ammonia was the most effective reagent, removing Fe, Si, and Al to levels of <1 ppm.
Water-starved digestion of the slag with 100 ml sulphuric acid and purification of the resulting solution led to a manganese recovery of >99.7% into a manganese carbonate product at a pH >8.5. However, co-precipitation of calcium carbonate resulted in the product exceeding the maximum specified calcium content. Further investigations will be aimed at investigating the kinetics of co-precipitation in order to decrease the amount of calcium carbonate precipitated.
A viable MnCO3 furnace feed material with a high manganese (> 45% Mn) and low iron content (< 2% Fe) was produced from the pregnant leach solution utilizing NH3 and (NH4)2CO3 or NaOH and Na2CO3 to increase the pH to >8.5. Water-soluble phases containing ammonia and sodium that formed could be detrimental to furnace operations. To rid the feed material of these phases and to yield a quality product the material was washed with water, which yielded a product containing >95% MnCO3.
Although the processes were shown to be technically feasible, the large amounts of the base reagent required to adjust the pH of the pregnant leach solution from less than 0 to 5.6 when 100 ml of sulphuric acid was utilized in the digestion stage resulted in an increase in operating costs, rendering the production of the manganese products unviable. Therefore, to improve economic viability a study was undertaken to optimize the quality of the PLS, and to produce a leach residue (cement additive) that contained < 1% Mn. It was found that decreasing the sulphuric acid addition to approximately 50 ml resulted in an increase of the pH of the PLS to approximately 3.4-4, and within this pH range most of the major impurity elements precipitated out and reported to the residue. This adjustment resulted in the production of a MnCO3 furnace feed material with a manganese content >45% and a high Mn: Fe ratio.
In addition, to produce pure manganese carbonate, a smaller amount of neutralizing reagent would be required to adjust the pH to 5.6 when utilizing an acid addition of 50 ml. This adjustment rendered the process economically viable. Additional benefits of using 50 ml of acid in the digestion stage include a significant reduction in the dilution of the pregnant leach solution with large amounts of base reagent, thereby maintaining a high manganese concentration in the leach solution, and eliminating potential gelling problems.
The use of a hydrometallurgical process to recover manganese products and produce a leach residue that is saleable as a cement additive is beneficial to the environment and surrounding communities in ferromanganese-producing areas. Both slag dumps and current arisings can be utilized, thereby reducing the environmental and health risks posed by the leaching of mobile manganese contained in the slag. In addition, all potential waste streams produced during the hydrometallurgical process, such as the barren solution, can potentially be recycled to produce additional marketable byproducts, including ammonium sulphate or sodium sulphate. However, further investigations would have to be carried out to confirm this.
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