Trans. Nonferrous Met. Soc. China 26(2016) 1696-1705

Recovery of titanium from undissolved residue (tionite) in titanium oxide industry via NaOH hydrothermal conversion and H₂SO₄ leaching

Fan-cheng MENG^1,2,3, Tian-yan XUE^1,2, Ya-hui LIU^1,2, Guo-zhi ZHANG^1,2,3, Tao QI^1,2

1. National Engineering Laboratory for Hydrometallurgical Cleaner Production Technology, Institute of Process Engineering, Chinese Academy of Sciences, Beijing 100190, China;

2. Key Laboratory of Green Process and Engineering, Institute of Process Engineering, Chinese Academy of Sciences, Beijing 100190, China;

3. University of Chinese Academy of Sciences, Beijing 100049, China

Received 10 July 2015; accepted 10 November 2015

Abstract:

To recover titanium from tionite, a new process consisting of NaOH hydrothermal conversion, water washing, and H₂SO₄ leaching for TiO₂ preparation was developed. The experimental results show that under the optimum hydrothermal conversion conditions, i.e., 50% NaOH (mass fraction) solution, NaOH/tionite mass ratio of 4:1, reaction temperature of 240 °C, reaction time of 1 h and oxygen partial pressure of 0.25 MPa, the titanium was mainly converted into Na₂TiO₃, and the conversion was 97.2%. The unwanted product Na₂TiSiO₅ remained stable in water washing, and its formation was prevented by improving NaOH concentration. In water washing process, about 97.6% of Na⁺ could be recycled by washing the hydrothermal product. The NaOH solutions could be reused after concentration. 96.7% of titanium in the washed product was easily leached in H₂SO₄ solution at low temperatures, forming titanyl sulfate solution to further prepare TiO₂.

Key words:

tionite; titanium recovery; NaOH hydrothermal conversion; water washing; H2SO4 leaching;

1 Introduction

TiO₂ is an important inorganic chemical reagent that is widely used in white pigment, plastic, paper, and photocatalyst [1-3]. The industrial technologies for TiO₂ production mainly include the sulfate process and the chloride process [4]. In China, more than 90% of TiO₂ is produced via the sulfate process [5]. One of the major solid wastes in the sulfate process is the undissolved residue generated during the digestion of titanium-based minerals [6,7]. This undissolved residue, known as tionite in some literatures [8,9], is a fine-grained mud composed of titanium, iron, and silicon minerals. Up to 0.4-0.6 tons of tionite (wet basis) are generated per ton of produced titanium oxide, and the content of TiO₂ in the dry basis of tionite is 35%-50% (mass fraction). In this sense, tionite can be regarded as a valuable secondary titanium resource. Residual H₂SO₄ and particular heavy metal ions are also present in fresh tionite [10]. Tionite is listed on the National Hazardous Waste List of China (waste code: 261-056-34). At present, tionite usually neutralizes with lime or limestone and is directly stacked in landfills. More than 10 million tons of tionite are discharged per year in China. The treatments previously mentioned not only create great environmental risks and dilemma in disposal space but also cause a significant loss of titanium resource.

Several processes have been reported for the reuse of tionite or the recovery of titanium from tionite. As an example, tionite has been utilized in construction materials, such as clay bricks [8], sulfur polymer cement [11], and ceramic material [9,12]. However, assuring the inertness of hazardous species in the obtained products is a significant concern, and the titanium resource in tionite is wasted. In addition, physical separation methods combining gravity concentration, flotation, or magnetic separation for recycling titanium minerals from tionite have gained significant attention [13-15]. However, these physical separation methods only recycle part of the ilmenite from tionite, and the rest of titanium minerals, such as rutile and anatase, could not be recovered. Due to its fine particle size and high content of impurities, tionite cannot be used as the raw material in the chloride process for TiO₂ production. The high content of silicon and rutile (H₂SO₄ can hardly digest rutile) has also impeded the reuse of tionite in sulfate process. Thus, it is of great importance to develop new method for recovering titanium from the tionite.

Hydrometallurgical processes offer easy and eco-friendly approaches of recovering valuable metals from solid industrial wastes [16,17]. Hydrothermal conversion in alkali solution is an effective method for the conversion or decomposition of titanium and silicon minerals [18,19]. Na₂TiO₃, which was originally obtained by roasting titanium-based minerals with molten NaOH, was the ideal titanate for TiO₂ pigment production in our previous studies [20, 21]. However, no studies have been reported on the preparation of Na₂TiO₃ via NaOH hydrothermal method as well as the competitive formation of Na₂TiSO₅ and the whole process for recovering titanium.

To avoid environmental issues and recover titanium from tionite, this study presented a new eco-friendly process. The flow sheet of this process combining NaOH hydrothermal conversion, water washing, and H₂SO₄ leaching for TiO₂ production is shown in Fig. 1. This new process seems to be more energy-saving and can consume solid waste tionite and even the waste acid produced in the sulfate process. It appears a promising supplement to the existing sulfate process of TiO₂ industry. The effects of key factors on the NaOH hydrothermal conversion of tionite and the recovery of titanium from tionite were investigated.

2 Experimental

2.1 Materials

The fresh tionite (wet basis) used in this study was supplied by Shandong Dongjia Group Co., Ltd., China. Prior to the experiments, the fresh tionite was washed with water and filtered for the removal of acid. Next, the tionite was treated with a dilute alkaline solution to neutralize the residual acid. The filtration cake was then dried at 100 °C overnight to obtain dry tionite. The chemical composition of dry tionite is listed in Table 1.

Fig. 1 Flow sheet of new process for recovery of titanium from tionite

The content of TiO₂ in dry basis is 46.4%. The X-ray diffraction (XRD) analysis of dry tionite shown in Fig. 2 indicates that rutile, anatase, ilmenite, and quartz are the main phases of tionite. Some titanium and silicon oxides may also exist in tionite as amorphous form [10].

Analytical-grade solid NaOH and deionized water were used throughout the experiments. Commercial- grade pure oxygen was used in hydrothermal conversion.

2.2 Experimental procedures

2.2.1 Hydrothermal conversion

The hydrothermal conversion experiments were carried out in a 1 L nickel autoclave, which was thermostatically controlled within ±2 °C. A mechanical agitator with a stirring speed of 250 r/min was applied to keeping the slurry suspended. For each experiment, the dry tionite was dispersed in the NaOH solution in the autoclave with the working volume of 65%-70%. Different amounts of O₂ was injected into the autoclave prior to the reaction. Then, the autoclave was heated in advance for about 1.5 h to reach the selected temperature. Once the temperature was reached, the time was set as the starting point of the reaction time. After the reaction, the mixture in the autoclave was filtered. The filter cake (hydrothermal product) was sampled and dried for further analysis.

Table 1 Composition analysis results of tionite (mass fraction, %)

Fig. 2 XRD pattern of dry tionite

2.2.2 Water washing for NaOH recirculation

Water washing experiments were performed in a flask reactor heated by an oil bath. The filter cakes obtained from hydrothermal conversion were washed with water at 55 °C. CaO was added into the water washed solution to remove the Si impurities. The water washed solution after desilicication and the hydrothermal converted solution obtained after hydrothermal conversion were then concentrated using a vacuum rotary evaporator to recycle the NaOH solution.

2.2.3 Acid leaching for TiO₂ production

In the acid leaching experiments, the washed filter cake was mixed with H₂SO₄ solution in a flask reactor heated by an oil bath. After the reaction, the mixture was filtered to obtain the titanyl sulfate solution. The prepared titanyl sulfate solution was hydrolyzed at boiling temperature, and the hydrolysis product was washed and calcinated to prepare TiO₂.

2.3 Characterization

The XRD patterns of the solid samples were obtained using an X-ray diffractometer (X’Pert PRO MPD, PANalytical, Netherlands) with Cu K_α radiation. The chemical compositions of the solid samples and the solutions were determined via inductively coupled plasma optical emission spectrometry (ICP-OES) (Optimal 5300DV, Perkin-Elmer, USA).

Titanium in tionite could be converted into Na₂TiO₃ or Na₂TiSiO₅ via NaOH hydrothermal conversion. The solid sample was dissolved in 3.1% HCl (mass fraction) solution. The dissolution process occurred according to the following reactions:

Na₂TiO₃+4HCl=TiO²⁺+4Cl^-+2Na⁺+2H₂O        (1)

Na₂TiSiO₅+4HCl=TiO²⁺+4Cl^-+2Na⁺+H₂SiO₃+H₂O (2)

After dissolution of the hydrothermal product (the titanium in the unreacted tionite cannot be dissolved), titanium conversion was calculated via the analysis of ICP-OES.

The morphologies of the solid samples were characterized by scanning electron microscopy (SEM) (JSM-6700, JEOL, Japan) equipped with energy dispersive X-ray spectroscopy (EDS) (INCA X-MAX, Oxford Instruments, US).

3 Results and discussion

3.1 Hydrothermal conversion

3.1.1 Effects of NaOH concentration and NaOH/tionite mass ratio

The effects of NaOH concentration and NaOH/tionite mass ratio on the conversion of titanium are shown in Fig. 3. The results indicate that the conversion of titanium increased with increasing the NaOH/tionite mass ratio at a known NaOH concentration. The conversion rapidly increased from 59.2% to 84.1% when the NaOH/tionite mass ratio increased from 2:1 to 6:1 in 40% NaOH solution. The theoretical mass ratio for the complete reaction is 0.77:1. Excess NaOH, which acts as a mineralizer in the hydrothermal process, is necessary to ensure that the reaction goes into completion. The results shown in Fig. 3 also indicate that the conversion of titanium increased with increasing the NaOH concentration. Furthermore, the conversion of titanium slightly increased when the NaOH concentration increased from 50% to 60% at NaOH/ tionite mass ratios above 4:1.

Fig. 3 Effects of NaOH concentration and NaOH/tionite mass ratio on conversion of titanium

The XRD patterns of the hydrothermal products obtained at different NaOH concentrations and NaOH/ tionite mass ratios are shown in Fig. 4. The main phases of the solid samples obtained at 50% NaOH solution were α-Na₂TiO₃, Na₂SiO₃, and a small amount of Na₂TiSiO₅. Na₂CO₃ was detected due to the reaction of residual NaOH in hydrothermal product with CO₂ in drying the hydrothermal sample for analysis. Fewer peaks of iron components in the hydrothermal products were detected because iron oxide may react with NaOH and exist with low crystallinity. α-Na₂TiO₃ (JCPDS  No. 028-1152) was a metastable phase of Na₂TiO₃ according to the previous study [20,21]. However, with the decrease of NaOH concentration, the amount of Na₂TiSiO₅ increased. The dominant phase of titanium was Na₂TiSiO₅ in the hydrothermal products obtained in 30% and 40% NaOH solutions. Some unreacted rutile, anaste, and ilmenite were also observed. No peaks of Na₂SiO₃ were detected in the above hydrothermal products, which indicates that most of Si and a part of Ti reacted with NaOH to form Na₂TiSiO₅. Na₂TiSiO₅ (JCPDS No. 048-1892), namely natisite, is a stable titanosilicate with a dense structure [22].

The hydrothermal products obtained in 50% NaOH solution with NaOH/tionite mass ratio of 4:1 and 40% NaOH solution with NaOH/tionite mass ratio of 4:1 shown in Fig. 4 were named hydrothermal products A and B, respectively. The SEM images and EDS results of hydrothermal products A and B are shown in Fig. 5. The results show that α-Na₂TiO₃ was somewhat porous and full of loose rough-etched traces. The rough-etched surface and porous structure could endow α-Na₂TiO₃ good ion-exchange ability when it was treated with water, contributing to the subsequent Na⁺ recycling. Whereas, with a smooth square sheet structure, Na₂TiSiO₅ remained stable in water (Section 3.2) and slowly disintegrated in H₂SO₄ solution to form a large amount of gel that contained silicon and titanium, which would result in significant loss of Na and Ti components.

Thus, the formation of Na₂TiSiO₅ must be avoided in NaOH hydrothermal conversion. α-Na₂TiO₃ was the ideal target product in NaOH hydrothermal conversion, and 50% NaOH solution was favorable for the formation of α-Na₂TiO₃.

Fig. 4 XRD patterns of hydrothermal products obtained at different NaOH concentrations and NaOH/tionite mass ratios

Fig. 5 SEM images of hydrothermal product A (a) and hydrothermal product B (b), and EDS point analysis of spot 1 (c) and spot  2 (d)

3.1.2 Effect of reaction temperature and reaction time

The effects of reaction temperature and reaction time on the titanium conversion are shown in Fig. 6. The results indicate that the conversion of titanium reached 87.7% at 240 °C for 1 h, whereas a less conversion of 68.3% was observed at 210 °C for 1 h. The results indicate that increasing the temperature was favorable to titanium conversion, which could be attributed to the fact that high temperatures can change the chemical equilibrium constants and boost the reaction rates [23]. Furthermore, the reaction time had less influence on the conversion of titanium after 1 h, especially at high temperatures, meaning 1 h was the optimum reaction time.

Fig. 6 Effects of reaction temperature, reaction time, and oxygen partial pressure on conversion of titanium

The XRD patterns of the hydrothermal products obtained at different reaction temperatures and reaction time are shown in Fig. 7. This result indicates that a long reaction time favored the formation of Na₂TiSiO₅ probably because the produced metastable α-Na₂TiO₃ transformed into stable Na₂TiSiO₅. In comparison with product obtained at 240 °C for 4 h, those products obtained at 240 °C for 1 h had less Na₂TiSiO₅. As shown in Fig. 7, more Na₂TiSiO₅ was also observed with increasing the reaction temperature. Although less Na₂TiSiO₅ formed at 210 °C, the conversion of titanium remained lower than 83% even for a long reaction time of 4 h (Fig. 6). As shown in Fig. 7, some unreacted rutile, anaste, and ilmenite still remained in the hydrothermal product at 210 °C. When the temperature increased to 270 °C, more than 94% of titanium conversion of tionite could be obtained, but much Na₂TiSiO₅ was observed. The formation of Na₂TiSiO₅ might be attributed to the combination of Na₂TiO₃ and Na₂SiO₃ at such a high temperature.

Fig. 7 XRD patterns of hydrothermal products obtained at different reaction temperatures and reaction time

3.1.3 Effect of oxygen partial pressure

Different amounts of O₂ were injected into the autoclave prior to the hydrothermal reaction to investigate the effect of oxygen partial pressure. The results shown in Fig. 6 indicate that the conversion of titanium increased obviously with increasing the oxygen partial pressure with the reaction time of 1 h. At an oxygen partial pressure of 0.25 MPa for 1 h, the conversion of titanium was 97.2%, which was much higher than that without adding O₂. Further increasing the O₂ partial pressure to 0.50 MPa led to no evident increase of the conversion of titanium with a reaction time of 1 h. Thus, 0.25 MPa of oxygen partial pressure was optimal for this reaction. The XRD patterns of hydrothermal products shown in Fig. 8 indicate that the addition of oxygen facilitated the decomposition of ilmenite in tionite, and the dominant phase of titanium in hydrothermal products remained Na₂TiO₃.

Fig. 8 Effect of oxygen partial pressure on XRD patterns of hydrothermal products

3.1.4 Mechanism on NaOH hydrothermal conversion of tionite

Titanium components undergo a dissolution/ precipitation process in NaOH solution under hydrothermal conditions [24]. The reaction of titanium-based minerals in tionite with NaOH solution resulted in the release of titanium as Ti(IV), probably in the form of . Among many kinds of meta-silicic ions,  was the predominant ion in highly concentrated NaOH solutions [25]. The dissolved Ti(IV) could form Na₂TiO₃ or integrate with  to form Na₂TiSiO₅. Thus, the overall hydrothermal reactions could be described as follows:

TiO₂+2OH^-→+H₂O                    (3)

2Na⁺+→Na₂TiO₃(s)                    (4)

SiO₂+2OH^-→+H₂O                    (5)

2Na⁺+++H₂O→Na₂TiSiO₅(s)+2OH^-   (6)

Na₂TiSiO₅ contains layers of tetrahedral SiO₄ and square pyramidal TiO₅ joined at the corners and separated by layers of Na⁺ ions [26]. Na₂TiO₃ was in the form of α-Na₂TiO₃ in this study, and it exhibited the NaCl-type structure with the Na and Ti ions randomly placed in the cation sites. It had a closely packed array of Na and Ti atoms in an octahedral coordination [27]. The bond length of Ti—O calculated by XRD was about 2.250  in Na₂TiO₃, which was longer than those in rutile (from 1.949 to 1.980 ) and Na₂TiSiO₅ (from 1.695 to 1.990 ) [28]. This result indicates that the Na₂TiO₃ structure was more active and metastable.

The XRD patterns shown in Fig. 4 indicate that more Na₂TiSiO₅ formed with decreasing the NaOH/tionite mass ratio. When the NaOH/tionite mass ratio was 6:1 in 50% NaOH concentration, Na₂TiSiO₅ was not detected. According to Eqs. (3) and (5), the NaOH concentration decreased as the hydrothermal conversion proceeded because the reactions consumed NaOH. At a high NaOH concentration of 50%,  and  would combine with Na⁺ to form Na₂TiO₃ and Na₂SiO₃, respectively. At a low NaOH concentration, Na₂TiO₃ would be unstable or disintegrated, and  would integrate with  to form Na₂TiSiO₅, as demonstrated in Eq. (6). The low NaOH concentration is inferred to be the key factor that leaded to the formation of Na₂TiSiO₅.

In addition, the reaction of ilmenite with NaOH solution under oxygen atmosphere is shown as follows [29]:

4FeTiO₃+8NaOH+O₂→4Na₂TiO₃+2Fe₂O₃+4H₂O   (7)

O₂ has an important function in the hydrothermal conversion of ilmenite. O₂ could aid the decomposition of FeTiO₃ and increase the total conversion of titanium in tionite. When the amount of O₂ is low, Reaction (7) will generate Fe₃O₄ or FeO, which are hardly soluble in NaOH solution and would surround the ilmenite particle to prevent further conversion reactions. However, with enough O₂ amount, the generated Fe₂O₃ underwent a dissolution/precipitation process in NaOH solution which could promote the decomposition of ilmenite. The re-precipitated Fe₂O₃ had low degree of crystallinity, thus, fewer peaks were shown in the XRD patterns. The solubility of Fe₂O₃ increases with increasing the reaction temperature and NaOH concentration [30], and the reaction is present as follows:

Fe₂O₃+2NaOH→+2Na⁺+H₂O            (8)

As shown in Fig. 6, a higher oxygen partial pressure led to a higher reaction rate and intense conversion of titanium-based minerals. In concentrated NaOH solutions, an acid–base equilibrium existed [31]:

2OH^-→H₂O+O^2-                            (9)

Another solubility equilibrium is described as follows [32]:

1/2O₂+O^2-→                           (10)

When the oxygen partial pressure increased, the quantity of O^2- and  clusters increased. They oxidized the iron components in ilmenite and facilitated the breakage and decomposition of Ti-O bonds. In this sense, a certain amount of oxygen must be injected into the autoclave to obtain the complete conversion of titanium-based minerals, especially ilmenite in tionite.

The following optimal hydrothermal parameters were proposed to obtain the ideal phase of Na₂TiO₃ and avoid the formation of Na₂TiSiO₅: NaOH concentration of 50%, NaOH/tionite mass ratio of 4:1, reaction temperature of 240 °C, reaction time of 1 h and oxygen partial pressure of 0.25 MPa. The hydrothermal product obtained under the above optimum hydrothermal conditions, namely hydrothermal product C, had a titanium conversion of 97.2% and its prominent phase of titanium was Na₂TiO₃.

3.2 Water washing of hydrothermal products and NaOH recirculation

Na⁺ in the hydrothermal products should be recovered for NaOH recirculation by water washing. Up to now, there was no report on the behaviors of Na₂TiSiO₅ in water. To further figure out the difference in ion-exchange ability of Na₂TiSiO₅ and Na₂TiO₃, the representative hydrothermal products B (main phase is Na₂TiSiO₅) and C (main phase is Na₂TiO₃), were washed in water with the water/hydrothermal product mass ratio of 1.5:1 at 55 °C four times. The XRD patterns of the water washed products are shown in Fig. 9. The peaks of Na₂TiO₃ and Na₂SiO₃ in hydrothermal product C both disappeared, and the water washed product C remained as an amorphous phase with very weak TiO₂ and FeTiO₃ peaks, which means that Na₂TiO₃ had excellent ion-exchange ability in water. However, Na₂TiSiO₅ in hydrothermal product B remained stable in water washed product B. Further ICP-OES analysis shows that Na⁺ in Na₂TiSiO₅ could hardly be leached in water. Hence, the loss of Na⁺ was greatly attributed to Na₂TiSiO₅ formation. Just as reported before, Na⁺ in Na₂TiO₃ could easily exchange with H⁺ in water [27]. This exchange was the basis of NaOH recirculation in this process. The ion exchange reaction could be described as follows:

Na₂TiO₃+xH₂O→Na_2-xH_xTiO₃+xNaOH         (11)

Fig. 9 XRD patterns of hydrothermal products B and C after water washing

Thus, Na⁺ in the structure of Na₂TiO₃ could also be recycled via water washing. The leaching results of Na⁺ and the removal fractions of other impurities via water washing are shown in Fig. 10. The total recovery of Na⁺ after washing four times was 97.6%. Moreover, the total removal fractions of Si, Al, and Mn were 78.3%, 93.3% and 29.7%, respectively. The compositional analysis results of the water washed product are listed in Table 2.

Fig. 10 Leaching fractions of Na, Si, Al and Mn at varying water washing times

Table 2 Compositional analysis results of water washed product (mass fraction, %)

Si was the major impurity which could lead to the formation of Na₂TiSiO₅. Thus, Na₂SiO₃ in the recycled NaOH solution should be limited. Table 3 indicates that the solubility of Si decreased with the increase of NaOH concentration. The concentrations of NaOH and Si in hydrothermal converted solution (CS) was 735.6 and 4.6 g/L, respectively. This result indicates that Si would not accumulate in the solution when it was reused. Further experiments reveal that residual Si exhibited no effect on the hydrothermal conversion when CS was directly reused without desilication. The results shown in Fig. 10 indicate that only 16.5% of Si remained in CS, and 61.8% of Si was leached in water after water washing. To remove Si impurities from water washed solution (WS), CaO was added when WS was heated at 95 °C, and more than 92% of Si was removed from WS with the precipitation of calcium silicates. After desilication, the concentration of Si in WS was less than 0.6 g/L.

Table 3 Solubility of Si in NaOH solutions with different concentrations (Calculated from solubility of Na₂SiO₃ in NaOH solutions at 50 °C from Ref. [33])

The NaOH concentrations in the CS and WS obtained from four times of countercurrent washing were about 735.6 and 202.7 g/L, respectively. The moderate NaOH concentration gaps made them both economically and technically feasible to be evaporated to a concentration of 50% (about 762.6 g/L) for reuse in hydrothermal conversion.

3.3 Leaching of titanium by H₂SO₄ solution for TiO₂ preparation

Titanium in the washed solid product could be leached by H₂SO₄ solution to prepare titanyl sulfate solution for TiO₂ production. The effect of temperature on the leaching fraction of titanium was investigated with 20% H₂SO₄. The results shown in Fig. 11 indicate that a large portion of titanium could be easily leached by 20% H₂SO₄ at low temperatures for 60 min. The leaching fraction of titanium increased with increasing the reaction temperature. However, the amount of titanium leached at 75 °C decreased after 120 min. This decrease may be due to the hydrolysis of titanium at higher temperature for a long time.

Fig. 11 Effect of leaching temperature and time on titanium leaching fraction

The results shown in Table 4 indicate that higher H₂SO₄ concentration tended to obtain higher titanium leaching fraction, and 96.7% of titanium could be leached in 40% H₂SO₄ solution at 55 °C for 60 min. The composition of the prepared titanyl sulfate solution was shown in Table 5. The results indicate that with the exception of Si, most of the other impurities could be leached. Most of the Si was separated from the solution in the form of silica gel remaining as a solid residue under the above conditions.

Table 4 Titanium leaching fraction by different H₂SO₄ concentrations

The H₂SO₄ concentration and reaction temperature in this process were much lower than those used for the digestion of ilmenite in the traditional sulfate process (85%-95% H₂SO₄, 180-200 °C) [10]. The apparent activation energy for the decomposition of titanium intermediates Na_2-xH_xTiO₃ by H₂SO₄ was reported to be 28.7 kJ/mol, which was much lower than that for the decomposition of ilmenite by H₂SO₄ (72.6 kJ/mol) [33]. Therefore, the titanium in the washed solid product could be easily leached by 20%-60% H₂SO₄ solution at 30-75 °C. Due to its good acid-leaching performance of the washed solid product, the waste acid containing about 20% H₂SO₄ generated from the sulfate process for TiO₂ production could be used directly or after concentration in the above acid leaching process.

After concentration, the titanyl sulfate solution was hydrolyzed at boiling temperature, and the obtained hydrolysis product H₂TiO₃ was then washed and calcinated to prepare TiO₂. The XRD pattern and SEM image shown in Fig. 12 indicate that the obtained TiO₂ product was well-crystallized rutile with the average sizes of elementary particles of 0.3-0.5 μm. The chemical composition of the obtained product was 99.4% TiO₂, 0.037% SiO₂, 0.013% ∑Fe, 0.051% MgO, and 0.113% SO₃. The product could be used as TiO₂ white pigment after post-treatment.

Table 5 Compositional analysis results of prepared titanyl sulfate solution (g/L)

Fig. 12 XRD pattern and SEM image of obtained TiO₂ product

4 Conclusions

1) A new process for the recovery of titanium from tionite was proposed. This process comprised of NaOH hydrothermal conversion, water washing, and H₂SO₄ leaching for TiO₂ preparation.

2) Under the optimum hydrothermal conversion conditions, i.e., NaOH concentration of 50%, NaOH/ tionite mass ratio of 4:1, reaction temperature of 240 °C, reaction time of 1 h, and oxygen partial pressure of 0.25 MPa, about 97.2% of titanium in tionite was converted and Na₂TiO₃ was the main phase of titanium. The increase of NaOH concentration and NaOH/tionite mass ratio in hydrothermal conversion prevented the formation of the unwanted product Na₂TiSiO₅.

3) About 97.6% of Na⁺ could be recycled after washing the optimum hydrothermal products with water four times. The hydrothermal converted solution could be reused without desilicication. More than 92% of Si was removed from the water washed solution by adding CaO, and the obtained NaOH solution could be reused after concentration.

4) Titanium in the water washed product was easily leached by 20%-60% H₂SO₄ solution at 30-75 °C, forming titanyl sulfate solution to further produce TiO₂. The optimum recovery of titanium was up to 96.7%.

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NaOH水热转化-H₂SO₄浸出法从硫酸法钛白酸解残渣(黑泥)中回收利用钛

孟凡成^1,2,3，薛天艳^1,2，刘亚辉^{1, 2}，张国之^1,2,3，齐 涛^1,2

1. 中国科学院 过程工程研究所 湿法冶金清洁生产技术国家工程实验室，北京 100190；

2. 中国科学院 过程工程研究所 绿色过程与工程院重点实验室，北京 100190；

3. 中国科学院大学，北京 100049

摘  要：提出一种从黑泥中回收利用钛的新工艺，该工艺包括NaOH水热转化、水洗和H₂SO₄浸出制备TiO₂。在优化的反应条件下，即NaOH溶液浓度为50%(质量分数)、NaOH/黑泥质量比为4:1、反应温度为240 °C、反应时间为1 h和氧气分压为0.25 MPa，钛转化率可达97.2%，主要含钛产物是Na₂TiO₃。非目标产物Na₂TiSiO₅在水洗中保持稳定，在水热反应中提高NaOH浓度可以抑制Na₂TiSiO₅的生成。水热产物经过水洗后，97.6%的Na⁺可以回收。含有NaOH的溶液经过浓缩之后可以回用。在较低温度下，水洗物料中96.7%的钛能被较低浓度的硫酸浸出得到钛液。利用所得钛液进一步制备合格TiO₂产品。

关键词：黑泥；钛回收；NaOH水热转化；水洗；H₂SO₄浸出

(Edited by Mu-lan QIN)

Foundation item: Project (51090380) supported by the National Natural Science Foundation of China; Projects (2013CB632604, 2013CB632601) supported by the National Basic Research Program of China; Project (51125018) supported by the National Science Foundation for Distinguished Young Scholars of China; Project (KGZD-EW-201-2) supported by the Key Research Program of the Chinese Academy of Sciences; Projects (51374191, 51402303) supported by the Natural Science Foundation for the Youth, China

Corresponding author: Tian-yan XUE; Tel: +86-10-82544848; E-mail: tyxue@ipe.ac.cn

DOI: 10.1016/S1003-6326(16)64247-4

Abstract: To recover titanium from tionite, a new process consisting of NaOH hydrothermal conversion, water washing, and H₂SO₄ leaching for TiO₂ preparation was developed. The experimental results show that under the optimum hydrothermal conversion conditions, i.e., 50% NaOH (mass fraction) solution, NaOH/tionite mass ratio of 4:1, reaction temperature of 240 °C, reaction time of 1 h and oxygen partial pressure of 0.25 MPa, the titanium was mainly converted into Na₂TiO₃, and the conversion was 97.2%. The unwanted product Na₂TiSiO₅ remained stable in water washing, and its formation was prevented by improving NaOH concentration. In water washing process, about 97.6% of Na⁺ could be recycled by washing the hydrothermal product. The NaOH solutions could be reused after concentration. 96.7% of titanium in the washed product was easily leached in H₂SO₄ solution at low temperatures, forming titanyl sulfate solution to further prepare TiO₂.