The Study of Method for Complex Processing Turgay Sub-Standard Aluminum-Containing Raw Materials

doi:10.4236/ampc.2012.24B055

Paper Menu >>

Journal Menu >>

Advances in Ma terials Physics and Chemistry, 2012, 2, 216-220

doi:10.4236/ampc.2012.24B055 Published Online December 2012 (htt p://www.SciRP.org/journal/ampc)

The Study of Method for Complex Processing Turgay

Sub-S tandard Aluminum-Containing Raw Materials

G. Sarsenbay , L. A. Myltykbaeva, R. A. Abdulwalyev, S. B. Satylganova

Cen ter of Eart h Sciences, Metallurgy and O re Beneficiation, JSC, Science an d Educati on Ministry of the Republic of Kazakhstan

Email: ао.cnzmo@rambler.ru

Received 2012

ABSTRACT

obj ects of the r esearch are Ka zakhs tan’s Tur gay clay, studied of method for alumina and potassium metasilicate obtaining from Tur-

gay sub-standard aluminum raw materials. Concluded that optimal conditions for the process of Turgay clay: reaction temperature

100°C, original solution K2O concentr ati o n to 300 g/ dm3, reaction time 120 min, liquid-solid ratio of 3:1; optimized the conditions of

digestion alumina concentrate: original Na2O solution concentration of 400 g/dm3, temperature 280°C, molar ratio CaO : SiO2 =

1. Recovery is 99.6% of alumina digestion under this condition; crystallized solid phase components as Na2O·Al2O3·6H2O sodium

hydroaluminate crystals. Extracted of alumina from solution of sodium hydroaluminate.

Keywords: Potassium Hydroxide Solution; Leaching; Clay; Alumina Concentrate; Sodium Aluminate Solution; Digestion;

Desilication; Alumina

1. Introduction

With the reduction of bauxite resources, the application of low-

grade aluminum-containing raw materials i n aluminum produc-

tion will be the key question. Kazakhstan is rich of low grade

bauxite mine (burnt ash, clay), which were the storage of Tur-

gay clay long enough to provide raw materials for alumina

production [1]. For low grade aluminum ore, chemical benefic-

iation processing – alkali leaching to removal some silicon-

containing to extraction silicate mineral, and alumina produc-

tion by using concentrate can be comprehensive utilization of

raw materials, solve problems of production effectively. Study

on alkaline leaching of high-silicon aluminum ore, treated by

sodium hydroxide solution and extraction silicate widely visible

[2,3], not seen on the potassium hydroxide reports. Potassium

silicate as main ingredient for high-quality potassium fertilizer

of chloride-free is widely used in agricultural production. For

the purpose of this study to complex processing Turgay clay,

potassium hydroxide solution used for the first time of low

grade aluminum-containing raw materials dressing process, by

planning central composite second order rotatable experiment

and hydrochemical test, to find the best reaction condition of

extraction from Turgay clay industrial alumina and chlorine-

free po tash fertil izer processing methods.

2. Experimental

2.1. Optimization Process of Clay ore Dressing

Potassium silicate solution and alumina concentrate can be

obtained by baking clay leaching by potassium hydroxide solu-

tion, using central composite second order rotatable test [4] to

find the optimal leaching conditions.

Chemical composition of Turgay’s baking clay samples for

experiments is: SiO2 37%; Al2O3 42.6%; Fe2O3 13.8 %; CaO

1.3%; Na2O 0.8%; other 1.5%; A/S=1.15. The experiments an d

results: using of the central composite of second order rotata-

ble to develop test, factors influencing the leaching effect of

three is made for the variabl e: X1 as the concen tration for K2O

in original solution, g/dm3; X2 for leaching time, min; X3 for

liquid-solid ratio, percentage of SiO2 into solution (y) selected

optimization parameter. Experiment conditions and results of

Second order rotatable as shown in Table 1.

Table 1 Conditions and results of experiments.

Ν Conditions, g/dm 3, min Solu tion components, g/dm3, %

X1 X2 X3 K2O Al2O3 SiO2 SiO2

1 100 60 2:1 61.1 1.38 98.0 48.21

2 300 60 2:1 211.5 2.46 243.5 79.00

3 100 180 2:1 56.4 1.63 99.5 48.94

4 300 180 2:1 253.8 2.89 2 28.5 78.40

5 100 60 4:1 61.1 1.13 70.5 69.32

6 300 60 4:1 282.0 2.64 105.0 79.44

7 100 180 4:1 61.1 1.63 72.5 71.29

8 300 180 4:1 282.0 3.13 97.5 82.84

9 31.8 120 3:1 30.25 2.6 4 26.5 20.93

10 336.4 120 3:1 235.0 1.13 162.5 80.86

11 200 19 3:1 188.0 1.13 95.0 65.02

12 200 221 3:1 188.0 2.64 112.0 76.66

13 200 120 1,31:1 188.0 2.64 208.0 62.26

14 200 120 4,68:1 188.0 0.12 74.0 79.06

15 200 120 3:1 164.5 1.63 114.3 78.23

16 200 120 3:1 188.0 1.13 114.5 78.37

17 200 120 3:1 164.5 1.13 114.0 78.03

18 200 120 3:1 164.5 1.13 115.0 78.71

19 200 120 3:1 164.5 1.63 113.5 77.69

20 200 120 3:1 88.0 1.63 115.3 78.88

G. SARSENB AY ET AL.

217

According to the planning of matrix and experimental results

the regression equatio n cal culated, t he equati on is following:

У= 78.14 +13.38Х1 +1.84Х2 +5.61Х3 –8.36Х 12

–1.30Х22 –1.36Х32 – 4.8 3Х 13

Analysis equation can reach the following conclusion: the

factors influencing the silica into solutio n of potassium hydroxide,

the action of the concentration of alkali solution mostly strong.

And compared to other factors, influence of reaction time on

the translate silicon dioxide into solution is weak. Combined

effects of three factors are more complex; factor values from 0

to 1, optimization parameters (у) grows, factor value is higher

than the 1, у value decreases. Three f actors affect t he complex-

ity can be interpreted as, dissolution and precipitation of silicon

dioxide in the system are two processes occur simultaneously,

the result of precipitation forming insoluble compounds - hydro

aluminum silicate of potassium. When baking clay samples

contact with potassium hydroxide solution, silicon dioxide dis-

solves faster than the hydrated aluminum silicate, β – cristoba-

lite (Beta-SiO2) in quartz and silicon into solution, this solution

(potassium silicate) as the main ingredient for fertilizer produc-

tion of potassium is chloride-free. At the same time mullite

(3Al2O3.2 S iO2) break down into solution, concentration of

alumina in solution at lower relative will exist of alumi-

num-silicon complexes, where the proportion of aluminium in

silicon atoms as a unit, as reaction continues, the complexes

with alkali solution combining format insoluble hydrated alu-

minum silicate of potassium. Experiments concluded that the

optimal conditions for the process of Turgay clay: reaction

temperature 100°C, original solution concentration K2O 300

g/dm3, reaction time 120 min, liquid-solid ratio of 3:1.

2.2. Optimization of Process of Digestion Alumina

Concentrate in Sodium Aluminum Solution

The process of extraction alumina products from alumina con-

centrate carried out by hydrochemical methods [5]. Optimal

preparation of alumina under leaching condition concentrate

chemical composition as follows: SiO2 10.4%; CaO 0.2%; K2O

0.2%; Fe2O3 9.55%; Al2O3 62.8%; other 5.0%; A/S 6.04. Phase

compositions are mainly for Mullite and Hematite, with small

amounts of hydrated aluminum silicate of potassium, amorph-

ous SiO2 content low, shows many SiO2 in clay in the process

is dissolved of solution. Concentrate aluminum oxide digestion

in sodium aluminate solution optimizated by hydrochemical

proces s. Test conditions: temperature of 200~280˚C, time 60

min, original Na2O concentration of sodium aluminate solution

330~450 g/dm3, аk 30, CaO: SiO2 = 1.2~ 2. Affect of three fac-

tors of temperature, concentration and calcium oxide on the

aluminum recovery shown in Figure 1-3.

Figure 1 test results view, increasing temperatures from

200˚C to 280˚C, percentage of Al2O3 into sodium aluminate

solution accordingly increased from 90.6 % to 97.63% .

Figure 2 test resu lts, when concen trati on gradu ally increased

to 450 from 330 g/dm3, the alumina recovery into solution co r-

responding increased from 89.3% to 98.56%.

As shown in Figure 3, when the calcium oxide content in-

creased from molar rati o CaO: Si O2 = 1 to 2 , alumina reco very

solution corresponding decreased from 99.6% to 94 %. Studied

the best conditions of d igestion: original solution Na2O concen-

tration of 400 g/dm3, temperature 280˚C, molar ratio CaO :

SiO2 = 1. Recovery is 99.6% of alumina digestion under this

condition.

2.3. Optimization of Process for Desilication of

Sodium Aluminate Solution

The chemical composition of sodium aluminate solution from

processing alumina concentrate by hydro chemistry method as

follows: Na2O 376.7 g/dm3; Al2O3 65.93 g/dm3; SiO2 4.22

g/dm3, αk 9.4, αk high value of this solution, is not conducive

to decomposition out Al(OH)3 from aluminate solution, there-

fore, need ed to be decrease valu es αk before processing of crys-

tallization. This test uses the crystallization from solution of

hydrated sodium aluminate, water soluble crystals method gets

the αk ~1,6 of sodium aluminate solution. When crystallization,

small amounts o f SiO2 will affect t he cr ystall ization in solution,

so before the sodium aluminate hydrate, pre-desilication

process of sodium aluminate solution. Take into account the

effects of concentration on silicon removal efficiency, Na2O

dilute solution concentration from 376.6 g/dm3 to 200 g/dm3,

other components as Al2O3 35 g/dm3 accordingly, iO2 2.2

g/dm3.

Calcium oxide for desilication agent, add amount CaO : SiO2

to 1.5, 2 and 3 calculated, reaction time is 30 - 180 min, test

conducted in the temperature range of 150-250°C, as shown in

Table 2.

Figure 1. The effect of temperature on the aluminum recovery.

Figure 2. The effect of concentration on the alumina recovery.

Figure 3. The effect of calcium oxide content on the al umina recov-

G. SARSENB AY ET AL.

218

ery.

Test results showed highest conditions of sodium aluminate

solution desilication rate: reaction temperature 200 °C, CaO

added molar rat io CaO : SiO2 is 3, time for 120 min. Under this

condition, sodium aluminate solution desilication rate of 79.5%,

solution composition for Na2O 191 g/dm3, Al2O3 34 g/dm3,

SiO2 0.594 g/dm3, αk 9,2.

2.4. Study on Formation of Alumina from

Desilicated Sodium Aluminate Solution

1) Separating out sodium hydroaluminate crystals from de-

silicated sodium aluminate solutio n

Consists of sodium aluminate solution crystallization of so-

dium hydroaluminate - Na2O·Al2O3·nH2O test: to evaporation

solution concentration of Na2O for 500-550 g/dm3, from which

separation crystals. Test results are shown in Table 3. After

enrichment to concentrations of Na2O 548 g/dm3, removal of

sodium aluminate solution concentration to concentrations of

Na2O after 548 g/dm3, crystallization temperature of 45°C,

under the conditions to quality ratio of 0.05 to join seed crystal,

constant stirring. Conditions and results of crystallization shown

in Table 3.

Table 2. Experimental conditio ns and res ults of desilication of sodium aluminate solutio n.

Conditions Components, g/dm3 Des .

rate, %

t,°C CaO:SiO2 min Na2O Al2O3 SiO2

1 100 3 120 182,4 33,7 1,93 13,4

2 150 3 120 188 33,3 0,6 76 ,8

3 200 3 120 190,5 34 0,594 79,5

4 250 3 120 196 20,1 0,65 75

5 200 1 120 196 30 0,747 66,7

6 200 1 ,5 120 190 32 1,0 0 55,6

7 200 2 120 192 33,5 0,56 75

8 200 3 120 191 34 0,47 79,5

9 200 3 30 196 34 0,725 67,6

10 200 3 60 189 3 3 ,3 0,6 77

11 200 3 120 191 34 0,594 79

12 200 3 180 188 34 0,6 7 69,2

Table 3. Experimental conditio ns and res ults of crystallization of sodium hydroaluminate.

°С T

Test conditions,

composition, g/dm3 Test results

composition, g/dm3

Al2O3 Na2O αk Al2O3 Na2O ακ

45 10 91,89 561,1 10 76,67 550,6 11,8

45 20 91,89 561,1 10 71,44 538,5 12,4

45 30 91,89 561,1 10 31 ,2 527,3 27,8

45 40 91,89 561,1 10 29 ,5 502,1 29,0

G. SARSENB AY ET AL.

219

45 50 91,89 561,1 10 27,33 501,8 30,2

Crystallization rate test results in mixing continuously when

50 h reached the highest value. Chemical composition of sepa-

rated sodiu m h ydroa lu minat e cryst als: AI2O3 25.5%; Na2O 24.1%;

other 34.2%, αк 1.58 solid phase components as

Na2O·Al2O3·6H2O, sodium hydroaluminate crystal x-ray dif-

fraction curve as shown in Figure 4 .

2) Extraction of aluminum hydroxide from solution of so-

dium hydroaluminate

Separate sodium hydroaluminate crystal αk is 1.58, this wa-

ter-soluble crystals available αk value breaks and crystal de-

composition conditions of sodium aluminate solution, from

which precipitation Al (OH) 3 crystal [6]. Test pr oced u res are as

follows: dissolving sodium hydroaluminate crystal

Na2O·Al2O3·6H2O, get aqueous chemical composition for,

AI2O3 100.9 g/dm3; Na2O 98.1 g/dm3; αk is 1.58, according to

the quality of the ratio of 0.3, to join seed – aluminum hydrox-

ide in water solution, temperature of 62ºC - 44 ºC cond itions, to

70 p/min speed mixing hydrolysis of sodium aluminate solution

to 48 h. According to table4 test findings, when 24 h reaction,

hydrolysis rate of 41%, when 48 h reaction, hydrolysis rate

Increased to 59 %. (Table 4)

After the complete hydrolysis of sodium aluminate solution,

the liquid-solid separation are obtained solid aluminum hy-

droxide, chemical components for AI2O3 61.30%, Na2O 0.23%,

other 35.75%, X ray diffraction curve shows the solid formation

is divided into size 20-50 µm of gibbsite, as shown in Figure 5.

3) prepara t ion of alumina from aluminum hydroxide

From solid aluminum hydroxide under the condition of tem-

perature of 1050˚C, calcined 1h we are meeting the criteria of

production alumina solid products. Analysis and identification

of aluminum oxide crystals derived from chemical co mposition

as: AI2O3 98.5%, Na2O 0.78%, SiO2 0.02%, Ti+V+Gr+Mn

0.01%, ZnO 0.01%, P2O5 0.002%, Fe2O3 0.026%, weight re-

duction is 1.2%. X-ray diffraction analysis and its solid groups

are divided into: δ Al2O3, χ · Al

2O3,Al2O3, θ Al

2O3, κ Al2O3,

beta-Al2O3, as shown in Figure 6.

Figure 4. Sodium hydroaluminate crystal x-ray diffraction curve.

Table 4. Hydrolysis of sodium aluminate solution test results.

Seed content Tim e, h

Composition,

g/dm3 αк Hydrolysis

rate, %

Na2O AI2O3

0.3 24 100. 3 61.5 2.7 5 41

0.3 48 105. 7 42.7 4.1 59

Figure5. Aluminium hydroxide crystals by x-ray diffraction curve.

G. SARSENB AY ET AL.

220

Figure 6 aluminum oxide crystal by x-ray diffraction curve.

3. Summary

By research: summary out KOH solution processing Turgay

clay process and sodium aluminate solution digested out alu-

mina concentrate process best reaction conditions ; Optimizatio n

conditions of dissolving sodium aluminate solution desilication;

crystalline solid phase components as Na2O·Al2O3·6H2O so-

dium hydroaluminate crystals; preparation meeting the criteria

of production alumina solid products; study for the first time

out complex alkaline processing method of clay application of

KOH solution.

REFERENCES

[1] Kirpal, G.R., (1970) Kaolin clay and allophone from Northern

Kazakhstan / / Clay and mineralogy of their properties and prac-

tica l value. Moscow, pp.226-228.

[2] Suleyeva N.G., Sherban S.A., Tazhibayeva S.H., Romanov L.G.,

(1982) Study of solubility of ash components of Ekibastuz coal

in alkaline ∥ comprehensive utilization of mineral raw mate-

rials. № 3, pp. 62-66.

[3] Bukebayev E.T., Nurmagambetov H.N. Investigation of the

process of kaolin clay desili cation ∥ comprehensive utilization

of mineral raw materials, 1982, № 8, pp.28-31.

[4] Nalimov V.V., Chernova N.A. (1965) Statistical methods of

planning extreme experiments, Moscow, p. 330.

[5] Ni L.P. , Raizman V. L., (1988) Combin ed methods of p rocessing

sub-standard aluminum raw material, Alma-Ata, p. 254.