SU1138190A1 - Method of coal and graphite flotation - Google Patents

Abstract

METHOD OF FLOTATION OF COAL AND GRAPHITE, including preliminary pulping, conditioning with a reagent mixture. tractor kerosene and foaming agent, characterized in that, in order to increase the extraction of useful components in the concentrate, improve the flotation process selectivity and reduce the flotation reagent consumption, alkyl derivatives of 1,3-dioxa-2-silicyclohexane of the general formula K R ( R A TR w RR with where R is alkyl,

Description

The invention relates to the beneficiation of minerals by the method of: flotation and can be used in beneficiation plants in the enrichment of coal and graphite.

The flotation of coal and graphite is carried out using chemical compounds with different polar atoms, functional groups, or use technical products containing in the bulk chemical composition, in an overwhelming amount, one or another polar chemical compounds ij.

Iaaesten method of flotation of hydrophobic minerals, including preliminary pulping, conditioning with a reagent mixture of tractor kerosene with bottom residues from the production of butyl alcohol 2.

However, this method of flotation of hydrophobic minerals is characterized by a high consumption of reagents and low productivity of flotation machines.

The known method of coal flotation, inclusive pre-pulping and conditioning with reagents - alkyl derivatives of 1,3-dioxane. h

Despite the high efficiency, the consumption of 1,3-dioxanes is 0.6–0.7 kg / t, and the flotation selectivity is not high enough. The ash content of the concentrate is 9.5–10.5% ((the ash content of the initial flotation feed 21, 5 - 24.2%).

The closest to the proposed method is the flotation of coal and rpa phi, including preliminary pulping, conditioning with a reagent mixture of tractor kerosene and frother, and T-66 4 is used as frother.

The disadvantages of the known method of coal flotation, despite their relatively high efficiency, are the increased consumption of reagents and the reduced selectivity of coal flotation.

The purpose of the invention is to increase the extraction of useful components in the concentrate, to improve the selectivity of the flotation process and to reduce the consumption of flotation reagents.

The delivered target is achieved in that, according to the method of flotation, coal and. graphite, including Pre-pulping, conditioning with a reagent mixture of tractor kerosene and foaming agent, alkyl derivatives of 1,3-dioxa-2-silocyclohexanes of the general formula are introduced into the conditioning as blowing agent;

JR R

W

%

R r

where R is Cj-0-alkyl.

Alkylproducts of 1, 3-dioxa-2-silicyclohexane and its analogues, used in organic chemistry to protect dols, are obtained by reacting diols with chlorosilane-alkoxysilanes and polyorganosiloxanes. Alkyl derivatives of I, 3-diox-2-silacyclohexane as a reagent for the flotation of minerals are not used.

Physical and chemical contacts:

Bp from 135-178

Density 0.9369-0.9759

Coefficient

refraction, 3980-1,4260

The chemical compounds 1,3-dioxa-2-silacyclohexanes in the flotation process act as a blowing agent.

Like other heteropolar chemical compounds used in coal flotation, 1,3-dioxa-2-silacyclohexanes promote the formation of smaller air bubbles, i.e. increase air dispersion; they prevent the fusion of individual bubbles and the formation of larger bubbles from them; increase the strength of the bubbles and the stability of the foam formed as a result of the rise of mineralized bubbles on the pulp surface; influence the collective action of the reagents on fixing them on the minerals, reducing the consumption of the collector and increasing the extraction of useful components in the froth product.

1,3-dioxa-2-silacyclohexanes are more effective foaming agents than T-66 c. due to the fact that they have an increased foaming capacity. The height of the two-phase foam is 1.5 times higher compared with the T-66 table. H). The presence of two oxygen atoms in the molecule of 1,3-dioxa-2-cilocyclohexane allows them to be actively adsorbed on the reaction center of the coal surface due to H-bonds (on the positive portions of the coal surface. The branched network of hydrocarbon radicals allows to significantly increase the hydrophobization of the surface and to improve the adsorption of the main collector reagent on the coal surface. This ultimately leads to a significant reduction in the consumption of the reagent mixture and an increase in the extraction of combustible mass in the concentrate. The properties of 1,3-dioxa-2-silacyclohexanes are confirmed with laboratory experiments on the flotation of coal fines when used individually as reagents. The use of 2,2,4-trimethyl-1,3-dioxa-2-silacyclohexane instead of 2, 2 , 4-trimethyl-1, 3-dioxane makes it possible to increase the extraction of combustible mass into concentrate by 8–9% with a simultaneous decrease in reagent consumption by a factor of 3 (Table 1). Increased hydrophobization of the surface upon adsorption on 1,3-dio angle ca-2-silacyclohexanes are explained by the U-electron structure and stereochemistry of the pea molecule ENTT. Studying the stereochemistry of molecules with the use of the CN DO / 2 method makes it possible to establish that the 1,3-diox-2-silocycloga molecules of the strands are significantly different in structure from the 1,3-dioxanes, for example, the Si-O bond length 1.5 times the bond length in the 1,3-dioxan molecule and is 1.9510 m and 1.3910 m, respectively. This leads to an increase in the total area of the cycle by decreasing the О.V t angle by 19 compared to the С „0 С l in 3-dioxanes and by increasing the angle 0, Si 0. In addition, the length of the Si-CH bond increases compared to C, - CH from 1.51 10- ° to 1.9235 "10 m, and the Si-H bond length is about 1.5 times as compared to the C-H bond. An increase in the cycle area of the molecule and the length of the bonds, silicon with a methyl group and hydrogen, in the case of the adsorption of molecules 1, 3-dioxa-2-silicyclohexano B, leads to an increase in its hydrophobization, and hence flotation of coal particles. Molecules of 1,3-dioxa-2-silacyclohexanes have an increased dipole moment in comparison with 1,3-dioxanes, which increases the energy of their adsorption on the coal surface. Due to the fact that T-66 mainly contains compounds of the dioxane and pyran cycle, their adsorption and hydrophobization ability is lower than 1,3-dioxa-2-silacyclohexanes, which ultimately C 1 likens the floatability of the coals when using T-66 as a reagent foaming agent. Thus, 1,3-dioxa-2-silacyclohexanes have a greater dispersing and hydrophobization ability compared to T-66, which ultimately leads to increased floatability of coal fines and product. The method is carried out as follows. The initial coal sample is mixed with water, conditioned with flotation agents and floated. Example. To carry out the process, we take a portion of coal or graphite, for example, 100 g, mix it with water in a laboratory machine of the type Mechanobr with a volume of 4 4 0.75 l. within 2 min. Then, a portion of the flotation reagent of tractor kerosene with alkyl derivatives of 1,3-dioxa-2-silacyclohexane, for example, tractor kerosene with 2,2,4-trimethyl-1, 3-dioxa-2-silacyclohexane, is introduced into the conditioning in a ratio of 95: 5. After contacting the coal with the reagent, air is supplied to the flotation pulp for 1 min and flotation takes place for 1 min. The air supply to the pulp is stopped and the next portion of the reagent falls, followed by contacting it with coal for 1 minute. After contact of the coal sample with the reagent, air is again fed to the pulp and the second concentrate is removed.

five

The known method of coal flotation includes preliminary pulping and conditioning with tractor kerosene and in a ratio of 99: 1 to 95: 5. The study found that the use of alkyl derivatives of 1,3-diox-silacyclohexanes as a collector mixed with tractor kerosene (in relation to J; 99) makes it possible to increase the extraction of the combustible mass into concentrate by 3, 7% compared to using a mixture of T-66 with tractor kerosene with a simultaneous decrease in the consumption of a mixture of reagents by 2-3 times and improving the selectivity of the process of flotation of the angle. The ash content of the concentrate in the case of using alkyl derivatives of 1,3-dioxa-2-silacyclohexanes as a blowing agent decreases by 6-0.9%. The efficiency ratio rises from 0.767–0.779 to 0.797–0.808 (Table 2).

An increase in the T-66 reagent mixture from 1 to 5% makes it possible to somewhat improve the coal floatability.

By reducing the consumption of the T-66 reagent mixture with tractor kerosene (5:95) from 0.86 - 1.29 to 0.68 kg / t, the extractable combustible mass in-concentrate increases to 88.8 - 89, -6% . However, the use of a mixture of alkyl derivatives of 1, 3-dioxa-2-silacyclohexanes with tractor kerosene in such a ratio makes it possible to increase: extraction of the combustible mass to concentrate to 92.1 - 93.7% while reducing the consumption of the reagent mixture from 0.68 to 0.368 ( Table 2).

The ash content of the flotation concentrate in the case of using the proposed flotation method is reduced by 0. The efficiency ratio rises from 0.754-0.766 to 0.794-0804 (Table 2).

81906

The high efficacy of the alkyl derivatives of 1, 3-diox-2-silacyclohexanes, used as foaming agent, can be explained by 5 high foaming properties.

The results of coal flotation using various technical products as foaming agents are presented in Table. 2 Greagent-collector. - tractor kerosene.

The foaming ability of technical products used as blowing agents is given in Table 3.

5 With the same concentration of pea-. In the case of 2,2,4-trimethyl-1,3-dioxa-2-silacyclohexane, the height of 2-phase foam in water is 1.5 times higher than T-66 (Table 3).

20 in the case of graphite flotation using the proposed flotation method, positive results were also obtained. So, for example, the use of tractor kerosene

(o, 6 kg / t and foaming agent 2,2,5,5 tetramethyl-1, 3-dioxa-2-stolycyclohexane allows to increase carbon production into a concentrate from 94.8 ho of 95.31% compared with As a foaming agent T-66, the consumption of 2,2,5,5-tetrameetch 11, 3-dioxa-2-stolycyclohexane is reduced 1.5 times compared with T-66, B Table 4 shows the results

5 graphite flotation with different reagent modes.

Therefore, the application of the proposed method makes it possible to improve the technological parameters of floatation of coal and; graphite by increasing the extraction of the useful component in the concentrate, improving the selectivity of the flotation process and 5. reducing the consumption of flotation reagents. Coal flotation using cyclic acetals

381908

T a b l i. c a

99: 1 0.860.80.2 19.8 100.0 1.290J6.7 23.3 100.0 95: 5 0.680 81.3 18.7 100.0 0.680 80.0 20.0 100.0 2 2, 2,4-three99: 1 0.460 82.5 17.5 100.0 methyl-1,3 diox-295: 5 0.368 83.6 16.4 100.0 cicyllohexane 99: 1 0.460 81.2.ia.S 100, 0 95: 5 0.368 82.7 17.3 100.0 3 2.2-diethyl-5.595: V 0.400 78, .6 21.4 100.0 dimethyl-I, 395: 5 0.39281.818.2 100 , 0. dioxa 2-silocyclohexane

; Table 2 5.3 47.7 13, 779 7.5 52.6 18.086.50.767 5.7 48.7 13.788.80.766 8.2 57.2 18.089.60.754 4.7 56.0 13.7 91 , 1 0,808 4,9 58,4 13,792,10,804 6,9 66,0 18,092,20,797 7,1 70,1 18,093,70,794 6,4 60,6 18UO89,70,804 7,067,4 18,092,80,795

2,2,4-grimethylT-66 1,3 dioxa-2 sylacyclohexane

The height of the two-phase foam, mm, at a concentration of, mg / l 11.5 23.0, 46.0 92 17.5 35 70

40 100 130 200

160 190 205

60

Green oil

15

20 40 135

Table4 140 16.5 33.0 66 132

Claims (1)

METHOD OF COAL AND GRAPHITE FLOTATION, including preliminary pulping, conditioning with a reagent mixture. tractor kerosene and blowing agent, characterized in that, in order to increase the extraction of useful components in the concentrate, to improve the selectivity of the flotation process and to reduce the consumption of flotation reagents, alkyl derivatives are introduced into conditioning as a blowing agent 1, 3-dioxa-2-silacyclohexane of the general formula where R is alkyl, C. 06ΐ8ει I ^{, B} Tis>