SU1549590A1 - Method of jigging mineral deposits - Google Patents

Abstract

The invention relates to the enrichment of minerals and can be used in the mining industry. The goal is to increase the extraction of the useful component. The method of depositing includes the introduction of material into a liquid-energy carrier, the excitation of oscillations in a liquid-energy carrier by various frequencies, the separation of material by density, the withdrawal of separation products. The magnitude of the vibration amplitudes is determined by the formulas A ₁ = K ₁ A (K ₂ +1), A ₂ = K ₂ A (K ₂ -1), and the frequency difference is / Ω ₂ -Ω ₁ / = K ₃ (Q _beats / H), where Q _beats is the specific volumetric feed capacity, m ^3. s ^-1. m ^-2

H - the height of the layer of enriched material, m

A - optimal oscillation amplitude for enriched material, m

K ₁ and K ₂ - coefficients depending on the content of the heavy fraction in the diet, equal, respectively, 0.35-0.5 and 1.5-1.8

K ₃ is a coefficient depending on the contrast of densities of the products being divided, equal to 0.8-1.2. The method allows to obtain an oscillating mode with periodic oscillations of the amplitude. The amplitude oscillation period is close to the average residence time of the material in the sediment machine. In the region of minimum amplitudes, the material can be stratified effectively. In the region of maximum amplitudes, the formed heavy layer is effectively unloaded. The average throughput at the same time increases. 1 dw., 5 tab.

Description

The invention relates to the enrichment of minerals, and specifically to methods of depositing, and can be used in the mining industry.

The aim of the invention is to increase the recovery of the useful component.

The method of depositing minerals involves introducing material into a liquid-energy carrier, excitation of different frequencies in a liquid-energy carrier, stratification of the material by density, output of separation products, the magnitude of the amplitudes of oscillations being determined by the formulas:

(one)

(k; - o, (2)

and the frequency difference is

Q ----,

A, K, a (K2 + 1),

Ag K2a

.l k,

(3)

where A 4 and Ae - amplitude of oscillation, m; 6J, and Qu - oscillation frequencies, Hz;

it

- specific volumetric nutrition performance,.

h - the height of the layer of enriched material, m;

a is the optimum vibration amplitude for the enriched material, m;

The maximum amplitudes are intensely unloaded through the bed of the formed layer of the heavy product. Thereafter, the amplitude is reduced, and the cycle is reversed.

Thus, the capacity of an artificial bed is not constant, as when jigging with a constant

K ,,, Kr are the coefficients depending on the JQ amplitude (plot 5), and

with period T (Figure 6). The performance of the machine on the finished product is expressed by the area under the schedule, this increases.

from the content of the heavy fraction in the diet, equal respectively to 0.35-0.5 and 1.5-1.8; K is a coefficient depending on the contrast of densities of the products being divided, equal to 0.8-1.2. The drawing shows graphs: components of oscillations 1 and 2, total oscillations 3, the envelope of the total oscillations A and the dependence of the throughput on time when using the method according to prototype 5 and using this technical solution 6.

Fluid oscillation in this method is the sum of two components (graphs 1 and 2). Moreover, the frequency difference of these components is very small compared to their frequency. So, for example, with a specific performance Q Ca 8 "10 T / M H, layer height 200 mm, the frequency difference (OE2-CO,), determined by the formula (3), will be 0.005-0.006 Hz, while the oscillation frequency is usually found within 1-3 Hz.

The addition of oscillations with different, but fairly close frequencies, leads to the occurrence of oscillations at which the amplitude of the total oscillations is slow, with a frequency (W2 - oOt), oscillates between the minimum and maximum values (plot 3).

During one cycle of amplitude oscillation, the precipitation process proceeds as follows.

At the minimum amplitude of oscillations, an enrichment material accumulates on a layer of an artificial bed. The process of stratification of the enriched material is proceeding according to density: unloading through an artificial bed proceeds not intensively. The oscillation amplitude gradually increases, while the process of stratification by density slows down and the unloading is intensified. When reaching maxi

The maximum amplitudes are intensely unloaded through the bed of the formed layer of the heavy product. Then the amplitude decreases and the cycle repeats.

Thus, the capacity of an artificial bed is not constant, as when jigging with a constant

Q amplitude (plot 5), and fluctuates

five

0

five

Q

Q

with period T (Figure 6). The performance of the machine for the finished product, expressed as the area under the schedule, increases.

Thus, due to the use of two frequencies for excitation of fluid-energy carrier, the amplitudes of which are calculated by formulas (1), (2), and the frequency difference by formula (3), an oscillating mode characterized by periodic oscillations of amplitude can be obtained in a jigging machine , the period of which is close to the average residence time of the material in the jigging machine. In this case, in the minimum amplitude area (region I), the material can be effectively stratified to form a layer to be unloaded through an artificial bed.

In the region of maximum amplitudes (region II), the resulting heavy layer is effectively unloaded. At the same time, the average throughput of the artificial bed increases, which leads to a decrease in the loss of the conditioned heavy fraction in the discharge of the machine, therefore, the extraction of the useful component increases.

Experiments were conducted to determine the optimal values of the coefficients K4, K2, K3 included in the calculation formulas.

Oxide concentrate grade II with soy holding 37,7% Mn enriched at

size (-5) mm on the jigging machine OMRU-2.1.

The known optimum amplitude for this material was mm.

The optimal frequency of pulsations was 2 Hz.

The jigging machine was equipped with dual pulsators, which made it possible to obtain, during jigging, total oscillations, providing a superposition of two components.

Estimated specific machine capacity for power is

five

0

five

Q "2.1-2.5 m / h m2, layer height h 80 mm.

At enrichment, a part of concentrate of grade II was isolated, its part satisfying the condition of grade I (manganese content, 43%), representing the losses of the previous operation.

Two series of experiments were carried out. In the first series, the range of optimal values of the K 2 coefficients at Ke 1, 6Eg – C0, 8 x 1 (T 125 ° C) was determined. The extraction of manganese into chamber product 6 was determined. The results of the experiments are shown in Tables 1–4.

The dependence of the extraction of manganese on the coefficient Kg at Kt 0.2 is given in Table. one.

The dependence of the extraction of manganese on the K4 coefficients at K 0.35 is given in Table. 2

The dependence of the extraction of manganese on the coefficient K at K, 0.5 is given in Table. 3

The dependence of the extraction of manganese on the coefficient K at K 0.75 is given in Table. four.

From the data table. 1-4, it can be seen that the best extraction (Ј 21-23%) was reached at K 0.35-0.5; K2 1.5-1.8. This range of values of K, K is optimal.

In the second series of experiments, the optimum range of values of the coefficient K ,, determining the magnitude of the oscillation period of the amplitude, was determined. optimum values of K4 0.35, "Ј 1.8. The minimum and maximum amplitudes of oscillations in this mode were respectively: Amine 18mm 32 mm. The results of the experiments are given in table. five.

The dependence of the extraction of manganese in the chamber product on the coefficient K is shown in Table. five.

As can be seen from the data table. 5, the optimum Ke value range was 0.8–1.2.

The method is carried out as follows.

Oxide concentrate of II grade with a content of 33.7% Mn is enriched with a particle size (-5 mm) on a jigging machine OMRU-2.4. The data received for calculating the amplitudes and frequencies are as follows: 25 mm; Q 2.3 m3 / h mg; h 80 mm; WITH, 2 Hz.

U 15

495906

The accepted values of the coefficients:

K, 0.42; K 1.65; Ke 1.0.

The calculated amplitudes: A ,, - 28 mm; Ar 7 mm.

Calculated values of the frequency difference ("g. -O), 0.01 Hz

The values of oscillation frequencies: G) (- 2 Hz; С0а 2.01 Hz.

With the enrichment of manganese-containing ores in this way, the extraction of manganese in the concentrate was Ј 23.4%; the quality of the concentrate was 45.2% with a yield of 17.4%.

Claims (1)

Invention Formula The method of depositing minerals, including the introduction of materials into a liquid-energy carrier, the excitation in a liquid-energy carrier of oscillations of various frequencies, the withdrawal of separation products, characterized in that, in order to increase the extraction useful component, the oscillations are excited with amplitudes whose magnitude is determined by the formulas A (K, a (K4 +1), Ae (K5 -1), at frequencies, the difference is Ql To -tfih to, YU de A4 and A2 - amplitude of oscillation, m; Kt, are coefficients depending on the content of the conditioned heavy fraction in the diet and are, respectively, 0.35-0.5 and 1.5-1.8; a - known optimal vibration amplitude for enriched material, m; WITH ,, COH.- oscillation frequency, Hz; K is the coefficient depending on the contrast of the densities of the products to be divided and equal to 0.8 ± 2; Qua, - specific volumetric feed capacity, m. S h - the height of the layer of enriched material, m MI, & g  t