RU2375709C1 - Method of rapid determination of concentration of arsenopyrite, pyrrohtine, pyrite in sulphide ore concentrate - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to extraction of gold and other metals from ore. Composition of arsenopyrite FeAsS, pyrrohtine FeS, pyrite FeS₂ is determined through microprobe analysis. Reference coefficients for arsenopyrite, pyrrohtine, and pyrite are calculated once for the next batch of ore. Reference coefficients for arsenopyrite, pyrrohtine, and pyrite are calculated from given calculated ratios. Concentration of arsenium and iron is determined through X-ray spectral analysis of the concentrate. Concentration of arsenopyrite in the concentrate is calculated by multiplying concentration of arsenium in the concentrate and the calculated reference coefficient. Concentration of iron aresnopyrite in the concentrate is calculated based on concentration of arsenopyrite in the concentrate and concentration of iron in arsenopyrite. Fractional analysis of the concentrate is carried out in a heavy liquid. An express concentrate is obtained. The express-concentrate is dissolved in concentrated hydrochloric acid. The precipitate is separated and weighed. Total concentration of arsenopyrite and pyrite in the express concentrate is calculated from the ratio of weight of the precipitate to the weight of the express concentrate. Total concentration of iron arsenopyrite and pyrite in the concentrate is determined through X-ray spectral analysis of the precipitate of the express concentrate. Concentration of pyrrohtine in the concentrate is calculated from formula: w[FeS]_concentrate=w[Fe]_concentrate-w[FeAsS+FeS₂]_{express concentrate}×w[Fe]_(FeAsS+FeS2))R_FeS, where: w[FeS]_concentrate - is concentration of pyrrohtine in the concentrate, %; w[Fe]_concentrate - is concentration of iron in the concentrate, %; w[FeAsS+FeS₂]_{express concentrate} - is total concentration of arsenopyrite and pyrite in the express concentrate d.e.; w[Fe]_(FeAsS+FeS2) - is total concentration of iron arsenopyrite and pyrite in the concentrate, %; R_Fes - is reference coefficient of pyrrohtine. Concentration of pyrite in the concentrate is calculated using formula: w[FeS]_concentrate=w[FeAsS+FeS₂]_{express concentrate}×w[Fe](FeAsS+FeS₂)-w[Fe](FeAsS)×R_FeS2, where: w[FeS₂]_concentrate - is mass ratio of pyrite in the concentrate, %; w[FeAsS+FeS₂]_{express concentrate} - is total concentration of arsenopyrite and pyrite in the express concentrate, d.e.; w[Fe]_(FeAsS+FeS2) - is total concentration of iron arsenopyrite and pyrite in the concentrate, %; w[Fe]_FeAsS - is concentration of iron arsenopyrite in the concentrate, %; R_FeS2 - is reference coefficient of pyrite.

EFFECT: increased accuracy and information content of analysis.

2 tbl

Description

The invention relates to methods for extracting metals from ores. It can be used in extraction or processing plants, in pilot plants for the rapid determination of the concentration of the triad of sulfide minerals - arsenopyrite, pyrrhotite, pyrite - in the initial ores or intermediate products of the process, mainly in flotation or gravity concentrates of primary sulfide gold-bearing ores. By technological properties, such ores are classified as refractory. The ore-forming metal, in particular gold, is in the form of occluded finely disseminated, associated inclusions and intergrowths with sulfide minerals.

A known method for determining the composition of ores and intermediate technological products for the extraction of metals, including concentrate, is quantitative mineralogical analysis.

An analogue of the invention is a mineralogical analysis of the composition of minerals and minerals [Jones MP Applied Mineralogy. M .: Nedra, 1991, p.202-205]. The method consists in the physicochemical determination of the qualitative and quantitative composition of minerals and minerals using a scanning electron microscope.

A disadvantage of the known method of mineralogical analysis is the determination time of up to 70-80 hours and, therefore, the inefficiency of use for operational control of technological processes.

The prototype of the invention is a method of quantitative chemical analysis to determine the amount of iron in ores and products of their processing [Filippova N.A. Phase analysis of ores and products of their processing. M .: Chemistry, 1975, p. 244, 243].

The method of quantitative chemical analysis includes the chemical separation of sulfide minerals of iron and determining the amount of iron in them. The sample is dissolved in hydrochloric acid when boiled without air. A solution containing pyrrhotite is separated from a solid residue containing arsenopyrite (complex, sulfide) and pyrite (simple sulfide). Determine the amount of iron contained in pyrrhotite. The amount of iron contained in arsenopyrite and pyrite is determined.

The disadvantage of the prototype is the limitation of technological capabilities due to the determination of the total amount of iron in arsenopyrite and pyrite. The disadvantage of the prototype is also the lack of accuracy. The studied ores together with ore sulfide minerals contain up to 50% or more non-metallic minerals and impurity minerals, the presence of which in the analysis reduces the accuracy of the results.

The objective of the invention is the expansion of technological capabilities, improving the accuracy and efficiency of the method of rapid analysis of the concentrations of arsenopyrite, pyrrhotite and pyrite.

The problem is solved in that in the method for the rapid analysis of the concentrations of arsenopyrite, pyrrhotite and pyrite in a sulfide ore concentrate, including the chemical separation of iron sulfides by hydrochloric acid, according to the invention, the average elemental composition in each of the triad of sulfide minerals is determined - arsenopyrite, pyrrhotite, pyrite - X-ray - spectral (RS) electron probe analysis (hereinafter referred to as microprobe analysis), and then the analytical part of the express analysis is performed.

Microprobe analysis of sample sections of sulfide minerals is performed. Get the average elemental composition, i.e. the concentration of each element in the mineral is w ^RS , each of the triad of sulfide minerals is arsenopyrite FeAsS, pyrrhotite Fe _n S _n-1 , pyrite FeS ₂ .

The reference coefficient of each of the triad of sulfide minerals is calculated. The reference coefficient of the mineral is a conditional value. It is the ratio of the sum of the concentrations (mass fractions) of mineral elements to the concentration (mass fraction) of the reference, i.e. exponential (marker) element of this mineral. The arsenopyrite reference element is arsenic, as in the triad of sulfide minerals, it is found only in arsenopyrite. For pyrrhotite and pyrite, the reference element is iron.

The reference coefficient of arsenopyrite is calculated by the formula:

Where

R _FeAsS - reference coefficient of arsenopyrite;

w ^RS [As] _FeAsS — arsenic concentration in arsenopyrite,%;

w ^RS [Fe] _FeAsS — iron concentration in arsenopyrite,%;

w ^RS [S] _FeAsS — sulfur concentration in arsenopyrite,%.

The reference pyrrhotite coefficient is calculated by the formula (hereinafter, pyrrhotite is designated by the chemical formula FeS):

Where

R _FeS - reference coefficient of pyrrhotite;

w _RS [Fe] _FeS — iron concentration in pyrrhotite,%;

w _RS [S] _FeS — sulfur concentration in pyrrhotite,%.

The reference coefficient of pyrite is calculated by the formula:

Where

R _FeS2 - reference coefficient of pyrite;

- концентрация железа в пирите, %;

- iron concentration in pyrite,%;

- концентрация серы в пирите, %.

- sulfur concentration in pyrite,%.

A quantitative analysis of the concentrate is carried out, the concentration of arsenic and the concentration of iron in the concentrate are determined.

The concentration of arsenopyrite in the concentrate is calculated by the formula:

Where

w [FeAsS] _Concentrate - concentration of arsenopyrite in the concentrate,%;

w [As] _Concentrate - arsenic concentration in the concentrate,%;

R _FeAsS - reference coefficient of arsenopyrite.

The concentration of iron arsenopyrite (attributable to arsenopyrite) in the concentrate is calculated by the formula:

Where

w [Fe] _FeAsS — iron concentration of arsenopyrite in concentrate,%;

w [FeAsS] _Concentrate - concentration of arsenopyrite in the concentrate,%;

w ^RS [Fe] _FeAsS — iron concentration in arsenopyrite,%;

100 - total concentration of arsenopyrite elements,%.

Conduct fractional analysis of the concentrate in a heavy liquid. Two fractions are obtained - ore (heavy) and non-metallic (light). The ore fraction consists of minerals containing iron - arsenopyrite FeAsS, pyrrhotite FeS, pyrite FeS ₂ , antimonite Sb ₂ S ₃ . The non-metallic fraction consists of minerals that do not contain iron - antimony sulfosalts, quartz SiO ₂ , calcite CaCO ₃ , muscovite KA1 [(OH, F) ₂ | AlSi ₃ O ₁₀ ] and impurity minerals. Further, the ore fraction is designated by the term "express concentrate" or "E-Concentrate".

Antimonite Sb ₂ S ₃ is an iron-free mineral and is present in sulfide ore concentrate at a concentration of up to 6%. In the subsequent stages of the express analysis, the antimonite content in the express concentrate is not taken into account and proceed from the assumption that the express concentrate consists of arsenopyrite FeAsS, pyrrhotite FeS, pyrite FeS ₂ .

Pyrrhotite is separated from arsenopyrite and pyrite. Dissolve the sample of the express concentrate in concentrated hydrochloric acid and separate the liquid and solid phases. Pyrrhotite dissolves in hydrochloric acid, arsenopyrite and pyrite remain in the sediment.

The weight of the insoluble precipitate of the express concentrate consisting of arsenopyrite and pyrite is determined.

The total concentration of arsenopyrite and pyrite in the express concentrate is calculated by the formula:

Where

w [FeAsS + FeS ₂ ] _{E-Concentrate} - the total concentration of arsenopyrite and pyrite in the express concentrate, e;

P [FeAsS + FeS ₂ ] _{E-Concentrate} - weight of insoluble precipitate of the express concentrate, g;

P [E-Concentrate] - weight of express concentrate, g.

A quantitative analysis of the insoluble precipitate of the express concentrate is performed, the total concentration of iron arsenopyrite and pyrite (attributable to arsenopyrite and pyrite) in the concentrate is determined.

The concentration of pyrrhotite in the concentrate is calculated by the formula:

Where

w [FeS] _Concentrate - concentration of pyrrhotite in the concentrate,%;

w [Fe] _Concentrate - iron concentration in the concentrate,%;

w [FeAsS + FeS ₂ ] _{E-Concentrate} - the total concentration of arsenopyrite and pyrite in the express concentrate, e;

- суммарная концентрация железа арсенопирита и пирита в концентрате, %;

- total iron concentration of arsenopyrite and pyrite in concentrate,%;

R _FeS - reference coefficient of pyrrhotite.

The concentration of pyrite in the concentrate is calculated by the formula:

Where

w [FeS ₂ ] _Concentrate - mass fraction of pyrite in the concentrate,%;

w [FeAsS + FeS ₂ ] _{E-Concentrate} - the total concentration of arsenopyrite and pyrite in the express concentrate, e;

- суммарная концентрация железа арсенопирита и пирита в концентрате, %;

- total iron concentration of arsenopyrite and pyrite in concentrate,%;

w [Fe] _FeAsS — iron concentration of arsenopyrite in concentrate,%;

R _FeS2 - reference coefficient of pyrite.

It is possible to carry out fractional analysis after microprobe analysis.

The technical result of the invention is the expansion of technological capabilities and increase the efficiency of the method of rapid analysis in consequence,

firstly, calculating the concentrations of the triad of sulfide minerals by measuring the concentrations of reference elements (arsenic and iron), as well as using conditional reference coefficients of each triad of sulfide minerals;

secondly, deductively-inductive measurement and calculation in stages at four hierarchical chemical levels - mineral (i.e. substances), concentrate, express concentrate, insoluble precipitate of express concentrate;

The technical result is also to increase the accuracy of the method due to the possibility of direct study of the express concentrate, excluding non-metallic minerals, minerals not containing iron, and minerals-impurities.

The method of express analysis of the concentration of the triad of sulfide minerals of a concentrate, initial ore or other intermediate technological product of sulfide ore helps to increase the degree of extraction of useful ore-forming metal, for example, gold or other noble or non-ferrous metal from refractory ores by monitoring and controlling the quality of the technological process, first the turn is by adjusting the pH of the medium and loading modes depending on the concentration of the triad of sulfide minerals.

The method of rapid analysis is as follows.

The assumption is made that the content of antimonite Sb ₂ S ₃ in the concentrate is excluded from the calculations.

The concentration of substances and elements is a mass fraction, expressed as a percentage, the so-called weight percent.

1. A microprobe analysis of sample sections of each of the minerals is carried out - arsenopyrite FeAsS, pyrrhotite Fe _n S _n-1 , pyrite FeS ₂ . Use well-known methods of mathematical statistics. Get the average elemental composition of arsenopyrite, pyrrhotite, pyrite.

2. Calculate benchmark coefficients for each of the triad of sulfide minerals - arsenopyrite, pyrrhotite, pyrite.

Reference arsenopyrite coefficient:

Where

R _FeAsS - reference coefficient of arsenopyrite;

w ^RS [As] _FeAsS — arsenic concentration in arsenopyrite,%;

w ^RS [Fe] _FeAsS — iron concentration in arsenopyrite,%;

w ^RS [S] _FeAsS — sulfur concentration in arsenopyrite,%.

Reference pyrrhotite coefficient:

Where

R _FeS - reference coefficient of pyrrhotite;

w ^RS [Fe] _FeS — iron concentration in pyrrhotite,%;

w ^RS [S] _FeS — sulfur concentration in pyrrhotite,%.

Reference pyrite coefficient:

Where

- реперный коэффициент пирита;

- reference pyrite coefficient;

- концентрация железа в пирите, %;

- iron concentration in pyrite,%;

- концентрация серы в пирите, %.

- sulfur concentration in pyrite,%.

Microprobe analysis and calculation of benchmark coefficients of each of the triad of sulfide minerals is carried out once for the next batch of ore.

The further stages of the express analysis of the current batch of ore are carried out online, for example, once or several times per shift daily. For each ore batch, benchmark coefficients are separately calculated.

3. Perform a quantitative analysis of a sample of the concentrate using one of the known methods, for example, spectral, X-ray spectral or chemical. Determine the concentration of arsenic w [As] _Concentrate and the concentration of iron

w [Fe] _Concentrate in concentrate.

4. Calculate the concentration of arsenopyrite in the concentrate

Where:

w [FeAsS] _Concentrate - concentration of arsenopyrite in the concentrate,%;

w [As] _Concentrate - the concentration of arsenic in the concentrate,%;

R _FeAsS - reference coefficient of arsenopyrite.

5. The concentration of iron arsenopyrite in the concentrate is calculated.

Where

w [Fe] _FeAsS — iron concentration of arsenopyrite in concentrate,%;

w [FeAsS] _Concentrate - concentration of arsenopyrite in the concentrate,%; w ^RS [Fe] _FeAsS — iron concentration in arsenopyrite,%;

100 - total concentration of arsenopyrite elements,%.

6. Conduct fractional analysis of a sample of sulfide ore concentrate. Use any of the known heavy liquids. Get express concentrate.

7. Separate pyrrhotite from arsenopyrite and pyrite. Concentrated hydrochloric acid is added to the sample-concentrate sample at a volume ratio of 1:50, boiled for 30 minutes without air. The resulting suspension is filtered, the insoluble precipitate is separated. The precipitate is washed, dried. The liquid phase contains dissolved iron sulfide - pyrrhotite. The precipitate contains iron arsenosulfide insoluble in hydrochloric acid - arsenopyrite and iron disulfide - pyrite.

8. Weigh the insoluble precipitate of the express concentrate and obtain its weight.

9. Calculate the total concentration of arsenopyrite and pyrite in the express concentrate.

Where

w [FeAsS + FeS ₂ ] _{E-Concentrate} - the total concentration of arsenopyrite and pyrite in the express concentrate, e;

P [FeAsS + FeS ₂ ] _{E-Concentrate} - weight of insoluble precipitate of the express concentrate, g;

P [E-Concentrate] - weight of express concentrate, g.

10. A quantitative analysis of the insoluble precipitate of the express concentrate is also carried out by one of the known methods, for example, spectral, X-ray spectral or chemical. The total iron concentration of arsenopyrite and pyrite w [Fe] (FeAsS + FeS ₂ ) in the concentrate is obtained.

11. Calculate the concentration of pyrrhotite in the concentrate

Where:

w [FeS] _Concentrate - concentration of pyrrhotite in the concentrate,%;

w [Fe] _Concentrate - iron concentration in the concentrate,%;

w [FeAsS + FeS ₂ ] _{E-Concentrate} - the total concentration of arsenopyrite and pyrite in the express concentrate, e;

- суммарная концентрация железа арсенопирита и пирита в концентрате, %;

- total iron concentration of arsenopyrite and pyrite in concentrate,%;

R _FeS - reference coefficient of pyrrhotite.

12. Calculate the concentration of pyrite in the concentrate.

Where

w [FeS ₂ ] _Concentrate - concentration of pyrite in the concentrate,%;

w [FeAsS + FeS ₂ ] _{E-Concentrate} - the total concentration of arsenopyrite and pyrite in the express concentrate, e;

- суммарная концентрация железа арсенопирита и пирита в концентрате, %;

- total iron concentration of arsenopyrite and pyrite in concentrate,%;

w [Fe] _FeAsS — iron concentration of arsenopyrite in concentrate,%;

R _FeS2 - repetition coefficient of pyrite.

Options for performing an express analysis, for example, of an initial ore, flotation or gravity concentrate, bio-cake or other intermediate product of a technological process for the enrichment or extraction of noble or non-ferrous metals, as well as other valuable elements, are possible.

Example.

The method of express analysis of the concentrations of arsenopyrite, pyrrhotite and pyrite was performed at the Olimpiadinsky GOK gold recovery plant according to the BIONORD® technology regulation, based on the flotation-sorption method for gold extraction, and including biooxidation of flotation concentrate using the association of microorganisms Sulfobacillus olympiadicus ferroplopplopromidoproplopromidoproplopromis ferroploplopromidoproplospromid ferroploptillopromidophysopromidophysopromidophysopromidoptilum ferro and microorganisms. The rapid analysis of flotation concentrate before the biooxidation operation was performed in the following order:

1. Microprobe analysis of polished sections of sulfide minerals: arsenopyrite, pyrrhotite and pyrite. Performed on an EVO H50 scanning electron microscope (Karl Zeiss) with an Everhardt Thornly secondary electron detector and a 4Q-BSD reflected electron detector. The electron microscope is equipped with an INCA Energy (Oxford Instruments) energy dispersive microanalysis system with a computer interface based on the Windows operating system. The results of the microprobe analysis are presented in table 1.

Table 1 The elemental composition of sulfide minerals of flotation concentrate Sulphide mineral Chemical formula The concentration of elements in minerals,% w ^RS [Fe] w ^RS [As] w ^RS [S] Arsenopyrite Feass 35.0 41.9 23.1 Pyrrhotite Fe _n S _n-1 59.3 0 40.7 Pyrites FeS ₂ 46.6 0 53,4

2. Calculation of benchmark coefficients.

Arsenopyrite benchmark

Reference pyrrhotite coefficient

Reference pyrite coefficient

3. X-ray fluorescence quantitative analysis of flotation concentrate. Performed on an Axios X-ray fluorescence analyzer spectrometer.

The concentration of arsenic in the flotation concentrate w [As] _Concentrate = 7.65%.

The concentration of iron in the flotation concentrate w [Fe] _Concentrate = 32.70%.

4. Calculation of the concentration of arsenopyrite in flotation concentrate.

W [FeAsS] _Concentrate = W [As] _Concentrate × R _FeAsS = 7.65% × 2.39 = 18.28%.

5. Calculation of iron concentration of arsenopyrite in flotation concentrate.

6. Fractional analysis of flotation concentrate, preparation of express concentrate (ore fraction of flotation concentrate). Tribromosomethane methane (bromoform) CHBr _{3 was} used as a heavy liquid.

7. Dissolution in hydrochloric acid. 250 ml of concentrated hydrochloric acid HCl are added to a sample-sample of 5 g express concentrate, boiled without air for 30 minutes. Add 250 ml of water at a temperature of 70-80 °. Filtered. The insoluble precipitate is washed on the filter with water at a temperature of 70-80 °. Then, washed on the filter with a 1% solution of hydrochloric acid with a volume of 750 ml. Dried in an oven at a temperature of 100-105 ° C until the weight stabilizes.

8. Weighing insoluble precipitate express concentrate on a laboratory balance.

P [FeAsS + FeS ₂ ] _{E-Concentrate} = 2.51 g.

9. Calculation of the total concentration of arsenopyrite and pyrite in express concentrate

10. X-ray fluorescence quantitative analysis of insoluble precipitate express concentrate, determination of iron concentration. Performed on an Axios X-ray fluorescence analyzer spectrometer. The total iron concentration of arsenopyrite and pyrite in the concentrate is measured.

w [Fe] (FeAsS + FeS ₂ ) = 23.20%.

11. Calculation of the concentration of pyrrhotite in the flotation concentrate.

12. Calculation of the concentration of pyrite in the flotation concentrate.

The results of the rapid analysis of the concentrations of arsenopyrite, pyrrhotite, pyrite flotation concentrate of the Olympiad GOK are presented in table 2.

table 2 - The concentration of sulfide minerals in the flotation concentrate of the biooxidation department of the Olympiadinsky GOK. Sulfide minerals of flotation concentrate. Concentration (mass fractions),% Arsenopyrite 18.28 Pyrrhotite 35.66 Pyrites 11.18 Non-metallic minerals, non-iron minerals, impurity minerals Rest

The total composition of the flotation concentrate includes non-metallic minerals, iron-free minerals, and impurity minerals, the determination of the concentrations of which is not included in the express analysis.

Used standard laboratory glassware and equipment.

The average accuracy of the express analysis is 95-96%. The duration of the express analysis is 30-60 minutes. Express analysis is performed one or several times per shift.

Claims (3)

1. The method of rapid analysis of the concentrations of arsenopyrite, pyrrhotite, pyrite in a sulfide ore concentrate, including the chemical separation of iron sulfides by hydrochloric acid, characterized in that they perform x-ray electron probe analysis of sulfide minerals of the concentrate, determine the concentration of each of the elements contained in arsenopyrite, pyrrhotite, pyrite, then calculate the reference coefficient of arsenopyrite by the formula:

where R _FeAsS - reference coefficient of arsenopyrite;
w ^RS [As] _FeAsS — arsenic concentration in arsenopyrite,%;
w ^RS [Fe] _FeAsS — iron concentration in arsenopyrite,%;
w ^RS [S] _FeAsS — sulfur concentration in arsenopyrite,%,
then calculate the reference coefficient of pyrrhotite according to the formula:

where R _FeS - reference coefficient of pyrrhotite;
w _RS [Fe] _FeS — iron concentration in pyrrhotite,%;
w _RS [S] _FeS - sulfur concentration in pyrrhotite,%, then calculate the reference coefficient of pyrite by the formula:

Where

- reference pyrite coefficient;

- iron concentration in pyrite,%;

- sulfur concentration in pyrite,%,
after that, a quantitative analysis of the concentrate is performed, the concentration of arsenic and the concentration of iron in the concentrate are determined, the concentration of arsenopyrite in the concentrate is calculated by the formula:

where w [FeAsS] _Concentrate is the concentration of arsenopyrite in the concentrate,%;
w [As] _Concentrate - arsenic concentration in the concentrate,%;
R _FeAsS - reference coefficient of arsenopyrite,
then calculate the concentration of iron arsenopyrite in the concentrate according to the formula:

where w [Fe] _FeAsS is the concentration of arsenopyrite iron in the concentrate,%;
w [FeAsS] _Concentrate - concentration of arsenopyrite in the concentrate,%;
w ^RS [Fe] _FeAsS — iron concentration in arsenopyrite,%;
100 - the total concentration of arsenopyrite elements,%, the next step is the fractional analysis of the concentrate in a heavy liquid, the ore fraction is isolated and an express concentrate is obtained, then the express concentrate is dissolved in concentrated hydrochloric acid, the insoluble precipitate is separated off, weighed, and then the total concentration is calculated arsenopyrite and pyrite in express concentrate according to the formula:

where w [FeAsS + FeS ₂ ] _{E-Concentrate} is the total concentration of arsenopyrite and pyrite in the express concentrate, e.e .;
P [FeAsS + FeS ₂ ] _{E-Concentrate} - weight of insoluble precipitate of the express concentrate, g;
P [E-Concentrate] - weight of the express concentrate, g, then a quantitative analysis of the insoluble precipitate of the express concentrate is performed, the total iron concentration of arsenopyrite and pyrite in the concentrate is determined, in conclusion, the concentration of pyrrhotite in the concentrate is calculated by the formula:

where w [FeS] _Concentrate is the concentration of pyrrhotite in the concentrate,%;
w [Fe] _Concentrate - iron concentration in the concentrate,%;
w [FeAsS + FeS ₂ ] _{E-Concentrate} - the total concentration of arsenopyrite and pyrite in the express concentrate, d.e .;

- total iron concentration of arsenopyrite and pyrite in concentrate,%;
R _FeS - reference coefficient of pyrrhotite, in the end, calculate the concentration of pyrite in the concentrate according to the formula:

where w [FeS ₂ ] _Concentrate - mass fraction of pyrite in the concentrate,%;
w [FeAsS + FeS ₂ ] _{E-Concentrate} - the total concentration of arsenopyrite and pyrite in the express concentrate, d.e .;

- total iron concentration of arsenopyrite and pyrite in concentrate,%;
w [Fe] _FeAsS — iron concentration of arsenopyrite in concentrate,%;

- reference coefficient of pyrite. 2. The method of rapid analysis of the concentrations of arsenopyrite, pyrrhotite, pyrite in a sulfide ore concentrate according to claim 1, characterized in that the reference coefficients are calculated separately for each batch of ore. 3. The method of rapid analysis of the concentrations of arsenopyrite, pyrrhotite, pyrite in a sulfide ore concentrate according to claim 1, characterized in that the fractional analysis is performed and an express concentrate is obtained after microprobe analysis or after calculating the concentration of arsenopyrite in the concentrate.