RU2183333C1 - Method for evaluation of diamond content in kimberlite rocks - Google Patents

Abstract

FIELD: exploration and prospecting of mineral resources, in particular, in exploration, quantitative and qualitative evaluation of the diamond content in kimberlite rocks. SUBSTANCE: representative lump samples are taken, microsections are produced, textural-structural features of the rocks are described, quantitative relations of complex oxides of the basic mass of kimberlite rocks: spinelide, perovskite, ilmenite are investigated. Using the microsections, the morphometric parameters of the crystals of spinelides of the basic mass of the rock are calculated, statistics histograms of the mass and quantitative granulometric compositions of spinelides are obtained. On the basis of the obtained histograms the distribution curve of the obtained histograms the distribution curve of the granulometric composition of spinelides in the rock volume is plotted. Referring to the proportion of the 0.044+0.02-mm size of the mass granulometric composition the average value of the diamond content in the kimberlite rock is calculated by an empirical formula. EFFECT: enhanced truth and efficiency of evaluation of the diamond content in kimberlite rocks. 3 cl, 2 dwg, 1 ex

Description

 The invention relates to methods for prospecting and exploration of mineral deposits and can be used in the search, qualitative and quantitative assessment of diamond content of kimberlite rocks.

There are methods for assessing the degree of diamond content of kimberlite rocks, based on the establishment of the typochemistry of paragenetic diamond satellite minerals, indicating the depth of the magma chamber, and indirectly on the potential diamond content of kimberlite rocks [1]. The predominant mineral paragenesis of natural diamonds is ultrabasic, harzburgite-dunite, which includes high-chromium pyrope with a low calcium content (CaO <1.6 + 0.38 Cr ₂ O ₃ at Cr ₂ O ₃ > 5 wt.%) And high-chromium chromite, of considerable interest in the practice of prospecting for diamond deposits by the schlicho-mineralogical method. A significant positive correlation between the contents of such garnets in samples of kimberlite rocks and their diamond content has been proved [2].

 The application of the method based on the analysis of diamond satellite minerals does not answer the question about the preservation of diamond crystals, which is determined by the rate of rise to the surface and the evolution of kimberlite melts.

 The closest in technical essence and the achieved result is a method for evaluating the diamond content of kimberlite rocks, including the selection of ore samples, the manufacture of sections, a description of the texture and structural features of the rocks, the study of the quantitative ratio and typochemistry of complex oxides of the bulk of kimberlite rocks: spinelids, perovskite, ilmenite [3] .

 It was previously established that in kimberlite rocks there are four genetic groups of spinelids that differ in grain morphology, chemical composition and genesis: 1) accessory, rarely rock-forming minerals of xenoliths of deep rocks; 2) discrete grains scattered in the bulk of the kimberlite rock, rarely spliced with other minerals - olivine, pyrope, wedge and orthopyroxene; 3) microphenocrystals of the bulk of the kimberlite rock; 4) reaction grains replacing other minerals, as a rule, of deep origin.

 With the schliemo-mineralogical search method, spinels of the first and second groups are used.

 The method is based on the method of studying the morphometric characteristics of spinelide crystals of the third group, which makes it possible to obtain the full particle size distribution of spinelids with a qualitative and quantitative assessment of the diamond content of kimberlite rock.

 An object of the invention is to increase the reliability and efficiency of assessing the diamond content of kimberlite rocks.

The problem is solved in that in the method for assessing the diamond content of kimberlite rocks, including the selection of ore samples, the manufacture of thin sections, a description of the textural and structural features of the rocks, the study of the quantitative ratio of complex oxides of the bulk of kimberlite rocks: spinelids, perovskite, ilmenite, the morphometric parameters are calculated from thin sections crystals of spinelids of the bulk of the rock, obtain histograms of the mass and quantitative particle size distribution of spinels based on the obtained histograms atm build distribution curve of particle size distribution in the bulk spinels and rock on the relative content class size -0.044 ± 0.02 mm size distribution mass mean value calculated diamondiferous kimberlite rocks by the empirical formula
And _avg = 7.07X ^24.06 / (65.71 ^24.06 + X ^24.06 ),
where A _cf is the average diamond content of kimberlite rock, car / t;
X is the relative content of the size class -0.044 + 0.02 mm of the mass particle size distribution of spinelides of the bulk of kimberlite rocks;
7.07; 24.06; 65.71 - empirical coefficients of the regression equation.

 Advantageously, the dimension calculation of spinel crystals is carried out from a sample of not less than 1000 grains with grouping according to size classes with a step of 2 in a size range of 0.2-0.0 mm.

 With the unimodal nature of the distribution curve of the particle size distribution of spinelids with a maximum at a particle size class of -0.044 + 0.02 mm, diamond content of kimberlite rock is judged, and with a bimodal nature of the distribution curve of the particle size distribution of spinelids with maxima at the particle size classes -0.044 + 0.02 and -0, 20 + 0.15 mm are judged on non-diamondiferous kimberlite rocks.

The invention is illustrated by drawings, which depict:
FIG. 1 - single-mode distribution of spinelids of the bulk of diamondiferous kimberlite rocks with a maximum in the size class of -0.044 + 0.02 mm;
FIG. 2 - bimodal distribution of spinelids in the bulk of non-diamondiferous kimberlite rocks with maxima at particle size classes of -0.044 + 0.02 mm and -0.15 + 0.10 mm.

 In the drawings, the abscissa axis shows the particle size classes of spinelides of the bulk of kimberlite rocks (mm), the ordinate axis shows the relative contents of the spinel particle size classes (rel.%). A distribution with one maximum is called unimodal, two - bimodal. Fashion is defined as the most common spinelid crystal size in the coarse range of 0.2-0.0 mm.

 In the drawings, reference numeral 1 shows a mass particle size distribution; position 2 - quantitative particle size distribution; position 3 - distribution curve of the particle size distribution of spinelids of the bulk in the volume of kimberlite rock.

 It has been experimentally established that industrially diamondiferous kimberlites in the fineness class -0.044 + 0.02 mm of mass particle size distribution contain more than 45 rel.% Of ore substance.

Using the methods of mathematical statistics, a regularity was established between the content of the fineness class -0.044 + 0.02 mm of the mass particle size distribution of spinelids and the diamond content of kimberlite rocks. Using the method of regression analysis, we tested the hypothesis of its description by various models. For each model, analysis of variance was carried out at a 5% significance level (α = 0.05).
Quantitative assessment of diamond content is calculated based on the relative content of this class according to the empirical formula
And _avg = 7.07X ^24.06 / (65.71 ^24.06 + X ^24.06 ),
where A _cf is the average diamond content of kimberlite rock, car / t;
X is the relative content of the size class -0.044 + 0.02 mm of the mass particle size distribution of spinelides of the bulk of kimberlite rocks;
7.07; 24.06; 65.71 - empirical coefficients of the regression equation.

The multiple correlation coefficient R = 0.99 and characterizes that fraction of the variability of A _cf , which is explained by regression.

 The method for assessing the diamond content of kimberlite rocks is implemented in several stages.

 First. In the field, at the stage of prospecting and evaluating geological exploration (as a result of boulder-glacier or clastic-river methods of searches), preliminary or detailed exploration, ore samples of kimberlite rocks are taken.

 Second. Production of areal transparent polished thin sections. Description of the textural and structural features of kimberlite rocks, study of the quantitative ratio of complex oxides of the bulk (perovskite content of more than 30% of the total amount of oxide minerals of the bulk of kimberlite rocks is characteristic of the low-diamond phases of diamond-bearing tubes and non-diamond-bearing kimberlite pipes, whereas in the bulk of high-diamond kimberlite rocks perovskite in such an amount is not found [3]). Thus, at this stage, kimberlite rocks are rejected, in the bulk of which perovskite predominates.

 Third. Measurement of spinelide crystals of the bulk of kimberlite rock using an automated image analysis system and processing programs and calculation of crystal morphometric parameters. The study is conducted in transmitted and reflected light with control in combined light. On thin sections, an automated calculation of the dimension of spinelide crystals from a sample of at least 1000 grains is performed with grouping by size class with a step of 2 in a size range of 0.2-0.0 mm. The calculation includes all, without exception, spinel grains, with the exception of crystals of the first, second and fourth genetic groups. At this stage, the difficulty is not to allow perovskite and ilmenite grains to be taken into account. Spinelides are marked by highlighting them according to the range of optical characteristics. Before calculating the parameters using the program tools, the marking plane is removed from the ilmenite and perovskite crystals, and spinel crystals that are in contact with each other are broken. For marked objects, the necessary morphometric parameters are calculated: ruggedness, dimension (average, minimum, maximum), elongation, average quantitative size, average mass size, and also the content and number of particles. Receive histograms of the distribution of quantitative, mass particle size distribution, based on the obtained histograms construct a distribution curve of the particle size distribution of spinelids in the volume of kimberlite rock.

 Fourth. By the nature of the behavior of the curve (a unimodal distribution with a maximum at the class of -0.044 + 0.02 mm of size - diamondiferous kimberlites) is qualitatively and then quantitatively (according to the relative content of the class -0.044 + 0.02 mm of size of the mass particle size distribution and the above described formula) are evaluated diamond content of kimberlite rock.

 As an example, the analysis of the particle size distribution of spinelide crystals of the bulk of the kimberlite rocks of two pipes of Yakutia is given.

 For research, we selected kimberlites of the hypabyssal facies of depth with a porphyry structure, massive texture with a minimum (<5%) content of xenogenic material, representing one of the phases of the introduction of kimberlite pipes.

Example 1. Single-mode distribution with a maximum in the size class -0.044 + 0.02 mm The bulk of the ore substance is in the size class -0.044 + 0.02 mm (68.5 rel.%) (Figure 1). This type of distribution of particle size distribution indicates a relatively rapid rise in the kimberlite melt, without stopping in the intermediate focus. The content of perovskite in the bulk of the kimberlite rock is significant. At a qualitative level, we can conclude that this kimberlite rock is diamondiferous. The calculation according to the empirical formula gives the following result, car / t: A _cf = 5.17 (true A _cf = 5.20).

Example 2. Bimodal distribution with maxima in the fineness classes -0.044 + 0.02 mm and -0.20 + 0.15 mm. The bulk of the ore substance is in the fineness class -0.20 + 0.15 mm (59.4 rel.%). The mass of crystals attributable to the particle size class -0.044 + 0.02 mm is 15.2 rel.% (Figure 2). The maximum at the fineness class of -0.20 + 0.15 mm indicates the existence of at least one intermediate magma chamber, in which normal spinelid crystals grew, which negatively affected the diamond content of this kimberlite rock. Perovskite in the bulk of the kimberlite rock is not marked. Calculated A _av = 0.00 (true A _av = 0.00).

 The expressness of the developed method: the ability to study in a short time the representative volumes of stone material determines the feasibility of the widespread introduction of the invention to assess the diamond content of kimberlite rocks in research and production organizations.

Sources of information
1. Inclusions in diamond and diamondiferous rocks / Under. ed. A.S. Marfunina. - M.: Publishing House of Moscow State University, 1991. p.118-121.

 2. RF patent 2090915, cl. G 01 V 9/00, 1997

 3. Bovkun A. V. Mineralogy of oxides from the binder mass of kimberlite rocks of Yakutia (Genetic and applied aspects) / Abstract of thesis. for the competition degrees of cand. geol. - min sciences. - M., 2000, p. 1, 18-20.

Claims (3)

1. A method for evaluating the diamond content of kimberlite rocks, including the selection of ore samples, the manufacture of thin sections, a description of the textural and structural features of the rocks, the study of the quantitative ratio of complex oxides of the bulk of kimberlite rocks: spinelids, perovskite, ilmenite, characterized in that the morphometric parameters of crystals are calculated from the thin sections spinelids of the bulk of the rock, obtain histograms of mass and quantitative particle size distributions, based on the obtained histograms construct a distribution curve Nia size distribution in the bulk spinels and rock on the relative content class -0.044 ± 0.02 mm size of the mass particle size distribution was calculated average value diamondiferous kimberlite rocks by the empirical formula
And _avg = 7.07X ^24.06 / (65.71 ^24.06 + X ^24.06 ),
where A _cf is the average diamond content of kimberlite rock, car / t;
X is the relative content of the size class -0.044 + 0.02 mm of the mass particle size distribution of spinelides of the bulk of kimberlite rocks;
7.07; 24.06; 65.71 - empirical coefficients of the regression equation.  2. The method according to p. 1, characterized in that the calculation of the size of the spinel crystals is carried out from a sample of not less than 1000 grains with grouping by size class with a step of 2 in the size range of 0.2-0.0 mm  3. The method according to p. 1, characterized in that, with the unimodal nature of the distribution curve of the particle size distribution of spinelides with a maximum at a particle size class of -0.044 + 0.02 mm, diamond content of kimberlite rock is judged, with the bimodal nature of the distribution curve of the particle size distribution of spinelids with maxima in the classes particle sizes of -0.044 + 0.02 and -0.20 + 0.15 mm judge the non-diamond content of kimberlite rock.

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