RU2035751C1 - Method for prospecting of mineral ore bodies - Google Patents

Abstract

FIELD: geophysical investigations. SUBSTANCE: method for prospecting of mineral ore bodies consists in rock sampling on investigated area and analysis of the taken samples for content of ore and petrogenic elements, revealing and delineation of anomalies containing high concentration of ore elements, revealing of geochemical barriers to which those anomalies are confined. Considered as barriers are barriers between four rock-forming elements - potassium, sodium, magnesium and calcium within geochemical barriers which are revealed by ratio between these elements with the use of densified research network. Samples are taken additionally to subject them to petrographic analysis and analysis of ore elements. On the basis of petrographic analysis of those samples, metasomatic barriers are mapped and their types are determined. Content of ore elements detected in additionally taken samples are used for calculation of associations of ore elements typical to revealed types of metasomatic barriers, and occurence of mineral ore bodies is determined by ubnormal values of ore elements on the basis of calculated association typical to the given type of metasomatic barrier. EFFECT: higher efficiency. 3 dwg

Description

 The invention relates to geochemical methods of searches and can be used to identify ore bodies of minerals.

A known method of searching for ore minerals, the essence of which is that they conduct lithochemical testing, in which samples of bedrock are taken from the surface or from surface mine workings, samples are analyzed, the contents of the desired chemical elements are established in them, samples containing these elements are detected in abnormal concentrations, and outline areas with these samples. Identified areas are considered surface geochemical anomalies. They study the geological structure of these anomalies and their geological position in the structure of a vast territory. Identified areas are compared with known reference geological and industrial facilities. Based on the results of the comparison, a conclusion is drawn about their prospects. On prospective anomalies identified in this way, mining operations evaluate the presence of industrial accumulations of minerals [1]
This method has such a disadvantage as the inability to detect ore objects that are not similar to known standards when valuable ore concentrations of previously unknown types of mineralization are rejected. In addition, this method is aimed at identifying ores of individual minerals and does not allow to fully study the studied area for the presence of a wide range of useful components. This leads to a sharp increase in costs when conducting repeated prospecting and evaluation work in the search for a different type of mineral raw material.

Closest to the proposed method is a search for ore minerals, including sampling rocks on the study area, analyzing them for the content of ore elements, identifying and outlining anomalies of elevated concentrations of ore elements, identifying geochemical barriers to which these anomalies are confined, correlating these barriers with the corresponding by associations of chemical elements, the choice of all these factors of ore-promising anomalies of ore elements, concentrated on the corresponding geochemical Riera, and evaluate these anomalies mining and drilling operations [2]
This method is based on the use of geochemical barriers of the earth's crust, where at a short distance there is a sharp decrease in the intensity of migration of chemical elements and, as a result, their concentration. The classification of geochemical barriers was developed and proposed to be used by A.I. in order to search for ore minerals. Perelman. When searching in this way, the detected anomalies of chemical elements are compared in composition with typical associations of chemical elements, and the geological situation of the studied anomaly is compared with a description of typical anomalies of this classification. Find standard descriptions of the types of anomalies that are similar to those observed, and make a conclusion about the ore prospects of this anomaly.

 However, this method of geochemical prospecting has a limited scope, since it allows you to only search for clusters of hypergenic ores. It is based on the classification of concentrations of chemical elements at the geochemical barriers of the hypergenesis zone, which reflects the laws of migration and deposition of chemical elements only in this zone. At the same time, the bulk of ore deposits are represented by endogenous types of ore concentrations, the spatial distribution patterns of which obey the laws of endogenous migration and deposition of chemical elements, which differ significantly from similar patterns of the hypergenesis zone. In hypergenic and endogenous processes, the sources of ore material are significantly different, which fundamentally affects the spatial distribution of ore objects. Therefore, using the search method for the prototype, it is impossible to search for endogenous ore bodies of minerals.

 The aim of the invention is to increase the efficiency of the search method by expanding its scope by providing search capabilities for endogenous ore bodies of minerals.

 The goal is achieved by the fact that by the method of searching for ore bodies of minerals, including sampling of bedrock in the studied area by profiles and determining the contents of ore elements in them, by the anomalous values of which judge the position of the ore bodies, additionally determine the concentrations of potassium, sodium in the samples, magnesium and calcium, calculate the ratios K / Na, K / Mg, K / Ca, Na / Mg, Na / Ca, Mg / Ca, build graphs of the variation of the gradients of these ratios along the profiles, on each of which, according to the most abnormal relative to the background values, the boundaries of the zones of geochemical barriers of the indicated types are poured, the boundaries of these zones are drawn over the entire set of profiles, additional samples are taken within the zones of geochemical barriers, a petrographic analysis is carried out, the results of which establish the presence of specific types of metasomatites, which include the sum of newly formed minerals exceeds 30% and according to which the boundaries of the zones of metasomatic barriers and their type are established, the content of ore elements in additionally selected samples is calculated associations of ore elements characteristic of the identified types of metasomatic barriers, and the position of the ore bodies of minerals is determined by the anomalous values of ore elements located in the zone of the metasomatic barrier from the calculated association characteristic of this type of metasomatic barrier.

 In FIG. 1 shows a diagram of the proposed method for searching ore bodies of minerals with the extraction and use of geochemical barriers to detect the desired objects, for which, according to the results of testing conducted along the profiles (6), based on the results of the analysis of petrogenic elements, geochemical barriers of the field grade are distinguished. In this case, three zones of barriers are distinguished: potassium-sodium (1), sodium-magnesium (2), magnesium-calcium (3), which are parallel to each other with partial overlap. Based on the analysis of ore elements, a number of anomalies were identified, which are divided into promising (4) located within the zones of the indicated geochemical barriers and unpromising (5) located outside these zones. Based on the position of promising anomalies, one can judge the presence of fossil ore bodies; therefore, the zones of geochemical barriers within which these anomalies are located are subjected to additional testing using a denser network (7). As an example, the position of the section of the profile of geochemical testing along the AB line (8) is shown, within which a geochemical barrier is revealed by the potassium-sodium ratio. Details of this are shown in FIG. 2.

 In FIG. Figure 2 shows an example of the separation of the geochemical barrier by changing the values of the potassium-sodium ratio. On the AB profile, the position of which is indicated in FIG. 1, the values of the potassium-sodium ratio are presented at the sampling points, which are presented in the form of a graph (9). As can be seen from comparing this graph with the geological and metasomatic section (12), the highest values correspond to the potassium feldsparization zone (potassium) 14, the smallest to the albitization zone (sodium) 16, and the intermediate ones to the potassium-silicon zones of greisenization (15) and berezitization (17), presented aggregates of quartz and light potassium mica. The propylite zone (18) does not fend off with the potassium-sodium ratio. To identify specific boundaries of the barrier from the feldspar to the berezite zones, a gradient calculation method is used when the difference in the values of the potassium-sodium ratio is calculated at adjacent test points. It can be seen in graph (10) that the zone of metasomatic changes from potassium feldspar to berezite is characterized by the presence of values that clearly exceed the background, while weakly altered rocks and propylites (changes in the calcium-magnesium series) are characterized by background fluctuations in the values of the gradients (11). The boundaries of the barrier are clearly beaten off by the position of the extremes of the extreme peaks. The boundaries of the zones inside the barrier are also reflected by gradient peaks. To more clearly isolate magnesium and calcium metasomatites, sodium-magnesium, magnesium-calcium, and other above-mentioned relations are used.

 In FIG. Figure 3 shows a diagram of the separation of the identified geochemical barriers (30) into metasomatic zones (23) and barriers (24, 25, 26) and the identification of ore body ranked objects associated with them. Two metasomatic barriers were identified within the potassium – sodium barrier: potassium feldspar – albite and albite – berezite. The Kalishpat-albite barrier is confined to the border of the Kalishpat (19) and albite (20) zones and is represented by the zone of ore-bearing greisens (24) by an aggregate of quartz and muscovite. The albite-berezite barrier is confined to the boundary of the albite (20) and berezite (21) zones and is made of quartz veins with sulfide mineralization (25). The sodium-magnesium barrier practically coincides with the albite-berezite barrier described above. The magnesium-calcium barrier coincides with the birch-propylite metasomatic barrier. The zone of beresites (21) is represented by an aggregate of quartz, sericite and pyrite, the zone of propylites (22) is an aggregate of calcium and magnesium carbonates, epidote and chlorite. The birch-propylite barrier is traced by kaarbonate-sulfide veins (26). Within the above metasomatic zones, the sum of newly formed minerals is more than 30% (23). Each metasomatic barrier is characterized by a specific ore geochemical specialization. Greisen zone is a rare metal association: thorium, tungsten, tin, bismuth, beryllium. The albite-berezite barrier is a gold-silver association with iron, arsenic, and a group of rare-earth yttrium. The birch-propylite barrier with carbonate-sulfide veins is characterized by the association of lead, zinc, silver, copper, antimony, gold and mercury. Within the indicated barriers, geochemical anomalies are identified that reflect the position of the ore bodies. In the greisen zone (feldspar-albite barrier), tungsten anomalies (27), in the zone of the berezite-propylite barrier, anomalies of lead and zinc (29), in the zone of the albite-beresite barrier, gold anomalies (28).

 The proposed method is as follows.

 On the study area, bed samples are taken according to profiles, samples are analyzed for the content of ore and petrogenic chemical elements, anomalies of elevated concentrations of ore elements of the rank of the field are identified and outlined, geochemical barriers to which these anomalies are associated are identified (Fig. 1). The geochemical barriers between the anomalies of the rank of the deposits are determined by the geochemical barriers between the four main rock-forming elements: potassium, sodium, magnesium and calcium, and in the following combination K / Na, K / Mg, K / Ca, Na / Mg, Na / Ca, Mg / Ca. The quantitative ratios of the contents of the elements of each pair in each sample are determined, gradients along the sampling profiles are calculated, for which the differences between the values at the adjacent points are determined, the indicated zones of the barriers are distinguished by the gradient zones exceeding the background values, and the extreme peaks of the extreme peaks are taken as a criterion for their contouring these zones (Fig. 2). Within the identified zones of geochemical barriers, thickened network is additionally taken samples of bedrock, the samples are subjected to petrographic analysis and analysis of the content of ore elements. Based on petrographic analysis, associations and ratios of newly formed minerals are established. At the same time, rocks containing newly-formed minerals in amounts exceeding 30% are classified as metasomatic rocks of ore-ore changes, and the type of metasomatic changes in accordance with the composition of newly-formed minerals is established according to the systematics of metasomatic rocks accepted in geological practice. Thus, within the identified geochemical barriers of the rank of the deposit, metasomatic barriers of the rank of the ore body are distinguished. According to the content of ore elements in additionally selected samples, associations of ore elements characteristic of the selected types of metasomatic barriers are calculated, and the position of the ore bodies of minerals is determined by the anomalous values of ore elements located in the zone of the metasomatic barrier from the calculated association characteristic of this type of metasomatic barrier.

 The proposed method can be successfully used in the search for non-ferrous, rare and noble metals for mineralization formed under the influence of magmatic, metamorphic and hydrothermal processes. Its application provides a comprehensive search of areas with a significant reduction in material costs.

Claims (1)

 METHOD FOR SEARCHING ORE BODIES OF MINERAL MINES, including sampling rocks by profiles and determining the contents of ore elements in them, by the anomalous values of which judge the position of ore bodies, characterized in that in addition to determine the concentration of K, Na, Mg and Ca in the samples, calculate the K / Na, K / Mg, K / Ca, Na / Mg, Na / Ca, and Mg / Ca ratios build graphs of the variation of the gradients of these ratios along the profile, on which the boundaries of the zones of geochemical barriers are set according to the most abnormal relative to the background values, within which additional samples are carefully taken, their petrographic analysis is carried out, the results of which determine the presence of this type of metasomatites, in which the amount of newly formed minerals exceeds 30% and by which the boundaries of the zones of metasomatic barriers are determined and their type, ore associations are calculated from the content of ore elements in additional samples elements characteristic of the identified types of metasomatic barriers, and the position of the ore bodies of minerals is determined by those located in the zone of the metasomatic bar era anomalous values from ore elements calculated association inherent to this type metasomatic barrier.

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