SU1257597A1 - Method of detecting and studying ore bodies - Google Patents

Abstract

The invention relates to geophysics and can be used to simplify and improve the efficiency of exploration for ore deposits of any type of minerals. The purpose of the invention is to reduce the labor intensity and increase the detection efficiency of ore bodies. In promising areas of ore deposits, determined by geological and geophysical methods, profiles are broken across the intended strike of the ore body. Profiling is performed by continuously moving the inductor at a height of up to 1.0 m from the ground. The EMF signals induced in the coil through the cable enter the magnetic recorder, where they are recorded on a magnetic tape. Continuous profiling is carried out in the opposite direction. For each profile, the forward and reverse profile EMF plots are compared. The boundaries of the ore body are reliably detected by the values of the extremal portions of the EMF plots, which have the same amplitude, and for iron ore bodies, the magnitude of the amplitude is proportional to the iron content in the ore body. 1 hp f-ly, 2 ill.

Description

The invention relates to geophysics and can be used to simplify and increase the efficiency of exploration for ore deposits of any type of minerals.

The purpose of the invention is to reduce the labor intensity and improve the detection accuracy of ore bodies, mainly iron ore, by clarifying their boundaries.

FIG. Figure 1 shows the results of profiling by an inductance coil along profile XI (a is the graph of the integral emf, S is the geologic section,); in fig. 2 - results of profiling by the inductance coil along profile X (a is the graph of the integral emf, S is the geological section).

FIG. 1 and 2, we denote the amplitudes of the extremal parts of the EMF plots; moreover, as applied to iron ore bodies, the magnitude of the amplitude is proportional to the iron content in the ore body. At the boundary of the ore body with the host rock, there is a significant change in the gradient of the vertical component of the geomagnetic field, which is reflected in the extremal parts of the EMF plots.

FIG. The extremes of amplitude A are shown, 2.5 mV with background values of amplitudes 0.2-0, ZSU. The ore body 4 (Fig. 1S) with 15% iron content is located under loams 1 and sandstones 2 host rock environments 3 and gneiss 5. The width of the ore body is determined by the internne distance: A, 2.5 mV - amplitudes of extremes of extremes of extremes of emf from most parts of emf plots; 1 is the amplitude of amplitudes A and is 47m links; 2 - sandstones; 3 - crystalline (from PC 9 to PC 56, Fig. 1S) and 9 m (from chests of schist (amphibole pyroxene); PC 83 to PC 92).

4 - ore body with iron content Detection of more depleted iron - 14%; 5 — gneisses and migmatites of biotite-25 by ore bodies and heterogeneities; A - 1.68 mV and A, - 0.8 mV - is shown on the example of profiling results for profile XI. On the EMF plot (Fig. 2a), the amplitudes of the extremes of EMF have another 30 values Aj; 1.7 mV and A 0.78mV i.e. , 75-1.8, A, A, / 3-4. The width of the iron-depleted ore body 6 (Fig. 25) is 16 m (from PC 22 to PC 38). Amplitude A corresponds to the amplitudes of the extreme parts of the EMF plots; 6 - ore body with an iron content of 10%; 7 - tectonic disturbance.

An example of the method.

In promising areas of ore deposits, determined by geological or geophysical methods, profiles are broken across the supposedly tectonic disturbance 7 among the most visible strike of the ore body. Pro-crystalline schists 3 and gneudes are profiled by continuously moving the inductor at a height of up to 1.0 m from the surface of the Earth. The EMF signals induced in the coil through a cable enter the magnetic recorder, where they are recorded on a magnetic tape. Continued profiling 5.

Heterogeneities of non-metallic nature, for example, karst etc., on other

j} Q deposits will correspond to each other in terms of A, but always smaller compared to A, and Aj, corresponding to the boundaries of the ore bodies, where the vertical gradient is

and in the opposite direction.

After the plot was taken, the plotter H-306 was used to rewrite the EMF signals from the magnetic tape to paper. For each profile, the forward and reverse profile EMF plots are compared.

The amplitude values in millivolts or millimeters of the extremal portions of the EMF plots are determined. As the experimental tests of the method showed, the boundaries of the ore bodies are reliably detected by the values of a number of identical values

the amplitudes of the extremal parts of the EMF plots, and, as applied to iron ore bodies, the magnitude of the amplitude is proportional to the iron content in the ore body. At the boundary of the ore body with the host rock, there is a significant change in the gradient of the vertical component of the geomagnetic field, which is reflected in the extremal tectonic disturbance 7 among crystalline schists 3 and gnei

owls 5.

Heterogeneities of non-metallic nature, for example, karst etc., on other

The deposits will correspond to each other in the value of A, but always smaller compared to A, and Aj, corresponding to the boundaries of the ore bodies, where the vertical gradient is

hundreds of times more (compared with the heterogeneity of non-metallic nature). To increase the express intelligence of the ore bodies, an inductance coil is mounted on vehicles

and move at a speed of 50 km / h.

Tests have shown that the optimal speed of the coil is up to 50 km / h: when moving the coil at a higher speed, the recording equipment is inert and it is possible to skip the heterogeneity of the body, which is small in width and ore content.

When a vehicle moves a coil, the extremes of amplitudes A (, Aj, A) increase in proportion to the speed of movement. In addition, the speed of exploration increases by 5-10 times compared to the pedestrian variant. In fields that differ sharply in structure and depth tense more than any host rock.

In addition, the method is applicable to the exploration of quartz-containing and piezo-active rocks.

Found the principle of intelligence and research on the values of amplitudes A,

the amplitude values can be varied by A, the EMF plots are applicable for lune,

c, but the ratio will remain t 1j6 A, i. 1.5-2 times more.

When comparing EMF graphs of forward and reverse moves, the boundary of contacts between ore bodies and host rocks is specified. It is determined midway between the displacements of the amplitudes along the horizontal axis of the EMF plots. If there are watered karst and tectonic disturbances, the extremal parts of the EMF graphs of the forward and reverse strokes are mirrored, therefore the limit of heterogeneities is determined with an accuracy of 1 m. The boundary of the ore body is established with an accuracy of 2-3 m.

The physical basis of the proposed method is a sharp change in the gradient of the natural magnetic field of the Earth at the boundary of the ore body with the host rocks. This change reaches from 300 to 900 nt / m and retains such a value at a height of up to 1.0 m from the Earth's surface. When the coil inductance crosses the places of the change in the gradient in the latter, extreme values of the emf are induced. At the boundaries of the iron-depleted ore body with the embedding rocks, the gradient varies from 100 to .300 nt / m, which induces an emf of smaller magnitude.

five

20

bykazh deposit. Previously, profiling is performed on a known geological section, exploring the characteristic fossil amplitudes A (, A and characteristic AZ amplitudes for heterogeneities. Then the ratios between A (AZ and AZ) characteristic for this type of ore body are found. square.

Claims (2)

 1. The method of detection and study of ore bodies, consisting in discrete registration at points of profiles of artificial seismic and natural electromagnetic fields with subsequent analysis of the amplitudes and frequencies of the received signals, tl and 30 35 40 Due to the fact that, in order to reduce labor intensity and increase the accuracy of ore bodies, mainly iron ore, by specifying their boundaries in promising areas of the fields, measuring the natural geomagnetic field is carried out continuously by moving a sensor connected to a magnetic recorder at a height of up to 1.0 m from the surface of the Earth, examine the EMF plots by profiles m, select the amplitudes A (, Aj, A) of the experimental parts of the EMF plots with the ratios A A, (1.5-1.7), AZ A, (3-4), where A and AJ are extreme values of the amplitudes. EMF or related to the places of contact between ore-1X bodies with interfering rocks, respectively, with rich and depleted iron content, A - extreme values of the amplitudes of the EMF, corresponding to non-uniformity of non-metallic nature, mainly karst, tectonic disturbances, and the distance between dots in the plots with amplitudes of emf A, refer to the width of the iron-rich ore body, and the distance between the points On physical and geometrical irregularities of nonmetallic nature (karst, tectonic disturbances, watering zones, etc.), the gradient of change of the geomagnetic field does not exceed too nt / m, which is explained by smaller extreme values of emf. I The proposed method is applicable for exploration of deposits of ore bodies of any type (polymetallic, non-ferrous metals, etc.), ore bodies are heterogeneities among the host rocks even highly magnetic, ore bodies of any type have their own magnetic field in tens times the stress is greater than any host rock. In addition, the method is applicable to the exploration of quartz-containing and piezo-active rocks. Found the principle of intelligence and research on the values of amplitudes A,  A, EMF plots are applicable for A, EMF plots are applicable for any bykazh deposit. Previously, profiling is performed on a known geological section, exploring the characteristic fossil amplitudes A (, A and characteristic AZ amplitudes for heterogeneities. Then the ratios between A (AZ and AZ) characteristic for this type of ore body are found. square. Invention Formula  1. The method of detection and study of ore bodies, consisting in discrete registration at points of profiles of artificial seismic and natural electromagnetic fields with subsequent analysis of the amplitudes and frequencies of the received signals, tl and 30 35 40 five 0 five Due to the fact that, in order to reduce labor intensity and increase the accuracy of ore bodies, mainly iron ore, by specifying their boundaries in promising areas of the fields, measuring the natural geomagnetic field is carried out continuously by moving a sensor connected to a magnetic recorder at a height of up to 1.0 m from the surface of the Earth, examine the EMF plots by profiles m, select the amplitudes A (, Aj, A) of the experimental parts of the EMF plots with the ratios A A, (1.5-1.7), AZ A, (3-4), where A and AJ are extreme values of the amplitudes. EMF or related to the places of contact between ore-1X bodies with interfering rocks, respectively, with rich and depleted iron content, A - extreme values of the amplitudes of the EMF, corresponding to non-uniformity of non-metallic nature, mainly karst, tectonic disturbances, and the distance between dots in the plots with amplitudes of emf A, refer to the width of the iron-rich ore body, and the distance between the points 51257597S with amplitude A, referring to the width of the ore sensor along the profiles of m in the inverse of the body with the depleted content of the boards, they combine graphs and the positions of the respective extrusion. 2. A method for detecting and investigating mines in clause, 1, and about t l and - due to the fact that EMF measurements are made by moving The smallest EMF values with amplitudes A ,, AJ, AZ specify the boundaries of the ore bodies and non-metallic heterogeneities. The smallest EMF values with amplitudes A ,, AJ, AZ specify the boundaries of the ore bodies and non-metallic heterogeneities. t, I t.e IS t.e / fff as g fVvJ MMftVV y . Yes to 30 75 3 TH a to 30 100 / w / w, " e, ITS tfS to &# 0.5 ais 0 Ai 4W, " E2E 7E2D Editor M. Kelemesh Compiled by I. Abramova Tehred A. Kravchuk Proofreader M. Demchik Order 4915/45 Draw 728 Subscription VNIIPI USSR State Committee on inventions for discoveries 113035, Moscow, Zh-35, .Raushska nab., d. 4/5 Production and printing company, Uzhgorod, st. Project 4