SE448578B - PROCEDURE FOR GEOPHYSICAL PROSPECTING OF POLYMINERAL ORE-CARBON - Google Patents

Description

15 20 25 35 448 573 2 This known phenomenon is the basis for a method for exploring polymineralic ore-bearing bodies by induced polarization (compare, for example, the book by vA Komarov "Electrical prospecting by induced polarization", published in 1980, publisher "Nedra", Leningrad , p 391). This known method is based on direct or alternating current flowing through a rock mass accommodating ore-bearing bodies, which is to be examined, and the so-called transition characteristic of media-induced polarization is measured, whereby the presence of ore-bearing bodies in the polarization zone is assessed depending on the anomalies of the induced polarization.

With this known method, however, it is possible to determine the number of adjacent (joined) ore-bearing bodies on the basis of the particular anomaly. In addition, under the conditions of the site to be extracted, considerable currents (of a few hundred A) must float, especially when electrically conductive rocks accommodating rocks are found in the site, which is practically impracticable. The use of this known exploration method in shafts is limited in that elongated electrically conductive objects, for example pipelines, rails and cables, are present in the shaft. Another method for geophysical prospecting of polymineral ore-bearing bodies is also known (compare, for example, Soviet Inventor Certificate No. 972,453, filed March 4, 1981 and published November 7, 1982 in the bulletin "Otkrvtiya, izobreteniya, promyshlennye obrazsty i. tovarnye znaki ", No. 41, int. r1.3 G oi v 11/00), the wine makes it possible to more accurately determine the amount of ore-bearing bodies in the these mass-bearing rock masses, which are examined. This known method is characterized by generating the elastic wave in the ore-bearing bodies enclosing the rock mass and recording the electromagnetic pulsed radiation to be generated by the ore-bearing bodies under the influence of the elastic waves, the amount _. _ ... ewa,., ..............

L? LO 15 20 30 44% 578 3 Polymineral ore-bearing bodies in the investigated rock mass are determined depending on the number of radiation pulse packets. IV This known method gives a relatively low accuracy in determining the amount of polymineral ore-bearing bodies in the investigated rock mass, since it is not possible to distinguish (identify) ore-bearing bodies with low power due to the electromagnetic radiation intensity being dependent on the ore-bearing the power of the body. The intensity of the pulsed electromagnetic radiation generated by the ore-bearing body also depends on the ore-bearing: roppene mineral composition and structure.

BACKGROUND OF THE INVENTION The main object of the present invention is to provide such a method for geophysical exploration of polymineral ore-bearing bodies, which makes it possible to increase the accuracy of the radiation intensity generated by the ore-bearing bodies by increasing the electromagnetic orifice bodies. located in the investigated massif. This object is achieved according to the present invention by means of a method for geophysical exploration of polymineral (several mineral-containing) ore-bearing bodies, in which elastic waves are generated in the rock (the rock) in which ore-bearing bodies are housed, and it is recorded. pulsed electromagnetic radiation to be generated by the ore-bearing bodies under the influence of the elastic waves, while the amount of polymineral ore-bearing bodies is determined depending on the number of radiation pulse packets; wherein the method according to the present invention is characterized in that in advance in the rock mass to be examined, elastic waves are excited (generated), which cause electrostatic polarization in the ore-bearing bodies, while the subsequent excitation .MW -f «i ....-. VH ..->. .........-_..... _ 10 15 En * Ö 25 30 35 .1l48 m x: G3 4 of the elastic waves are performed during a time interval, during which the electrostatic polarization charge occurs.

If a known ore-bearing body is present in the rock mass, it is suitable that a change in the electrostatic polarization charge of this ore-bearing body is also registered and that the elastic waves are then generated when this polarization charge becomes maximum.

It is known that a pulsed electromagnetic radiation is generated in polymineral ore bodies under the influence of an elastic wave, the electric field strength at a distance of 1 m from an elastic wave source being less than 107 to 108 rpm and being one thousand times higher than the field strength of electric, so-called contact and seismic fields. D The rise time and relaxation time of the electrostatic polarization charge depend on the mineral composition of the ore-bearing body, the rise time of the charge varying between a few and about ten seconds. The relaxation time of the charge is a few minutes.

In the rock mass to be investigated, all polymineral ore-bearing bodies are polarized regardless of their thickness.

The pulse amplitude of the electromagnetic radiation to be generated by polarized ore-bearing bodies under the influence of the elastic waves is higher than the pulse amplitude of the electromagnetic radiation to be generated by unpolarized ore-bearing bodies. At the time when the electrostatic polarizing charge of the ore-bearing body becomes maximal, the amplitude of the electromagnetic radiation caused by the elastic waves generated in the rock mass at this time increases by two to five times depending on the ore-bearing body mineral composition. This makes it possible to record the electromagnetic radiation from low-power ore-bearing bodies and from ore-bearing bodies which are at a considerable distance from the place where the electromagnetic radiation is .. .. - ._-..--. ~. --1 .. ~ .V ._ .. s> .... ~ _..._, i (rb * - 10 15 20 30 35 448 578 5 ning is registered (sensed), why the amount of ore-bearing bodies in it rock masses to be investigated can be determined with greater accuracy.

Brief Description of the Drawing Figures The invention is described in more detail below with reference to a concrete example of carrying out the method according to the present invention for geophysical exploration of polymineral ore, bodies and to the accompanying drawing, in which Fig. 1 shows a time diagram of the change of an electrostatic polarization charge for ore-bearing, galenite and sphalerite-containing bodies, Fig. 2 shows a timing diagram of the change of an electrostatic polarization charge for ore-bearing bodies containing quartz, antimony and cinnabar, and Fig. 3 shows in time diagram form the pulsed electromagnetic radiation.

Preferred Embodiment of the Invention The method proposed for the present invention for geophysical exploration of polymineral ore-bearing bodies is carried out in the following manner.

In a rock mass to be examined, elastic waves are generated which cause an electromagnetic radiation and electrostatic polarization of the ore-bearing bodies, for which purpose a charge of explosive, the explosive capacity of which depends on the volume of the rock mass to be examined, is brought to blow up.

By means of the method according to the present invention, the exploration is usually carried out in a mass of rock with a radius of approximately 100 m from the point of explosion. The capacity of the explosive charge depends mainly on the reproductive conditions of the elastic waves in the mass of rocks to be investigated, on the other hand the dimensions of the massif and on the mineral composition of the ore-bearing bodies in question. ~ - ~ ---------- ~ - .., ......._...._........_.._.-.... 10 15 20 25 30 448 578 6 The weight of the charge of, for example, ammonite is generally at most 6 kg. In cases where the solid to be examined has small dimensions, for example a radius of between 10 and 20 m, the elastic waves can be generated by means of sources of another kind (of the so-called non-blasting type).

The charge of explosives is usually placed in the mouth of an already existing hole (including a drill heel or blast hole) or in a depression in the bottom part of a quarry.

An electrostatic field generated by polymineral ore bodies is manifested by a positive charge at the surface of the ore bodies. Time diagrams 1 and 2 of the change in charge are shown for two investigated ore deposits in Fig. 1 and Fig. 2, respectively, where the charge coating G in 10 the sketch. Before a time t0 = 0 (i.e. before the blast is initiated), the ore-bearing bodies have a natural charge with a coating 0'0 (Fig. 1) and Gå '(Fig. 2), respectively. After blasting, the charge is increased, whereby the time interval tm a maximum axis, during which the charge receives Umax, is dependent on the mineral composition of the ore-bearing body and constitutes t'max = 1 s (Fig. 1) for ore-bearing, galenite- and sphalerite-containing bodies and t "max. = 14 s for ore-bearing quartz, anti-monite- and cinnabar-containing bodies.The relaxation time of the charges is a few min.

During a time interval during which the electrostatic polarization of the ore-bearing bodies occurs, elastic waves are then generated again in the mass of rocks to be examined, for example by blasting a charge of explosive. The repeated blasting is carried out, as a rule, in the vicinity of the first blasting point at a distance which makes it impossible to detonate the explosive. The weight of the explosive charge for the repeated blast may be less than the weight of the explosive charge for the first blast. The repeated (second) blasting is carried out by means of an ammonite charge with a weight of, for example, 1 kg.

Ln 10 15 20 - 25 30 35 448 578 7 .The optimal time for the repeated excitation of elastic waves is the moment when the electrostatic polarization charge reaches its maximum. To determine this time, a measuring device is placed on a known ore-bearing body, in which a quarry is occupied, which is intended to detect (sense) the change in the electrostatic polarization charge and consists of, for example, a so-called electrometer, whose measuring electrode can be periodically shielded. By observing the change in the electrostatic polarization potential, for example on the screen of an electronic oscilloscope, the maximum charge is visually determined.

At the same time as this maximum is reached, elastic waves are re-excited and the pulsed electromagnetic radiation of the ore-bearing bodies is recorded, after which the amount of polymineral ore-bearing bodies is determined on the basis of the number of radiation pulse packets.

Fig. 3 shows a time diagram of the pulsed electromagnetic radiation, the voltage U in V across the output of the recording device being plotted along the ordinate, while the time t in ms is plotted along the abscissa.

The radiation of the ore-bearing bodies consists of packets 3, 4, 5 of noise-like signals, which consist of short-lived pulses with different amplitudes and polarity. The time diagram shows three packets 3, 4, 5 of pulses with the aid of which it can be stated that by means of the exploration method proposed according to the present invention, three ore-bearing bodies of industrial interest have been discovered in the investigated mass of rocks.

In order to better understand the inventive concept, the following examples of carrying out the method according to the invention are described below.

The method proposed according to the present invention for geophysical exploration of polymineral ore-bearing bodies has been tested in a site for the search of ore-bearing bodies containing quartz, antimonite and cinnabar. On an ore-bearing body, which had been exposed by means of a quarry, an electro- was placed in advance. ..-. ~ ._...-........._. », 10 15 20 25 30 35 l448 578 8 meters for recording a change in the electrostatic polarization charge of this ore-bearing body. Then a 4 kg weighing ammonite charge was caused to explode at a point in the quarry.

Under the influence of an elastic wave generated by the explosion, an electromagnetic radiation was generated in the ore-bearing bodies in the mass of rocks which were examined. At the same time, the electrometer was registered and the change in the electrostatic polarization charge was visually observed. At the time when the electrostatic polarization charge coating 8 Coulomb / m2, U reached its maximum value of 8-110_ was carried out - 14 s after the first blast - a second blast of a 1 kg weighing ammonite charge at a distance of about 10 m from the point, where the elastic waves were excited by the first blast. The pulse amplitude of the electromagnetic radiation was 0.5; thus four ore-bearing bodies in the solid of 1.3; 2 and 0.8 V for different objects. One register- rocks, which were examined.

To determine the distance at which each ore-bearing body was located, the pulse transmission time was recorded, which for said pulse amplitudes was 3.25; 6.1; 10.15 respectively_14.4 ms.

This distance can be easily determined on the basis of the propagation speed (propagation speed) of the elastic path in the rock in which the ore-bearing body is housed. At a wave propagation speed of, for example, 5.5 m / ms in solid limestone, said distance for the fourth ore-bearing body is 14.1 ms x 5.5 m / ms = 78 m from the blasting point. during the test, it was found that the exploration holes were indeed drilled in these four ore-bearing bodies. For comparison of the method proposed according to the present invention with the known method of this kind, the electromagnetic radiation amplitude generated by the ore-bearing bodies under the action of the elastic ones was recorded by the first blasting. -... »,. e>.-...... V ..... _, 448 578 9 ningen wxciterade waves. Three ore-bearing bodies were discovered. The pulse amplitude was 0.1; 0.4 and 1 V, respectively, while the pulse transmission time was 3.2; 6.1 and 10.2 ms, respectively. The amplitude of the signals generated by the polarized bodies was thus increased two to five times, which made it possible to detect the ore-bearing body, which at the first blast, when the ore-bearing bodies were not polarized, was not detected. I Industrial Applicability The process proposed for the geophysical exploration of polymineral ore bodies according to the present invention can be used in the search and exploration of ore bodies containing tin, gold, zinc, lead, mercury, molybdenum, tungsten, antimony and rare. earth metals and is very effective in exploring ore-bearing bodies during the operational phase of known sites. ..._ .. ........, ._..__.._..._........ - ............___ .....-..... .. .. f, ....., .., ._ .., _, _, _ ,, _.,., .__, ._, ___ , ._ _ _ _, ___, __, _, __, ___ _

Claims (2)

l 0 PATENT REQUIREMENTS A method for geophysical exploration of polymineral ore-bearing bodies, in which elastic waves are generated in the rock in which the ore-bearing bodies are housed, and the pulsed electromagnetic radiation to be generated by the ore-bearing bodies during the effect of the elastic waves, the amount of polymineral ore-bearing bodies being determined on the basis of the number of radiation pulse packets, characterized in that in advance, in the mass of rocks to be examined, elastic waves which cause electrostatic polarization are excited in the ore-bearing bodies, while the subsequent excitation or generation of elastic waves is carried out during the time interval when the electrostatic polarization charge occurs. 2. A method according to claim 1, characterized in that - if a known ore-bearing body is present in the mass of rocks - a change in the electrostatic polarization charge of this ore-bearing body is also recorded, while the subsequent excitation of elastic waves are carried out, at the same time as this polarization charge gets its maximum value. _..., -._ .. a -, .... f ~.-.._._..., ..._, ._..__. ... pdf-i ~ «---, ----- .. ~ - --f ----------