RU2427010C2 - Method for searching ore deposits on microamalgams and device for its implementation - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: gas samples are taken from soil horizon and subsequently passed through each part of absorptive system. The latter consists of two parts of golden sorbents. The first part of the above system consists of one sorbent and speed of sample passing through it is not more than 5 l/min. The second part of the system consists of some number of golden sorbents, each of which provides the sample passage with speed of not more than 1 l/min. Available deep ore objects are estimated by content of mercury accumulated on sorbents at various pumping speeds. In order to implement the method, the device which includes gas sampling cap connected through dust collecting filter and three-way valve with mercury absorbing filter and absorptive system is proposed. Absorptive system is connected to measuring unit of mercury photometre and power supply unit, which are connected to each other. Measuring unit of mercury photometre is connected to vacuum pump with controlled pumping function.

EFFECT: more reliable searching results.

2 cl, 2 dwg

Description

The invention relates to geochemical methods of searching for ore objects, and can also be used to sort out geochemical anomalies obtained by other methods.

There is a method of searching ore deposits by microamalgams (see AS USSR No. 960703, priority date 09/23/82, class G01V 9/00), including selecting at each research point 3 ^x -4 ^x adjacent homogeneous sampling sites , the sequential installation of a gas sampling hood on each of the sites, sampling of soil air at different, sequentially increasing sampling rates, the determination of mercury vapor in the samples taken by a mercury photometer with a gold sorbent, and the assessment of the presence of ore elements at the point of study using changes in mercury content at points at different sampling rates.

A device for implementing this method (see ibid.) Includes a gas hood with a dust filter, a gold string sorbent, a vacuum pump with adjustable pumping, a measuring photometer, a power supply, a mercury filter absorber and a three-way valve. In this case, the power supply is connected to the photometer unit and the sorbent.

The basis of the invention, which provides the search for ore objects, is the established existence at the contact of two geospheres - the lithosphere and the atmosphere of a kind of geochemical barrier of amalgamation, in which mercury aerosols, forming a continuous ground layer, amalgamate all vaporous elements migrating from the depths. The dependence of the absorption of amalgams with ore elements by the surface of the gold sorbent on the concentration of ore elements in microamalgams is established.

Moreover, the more concentrated the amalgam, the higher the speed of pumping the air sample, it is sorbed by the gold surface, and, conversely, the more diluted the amalgam, the worse the wettability of the gold surface and its absorption during sampling (see ibid.).

Thus, in the considered method and device for its implementation, there is a real possibility of searching for ore objects and, based on the results of a mercury-gas survey, to reject ore and non-metallic anomalies.

However, a significant drawback of the known method and device (prototype), limiting its widespread use, is the need to select, for each studied point, 3 ^x 4 ^x adjacent sites that are uniform in sampling quality and distribution of mercury in the soil horizon (see ibid.).

But it is known that even when controlling the quality of mercury gas surveys, the results are consistent with a 2-fold discrepancy, while large discrepancies are practically acceptable even for close points (see instructions for geochemical methods of searching for ore deposits. Moscow, Nedra, 1983). Page 137).

Thus, the results of measuring mercury at different pumping rates can often be associated not with a difference in the concentration of ore amalgams, but with the heterogeneity of the selection of points and the quality of sampling.

In addition, the selection for each studied point of 3 ^x -4 ^x homogeneous sampling sites requires significant labor costs and is actually feasible rather when interpreting individual anomalies already identified by ordinary mercury surveys.

The task is to increase the reliability and simplify the method of prospecting for deposits in microamalgams and create a device that ensures the implementation of the operations of the method.

This problem is solved due to the fact that in the method of searching for ore deposits by microamalgams, which includes taking gas samples from the soil horizon onto a gold sorbent with subsequent desorption and determining its content at different pumping rates of the samples taken through the sorbent, sampling at each measured point is carried out with passing the sample through two consecutive sorbent systems with a speed of not more than 5 l / min, through the first system consisting of one sorbent, and with the number of sorbents in the second system, ensures vayuschih pumping less than 1 L / min through each of them, and content accumulated on the mercury sorbents at different pumping speeds is judged that there ore objects on depth.

A device for searching ore deposits by microamalgams includes a gas sampling hood connected through a dust removal filter and a three-way valve with a mercury filter-absorber and an absorption system, the absorption system is connected to a measuring unit and a power unit, which are interconnected, and the measuring unit is connected to a vacuum pump with adjustable pumping, and the absorption system consists of two sequentially arranged parts connected through an additional three-way valve, the first part consists of one gold sorbent, and the second contains a system of at least two gold sorbents that are identical to the first sorbent and located in such a way that the total flow of the air sample is distributed equally between them.

Figure 1 presents a possible variant of the device that provides the implementation of the proposed method.

Figure 2 shows the results of checking the effectiveness of the proposed method and device for identifying and evaluating ore bodies by amalgams in soil air.

To implement this method carry out the following operations:

1. Install a gas sampling cap on the soil horizon at the point under study.

2. A soil sample is taken for several minutes sequentially through both parts of the absorbing system with a pumping rate of not more than 5 l / min. Moreover, through the first sorbent at the inlet, pumping occurs at a total sampling rate of no more than 5 l / min and is maintained at the entrance to the second part of the system with flow separation through separate sorbents with a pumping rate of no more than 1 l / min.

3. At the end of the sampling, they are discarded from the gold sorbents by heating them and the mercury accumulated first on the second system of gold sorbents and then on the first system is measured.

4. Based on the results of measured mercury concentrations, the presence and content of microamalgams in soil air is judged.

A device for implementing the proposed method includes a gas hood 1 with a dust filter 2, a filter-absorber for mercury vapor 3, a first three-way valve 4, a first system of gold sorbents 5, a second three-way valve 6, a second system of gold sorbents 7, a measuring unit of a mercury photometer 8, block supply 9 and a vacuum pump 10, with adjustable pumping.

The device operates as follows.

At stage I, a soil sample is taken by a compressor through a gas sampling hood 1 and a dust removal filter 2 with a pumping rate of no more than 5 l / min through a sorbent system 5 and no more than 1 l / min through each of the 3 sorbents of system 7, while the position of the three-way valves 4 and 6 ensures the flow of the sample in accordance with the above and further through the measuring unit of the photometer into the atmosphere.

At the second stage, the position of the valve 4 ensures that atmospheric air enters through the mercury filter 3 and the sorbent system 5 and 7 into the measuring unit of the mercury photometer 8, while the sorbent 7 and the desorption of mercury accumulated on the sorbent system 7 are heated and measured.

At the III stage, the position of the taps 4 and 6 ensures the supply of atmospheric air through the mercury filter 3, the sorbent system 5 directly into the measuring unit of the mercury photometer 8, bypassing the sorbent system 7, while the sorbent 5 is heated simultaneously, the mercury is desorbed from it and measured.

In the specified device, air sampling with a constant speed of not more than 5 l / min is provided by the compressor, and various air flow rates in sorbent systems 5 and 7 are due to an increase in the number of channels containing gold sorbents in system 7.

At the same time, equal conditions for total absorption are provided, which depends on the surface area of gold in sorbent systems 5 and 7.

Thus, at each measured point, accumulation on sorbent 5 is associated with the presence of enriched ore amalgams, and accumulation on the sorbent system 7 is mainly due to diluted amalgams, up to pure mercury, that slip through sorbent 5.

Based on the ratio of measured concentrations, a conclusion is drawn about the presence or absence of ore amalgams at the measurement point.

Thus, in comparison with the prototype, the present invention provides greater reliability of measurements with significantly less labor.

In practice, it is commensurate with ordinary mercury-gas surveys, but significantly increases the possibility of detecting ore anomalies. In addition, labor costs and time spent at the shooting point are significantly reduced (at least 2 times).

The total sampling rate at the point is selected based on the number of sorbents in the second system and the limitation of the pumping rate of no more than 1 l / min, through each. In this case, pumping through the first sorbent should not exceed 5 l / min.

Pumping at a rate of more than 1 l / min through each of the sorbents of the second system leads to the loss of amalgams not enriched in ore elements.

Pumping with speeds of more than 5 l / min through the first gold sorbent leads to significant losses even of amalgams enriched with ore elements (see Anishchenko A.Z. and Kirikilitsa S.I. “Methodical recommendations for the operation of field stations of the Oreol type. Simferopol, 1979 g., p. 36).

After sampling, the mercury accumulated on each of the sorbent systems is successively measured, and the presence of ore deposits is judged by the difference in the measured concentrations of mercury.

The proposed method is devoid of the disadvantages inherent in the prototype, since at each point one sampling is performed and there is no need to search for 3 ^x -4 ^x homogeneous sites at the research point.

Figure 2 shows the test results of the developed method and device in a gold deposit with a known location of the ore bodies. Data are presented on the distribution of mercury in soil air over a profile crossing the ore body with a sampling step of 20 m mercury amalgam with and without ore elements.

The work was carried out as follows:

1. At each point, a gas hood was installed on the soil horizon.

2. A soil sample was taken at a rate of 3 l / min through two parts of the sorbent system, in each of which the sample passed over gold at different speeds — 3 l / min through the first part and 1 l / min through each sorbent of the second part.

3. After pumping was completed, the mercury accumulated on each of the sorbent systems for a given measurement point was successively measured.

As follows from the graphs showing the distribution of amalgams, the position of the ore body is reliably distinguished only by enriched amalgams. At the same time, the proposed method and device for its implementation will improve the reliability of the interpretation of the results by obtaining information about the total distribution of mercury on the studied profile.

Thus, the proposed method is more effective and reliable for identifying and localizing ore bodies in comparison with the prototype.

Claims (2)

1. A method for searching ore deposits by microamalgams, including taking gas samples from the soil horizon to an absorbing system that is a gold sorbent, followed by desorption and determining its content at different pumping speeds of the samples taken through the sorbent, characterized in that the sampling at each measured point carried out by passing the sample sequentially through two parts of the absorbing system with a speed of not more than 5 l / min through the first part, consisting of one gold sorbent, and with the number of gold sorbents in the second part, providing pumping at a speed of not more than 1 l / min through each of them, and the presence of ore objects at a depth is judged by the contents of the accumulated mercury on the sorbents at different pumping speeds. 2. A device for searching ore deposits by measured mercury contents in microamalgams, including a gas hood connected through a dust filter and a three-way valve with a mercury filter absorber and an absorption system that is a gold string sorbent, and the absorption system is connected to the measuring unit of the mercury photometer and power supply, which are interconnected, and the measuring unit of the mercury photometer is connected to a vacuum pump with adjustable pumping, characterized in that the glazing system consists of two successively arranged parts connected through an additional three-way valve, the first part consisting of one gold sorbent, and the second contains a system of at least two gold sorbents that are identical to the first sorbent and located so that the total air flow Samples are distributed equally between them.

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