RU2427009C2 - Searching method of ore deposits on amalgams - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: gas samples are taken from surface of soil horizon and they are subsequently passed through system of golden sorbents. At that, sample passing speed through each sorbent of the system is not more than 5 l/min. Available ore deposits are estimated by difference of mercury concentrations which passed through sorbents and entered the mercury analyser to be measured, and were accumulated on them and desorbed to measurement channel of mercury photometre.

EFFECT: higher reliability of searching results and lower labour intensity.

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.

A known method of searching ore deposits by microamalgams (see AS USSR No. 960703, Cl. G01V 9/00 priority of 09/23/82), including the selection at each research point of 3-4 adjacent homogeneous sampling sites, sequential installation of a gas sampling hood at each site, sampling of soil air at different, sequentially increasing sampling rates, determining the content of mercury vapor in the samples taken by a mercury photometer with a gold sorbent, and assessing the presence of ore elements at the study point from eneniyu mercury content at points at different sampling rates.

A device for implementing this method 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 (see ibid.).

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 method under consideration 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 (prototype), limiting its widespread use, is the need for selection for each investigated point of 3-4 adjacent sites, homogeneous in the quality of sampling and distribution of mercury in the soil horizon (see ibid.).

But it is known that even when controlling the quality of mercury-gas surveys, a 2-fold discrepancy is accepted, and even large discrepancies are practically acceptable even for close points (See Instructions for the geochemical methods of souring ore deposits. - M .: Nedra, 1983. p. 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 of 3-4 homogeneous sampling sites for each studied point requires significant labor costs and is actually feasible rather for the interpretation of individual anomalies already detected by ordinary mercury surveying.

It should be noted that the content of mercury vapor in the soil horizon, depending on the region and the studied ore object, varies from n · 10 ^-6 m ² / l to n · 10 ² m ² / l, and the content of ore elements in microamalgams - by 2-3 less than mercury (see ibid.).

Therefore, the technology of sampling and analysis of mercury is necessary, providing its reliable measurements in the range n · 10 ^-8 mg / l ÷ n · 10 ^-9 mg / l, i.e. with its nanogram contents in the soil surface horizon.

The task is to increase the reliability, simplify the method of prospecting for deposits by microamalgams, reduce labor costs, increase the sensitivity of the determination of mercury and increase the sensitivity of the device for implementing the method.

The problem is solved due to the fact that in the method of searching for ore deposits by amalgams, including gas sampling from the surface of the soil horizon, accumulation of mercury from the sample taken on a gold sorbent, followed by desorption and determination of its content, sampling at each investigated point is carried out through a system of gold sorbents located at the inlet of a mercury photometer, with a speed of not more than 5 l / min through each sorbent of the system and the difference in the concentrations of mercury passing through the sorbents and accumulated on them, they judge the presence of bottom deposits.

The proposed method is devoid of the disadvantages inherent in the prototype, since one sampling is carried out at each point and there is no need to search for 3-4 homogeneous sites at the research point, therefore the measurement of enriched and diluted ore amalgams is carried out in the course of one sampling.

The method can be implemented, for example, using a device including a gas hood with a dust filter, a gold string sorbent, a vacuum pump with adjustable pumping, a measuring photometer, a power supply, a filter, a mercury absorber and a three-way switching tap, at least one additional switching valve is introduced identical gold sorbent, and the sorbents are located in parallel in the sample stream sampled.

The number of sorbents in the system is selected depending on the expected amount of mercury accumulation, and the sampling rate does not exceed 5 l / min × n, where n is the number of sorbents used in the system.

Figure 1 presents one of the possible variants of a block diagram of a device that implements the method.

Figure 2 shows graphs of the distribution of mercury in soil air obtained during the work with the invention in one of the deposits with a known geological section and the location of the gold ore body.

To implement this method, perform the following operations:

1. At the measurement point, a gas hood is installed on the soil horizon.

2. A soil sample is taken for several minutes at a pumping rate of no more than 5 l / min through each of the gold sorbent systems at the inlet of a mercury analyzer operating without preliminary selection of mercury on gold using the Zeeman effect (for example, the RA-915 mercury analyzer) .

3. Measure the mercury content in the sample passing through the gold sorbents and entering the mercury analyzer.

4. At the end of sampling, the system of gold sorbents is heated and the accumulated mercury is discharged into the measuring channel of the mercury photometer.

5. Based on the measurement results of mercury that has passed through the gold sorbents and accumulated on it, the presence of ore deposits 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 three-way valve 4, a system of three gold sorbent absorbers 5, a measuring unit 6, a power unit 7 and a vacuum pump 8 with adjustable pumping.

The device operates as follows.

At stage I, the compressor 8 provides sampling of soil air at a rate of no more than 5 l / min through each of the sorbents of the system with a gas hood 1 through a dust filter 2 and a system of gold sorbents 5 into the measuring channel of the mercury photometer 6, while the position of the 3-way valve 4 ensures the receipt of the sample taken, as described above, while mercury is measured in the sample passing through the gold sorbent and entering the measuring channel of the photometer.

At stage II, at the end of the sampling, the valve 4 is switched, the atmospheric air is pumped by compressor 8 through the mercury filter 3 and the gold sorbent system 5 into the measuring channel of the mercury photometer 6, while the sorbent system 5 is heated, the mercury accumulated on it is desorbed and measured.

The ratio of mercury accumulated and measured on gold at a pumping speed of 5 l / min and mercury directly received and measured during pumping through a gold sorbent into the measuring channel of the photometer indicates the presence of ore nanoamalgas.

Thus, in comparison with the prototype of the present invention provides greater reliability of measurements with a significant reduction in labor costs, because allows measurements from a single sampling point for large sample volumes.

In practice, it is commensurate with ordinary mercury-gas surveys, but significantly increases the possibility of detecting ore anomalies. Labor costs and time spent at the shooting point are reduced by two to three times.

The total pumping rate is selected based on the number of sorbents and the rate of extraction through each sorbent not more than 5 l / min, because a pumping speed of more than 5 l / min through a gold sorbent leads to amalgam losses, even enriched with ore elements (see Anishchenko A.Z. and Kirikilitsa S.I. Methodological recommendations for the operation of field stations of the Oreol type. - Simferopol, 1979. , p. 36).

The number of sorbents and the pumping rate associated with this limitation are selected based on the observed concentrations of amalgam.

At the same time, amalgams enriched with ore elements are sorbed by gold sorbents at sample pumping speeds of 5 l / min each, and diluted amalgams go directly to the measurement channel, since they are not retained by gold at such speeds.

After measuring the contents of the diluted mercury amalgam in the sample, the sorbent system is heated, the mercury analyzer is discharged and the amount of accumulated mercury amalgam enriched in ore elements is measured and measured. By the difference in the concentrations of mercury passing through the sorbent and accumulated on it, the presence of ore nanoamalgas is judged. At the same time, sampling at a rate of up to 5 l / min per sorbent allows one to increase the measured mercury signal to reliable measurements of amalgam nanoconcentrations.

Figure 2 shows graphs of mercury in soil air, measured over a known gold ore body, obtained using the proposed method and device that implements it.

The survey was conducted along a profile intersecting the ore body in steps of 20 m with a device having a system of three gold sorbents.

The work was carried out in full accordance with the operations of the invention:

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

2. Soil air samples were taken at a rate of 5 l / min for 5 minutes through a system of 3 gold sorbents into the measuring channel of a mercury photometer (RA-915). The total sampling rate was 15 l / min.

3. The mercury content in the sample was measured, which passed through a system of gold sorbents and entered the measuring channel of the photometer.

4. At the end of the sampling, desorption and measurement of mercury accumulated on a system of 3 gold sorbents were carried out.

5. The obtained results of the measured mercury passed through the gold sorbents and accumulated on them and measured, were processed and analyzed.

The processed data are presented in the form of 2 graphs tied to the points of the worked profile. As follows from the above data, the position of the ore body is confidently distinguished by enriched amalgams. The proposed method allows to increase 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 allows you to confidently allocate ore bodies in weak mercury fields.

Claims (1)

A method of searching for ore deposits by amalgams, including gas sampling from the surface of the soil horizon, accumulation of mercury from the sample taken on a gold sorbent, followed by desorption and determination of its content, characterized in that the selection at each test point is carried out through a system of gold sorbents located at the entrance mercury photometer, with a speed of not more than 5 l / min through each sorbent of the system, and according to the difference in the concentration of mercury passed through the sorbents and received for measurement in the mercury analyzer, and n accumulated on them and desorbed into the measuring channel of a mercury photometer, they judge the presence of ore deposits.

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