SU1061095A1 - Microamalgam selecting sorbtion method - Google Patents

Abstract

1. DEVICE FOR SELECTIVE SORPTION TO MICROAMALHAM, containing a gas-intake block with a sorbent, a measuring system and a vacuum pump connected in series with each other by a gas pipeline, so that, in order to expand the possibilities of separating, the concentration of mercury by its amalgamic forms, between gas intake in it. An additional chamber with a distributor fixed in it with radial through channels connected to the gas duct and hemisphere is installed with a measuring unit and measuring system, and the gas receiving unit is equipped with gearboxes and two or more KeiMepamy connected in series through a gas pipeline and in each of them there are rotations a disk on the shaft, the sorbent being deposited on the surfaces of the disks and the inner surface of the hemisphere, and the shafts are interconnected and driven through gears, so m a way that the angular speed of rotation of disks sequentially decreased or increased as the distance from the actuator. 2. The device according to claim 1, denounced by the fact that in the additional chamber at the inlet of the gas pipeline there is a distributor installed, made in the form of a semi-sphere with radial channels, you | the surface of which is located inside the hemispheres with a sorbent.

Description

: o: l The invention relates to geochemical methods of prospecting for ore deposits and can be used in the development of equipment for performing integrated gas-port surveys using micro-aluminae, as well as for controlling the contamination of the environment with mercury and its amalgam compounds. A device for sorbing mercury vapors from gas samples is known, comprising a gas intake unit with a chamber having an inlet and an outlet, between which is a porous absorber of gold-coated gold wool, a p-itate unit and a measuring unit. When rolling a gas sample through the chamber, the mercury accumulates on the absorber and is then thermally desorbed and determined photometrically ij in the measuring unit. The drawback of the device is that it can be used to determine only the total content of mercury vapors in the elementary and amalgam states. Information on the forms of finding microamamals with this device cannot be obtained. The sorbent in this device does not work reliably — during continuous operation, the absorber is sintered, which leads to a decrease in the sorbing surface and, consequently, to an unsatisfactory results performance. The closest in technical essence to this is a device for selective sorption of microamalgams consisting of a gas-receiving unit (including a gas sampling cap with a dust removal filter and a gold sorbent), a rotameter, a vacuum pump, a measuring unit — a photometer, a power supply unit, a mercury-absorbing filter. and three-way cranes in the gas pipeline. The gas cap is installed at the test point. Pump a gas sample through a gold sorbent with a different, controlled by a rotameter, speed. Microamalgams accumulated on the sorbent at the time of annealing of the sorbent are transferred to a measuring unit - a photometer where their concentration is determined 2. The drawback of the device is that it does not allow several types of microamalgam to be selected from a single sample: the novelty of the forms of microamalgam, and also does not give a high percentage of sedimentation on the sorbent of slightly sorbing microparticles of mercury and some of its amalgamic compounds, especially at low temperatures. The purpose of the invention is to expand the possibilities of separating mercury concentrations into its amalgam forms. The goal is achieved by the fact that in the device containing a gas receiving unit with a sorbent, a measuring system and a vacuum pump connected in series with each other by a gas duct, an additional chamber is installed between the gas receiving unit and the measuring system with a distributor having radial through channels , connected to a gas pipeline and a hemisphere, and the gas-receiving unit is equipped with gearboxes, a drive and two connected in series through a gas pipeline route or more cameras, in each of which there is a rotating disk on the shaft, the sorbent deposited on the surfaces of the disks and the internal surface of the hemisphere, and the shafts are interconnected and driven through the gearboxes so that the angular velocity, rotation of the disks in series r decreases or increased with distance from the drive. In the additional chamber at the inlet of the gas pipeline, a distributor in the form of a hemisphere with radial channels is installed, the convex surface of which is placed inside, the hemispheres with a sorbent. The device implements a method of separating micromamals according to the wettability (sorption) of the golden sorbent surface. It is known that, depending on the presence of one or another element in combination with mercury, the amalgamating properties of the latter vary. It is also known that gold dissolves slightly in mercury and mercury does not actually dissolve, but only wets the surface of gold. Reducing the amalgam surface tension improves the wettability of gold with mercury. When mercury accumulates on the gold sorbent in the process of pumping a gas sample on the mercury microparticles, the cohesive forces (wettability) with the sorbent and the kinetic energy of their movement in the gas pipelines affect. If kinetic energy is greater than the adhesion forces of the sorbent with some micromamals, the latter do not accumulate on the sorbent. This allows the accumulation of various microamamals on the sorbent alternately. This can be done by changing the speed of pumping a gas sample or by rotating the sorbent at different speeds, which leads to a change in the centrifugal force, which tends to drop mercury microparticles from the sorbing surface. In order to accumulate micro amalgams from a single gas sample at a time, it is necessary to have several cameras with dirty trays connected in series.

The proposed device uses the second way to solve the problem - rotation cqpdeHTOB. For this purpose, rotating disks are used, on the surface of which a sorbent is applied. The disks are installed in chambers connected in series by means of a gas pipeline. The sample enters the first chamber, then the second, and so on. The disks are mounted on shafts, which are connected in series with each other and driven through gearboxes, which allow the disks with a sorbent to rotate at different angular speeds. As a result, one amalgamic form of mercury accumulates on each house disk with a sorbent.

For a more complete extraction of the mouth from the gas sample, an additional camera was installed after the rotating disc chambers. Basically, string sorbents are used in photometers. The gas sample stream only partially touches the surface of the sorbent, which prevents accumulation of all the mercury contained in the gas sample. In order to increase the efficiency of mercury accumulation, a sample stream has been proposed to be directed to the sorbent deposited on the inner surface of the hemisphere. In order for the microparticles to hit the surface of the sorbent at a right angle, the gas sample is directed into the radial channels of the distributor in the form of a hemisphere.

FIG. 1 and 2 show an example implementation of the device.

The device contains a gas intake unit 1 (a gas-collecting cap is not shown), a measuring system 2, a vacuum pump 3 with a rotameter (not shown), an additional cylindrical chamber 4, taps 5-7 and a gas pipeline 8 that connects all the listed units as well as entering the gas receiving unit 1.

The gas intake unit 1 includes cylindrical chambers 9 and 10 connected by a gas duct 8 successively, a reducer li with an angular velocity sensor (not shown), an actuator 12, a filter absorber 13 and taps 14-16. In chambers 9 and 10, disks 17 and 18 with gold sorbent 19 are mounted. Disks 17 and 18 are rigidly fixed on shafts 20, which are interconnected with each other using a gear 11 and also with a drive 12.

In an additional cylindrical chamber 4, a hemisphere 21 is installed with a gold sorbent 22 deposited on its inner surface and a distributor 23 in the form of a hemisphere.

having radial channels 24. The distributor 23 is fixed so that its surface is convex facing the inner surface of the hemisphere 21. The shafts 20 are mounted in sleeves 25, which exclude the influence of the external environment. The inlet and outlet openings of each channel, measures 9 and 10 are located in such a way that the axis of the inlet part of the gas pipeline 8 is perpendicular to the axis of the shaft 20 and is directed along the radius; and the axis of the gas outlet; the wire path 8 — tangential to the corresponding disk 17 or 18. This improves the efficiency of micro-amalgam accumulation and the release of desorbed mercury particles from chambers 9 and 10.

A multichannel can be used as the measuring system 2: an atomic absorption spectrometer; a photometer.

The device works as follows. .

Include the drive 12 gazrpriyomnogo unit 1 with a maximum angular velocity. The rotation is transmitted through the shafts 20 and the gearbox I-d scam 17 and, 1 | The disk 18 rotates at an angle; the speed of the disk is greater (or less) than the disk 17. The bushes 25 provide isolation of chambers 9 and 10 from external | her environment. Cranes are installed in the following position: 5-HELL, 6-HELL, 7-HELL,; 14-АБД, 15-HELL, 16-HELL. The pump 3 is switched on. Since the axis of the inlet part of the gas pipeline 8 is perpendicular to the axis of the shaft 20 and is directed along the radius of the disk 17, the micro particles are amalgams and the sorbent 19 is hit at the most favorable angle of incidence. At the same time, mercury particles accumulate on the sorbent 19 with the element whose cohesive forces exceed the kinetic energy of the particles. Next, the sample through the gas line 8 through the valve 15 enters the chamber 10, where, hitting the sorbent 19 on the disk 18, mercury particles with another element accumulate, possessing a higher (or lower) adhesive force with the gold sorbent than particles accumulated in chamber 9. Next, the gas sample along path 8 through taps 16 and 6 enters an additional chamber 4 through channels 24 of distributor 23, mercury particles that passed through chambers 9 and 10, departing from cannons 24 at the most favorable angle to the inner surface of the hemisphere 21, precipitated on s rbente 22. The sample is then over path 8 through the valves 7 and 5 Iasos 3 enters and exits into the atmosphere.

After pumping the required volume I gas sample pump 3 and the actuator 12 I turn off. Install taps in

Position: 5-db, b-db, 7-db, 14-bds 15-bb, 16-bp. Annealing of the sorbent 19 on the disk 17 is performed and the pump 3 and the actuator 12 are turned on. In this case, the desorbed microhaloids from the outlet opening of the chamber 9 flow along the path through the taps 15, 16, 5, 6 and 7 into the measuring system 2, where the concentration is measured mercury vapor with one element, and then through the pump 3 the desorbed mercury particles are released into the atmosphere. The transport of microgilalgam through tract 8 is carried out by ochshchenim from mercury and mechanical impurities in the filter-absorber 13 with atmospheric air. The pump 3 and the drive 12 are turned off.

Then, putting the taps in position: 5-db, 6-db; 7-DB, 14-BDS, 15-BP, 16-BP, annealing the sorbent 19 on the disk 18, turning on the pump and the actuator 12, and measuring the concentration of mercury with another amalgating element.

After that, the pump 3 and the drive 12 are turned off. The taps are set to the following position: 5-DB, 6-BP, 7-BP, 14-BDS, 15-DB, 16-DB, turn on the pump 3 and drive 12 and anneal the sorbent 22. The atmospheric air coming through the absorber filter 13 and the valve 14 through the path 8 is cleaned of mercury and mechanical impurities and transports the desorbed particles of mercury from the chamber 4 through taps 7 and 5 to the measuring

system 2. The total residual content of weakly sorbing {mercury is measured. Then mercury particles through the pump 3 are released into the atmosphere. Pump 3 and drive 12 are turned off.

Further, operations with new samples are repeated, each being lowered. cycl the angular velocity of rotation of the actuator 12. This will provide information on the concentration in the soil air of mercury vapor in various amalgam forms. If it is necessary to accumulate only the sum of all micromalgae, the cranes are placed in the 5-AD, 6-AD, 7-AD, .14-АБД, 15-БД, 16-БД positions.

In this example, two cameras with rotating disks are used. The number of chambers depends on the required detail of the separation of micro-amalgamic forms of mercury and the work productivity.

The device has the following advantages, ensuring the achievement of a positive effect: increased functionality due to the separation of amalgamation elements / better conditions, precipitation of mercury vapor when determining the total content of its various forms; increased accuracy of determination of mercury content by increasing the quality of its deposition on a hemispherical sorbent, which ultimately will improve the reliability of the discovery of mineral deposits.

Claims (2)

1. DEVICE FOR SELEN- OF SORPTION MICROAMALGAM containing a gas collection unit with a sorbent, a measuring system and a vacuum pump connected in series with each other by a gas pipeline. path, characterized in that, in order to expand the possibility of separating mercury concentrations into its amalgam forms, an additional chamber is installed in it between the gas receiving unit and the measuring system, with a distributor fixed in it, having through radial channels connected to the gas pipeline a path and a hemisphere, and the gas receiving unit is equipped with gears, a drive, and two or more chambers connected in series via a gas path, each of which has a rotating disc to the shaft, moreover, the sorbent is deposited on the surface of the disks and the inner surface of the hemisphere, and the shafts are connected with each other and with the drive through gears so that the angular speed of rotation of the disks decreases or increases sequentially with distance from the drive. 2. The device according to π. 1, characterized in that in the additional chamber at the inlet of the gas path is installed a distributor, made in the form of a half sphere with radial channels, a convex surface of which is placed inside the hemisphere with a sorbent. >