SU1698306A1 - Method of cleaning gases from mercury vapors - Google Patents

Abstract

The invention relates to non-ferrous metallurgy and can be used in the production of mercury from ores and concentrates. The purpose of the invention is to increase the degree of mercury recovery and the performance of the cleaning process. Mercury-containing gases are cleared of mercury by passing them through keaocevny sand, on which, a layer of gold is deposited with a thickness of 3000-4000 And 1 table. 2 or

Description

The invention can be used in non-ferrous metallurgy in the production of mercury from ores and concentrators.

A known method of purification of mercury-containing gases from mercury using a solid sorbent, in which it uses hydroponite as a sorbent. So, when the content of mercury in air is 0.000125 mg / l after treatment with hydroperiod, its content decreases to 0.0000002 mg / l.

The disadvantage of this method is to reduce the activity of the sorbent during subsequent use until its complete destruction, a high consumption of sorbent.

Closest to the present invention is a method for purifying mercury-containing gases from mercury, in which a candle of calcination of mercury-containing ore is used as a sorbent.

The disadvantages of this method are: reduced activity of the sorbent during subsequent use, the need for periodic unloading and replacement of the sorbent. In addition, the multistage purification process requires high-temperature heating, i.e. Additional energy consumption.

The efficiency of mercury extraction is not high enough, namely, when the content of mercury in the flue gases of 54–67 mg / m, the mercury content in the exhaust gases was no more than 9 mg / m when the mercury was recovered in the calcine, 83%.

The purpose of the invention is to increase the degree of mercury recovery and the performance of the cleaning process.

The goal is achieved by haem, that according to the method of gas purification from mercury vapor using solid sorbents, quartz sand is used as a sorbent, on which a layer of gold is deposited with a thickness of 1 3000 to 4000 A

Comparative analysis with the well-known shows that the proposed technical solution is different in that quartz sand is used as a sorbent, on which a layer of gold with a thickness of 3000 to 4000 A is deposited.

Since sand has a highly developed surface and due to the fact that gold is easily amalgamated, the degree of amalgam formation of mercury on the surface of gilded sand is very high, with

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In this case, mercury is easily released with a small base, roaring (100 - 200 ° C).

The proposed method of purifying gases from pyros PI.MH is carried out as follows.

The gas containing gas is passed through a layer of silica sand coated with gold, the mercury is sorbed by the latter, forming mercury amalgam on the surface of the gilded layer, the cleaned gases are removed, the sand is heated to 100 - 200 ° C and the separated mouth is also removed.

FIG. Shows a section of a device for purifying mercury gases, an external view; Fig. 2 shows a number of such sections communicating with each other by collectors.

The device contains a cylindrical chamber 1 with a lid 2 with a supporting metal grid 3 located inside, on which is placed a layer of quartz sand coated with gold coating 4. Under the grid 3 a heater 5, an inlet manifold 6 and a valve 7, collector 8, exhaust manifold are installed 9 and valve 10, pressure gauge 11,

The proposed method is as follows.

Quartz peg-ok is preliminarily subjected to vacuum thermal sputtering of an ultrathin gold layer (the layer of deposited gold is 3000–4000 A, thus 2 g of gold per 1 kg of sand). Then the quartz sand with gold coating applied through cover 2 is loaded into the cylindrical chamber and placing it on the grid 3. The gas to be cleaned through the inlet pad 6 and the valve 7 is discharged into the chamber, the laplenia is fixed by the pressure gauge 11, while the Hd of the surface of the gilded sand forms mercury amalgam, the purified gas exits logs 9 and veins il 10, after which the sand is warmed up by the applicant 5 to 100–200 ° C, and the extracted mercury enters the collection 8, after which it is discharged from the device

In the proposed method of purifying gases from mercury vapors, quartz sand is used as the sorbent, on which a layer of gold is deposited with a thickness of 3000 - OOO K.

This range is due to the following circumstances. With increasing / greater than 4000 A, the degree of extraction of mercury from mercury-containing gases practically does not increase, however, the consumption of gold increases, with thicknesses less than 3000 A, the coating becomes uneven and the entire sand surface does not participate in the cleaning process, and therefore the degree of mercury recovery also getting worse.

The experimental data are shown in the table.

It was established experimentally that with the passage of a gas with a mercury content of 100.0 mg / m at a rate of 1 l / min at room temperature, 10 mg / m3 of mercury remains in the gas, i.e. extraction efficiency up to 0.0001%. The sand sorption capacity is 700 µg mercury per kg of sand. Thus, in comparison with the known method, the proposed method improves the degree of extraction of mercury by the purification process performance due to the fact that gold-coated gold sand is used as a sorbent, which is easily amalgamated and with a slight preheating, mercury is easily released. the need for the procedure of periodic discharge of the sorbent.

The mercury content after purification with an initial content of 100 mg / m and a speed of 1 l / min at room temperature is presented in the table.

Claims (1)

Thus, the most optimal thickness of gold is 3000-4000 A. Claims The method of cleaning mercury-containing gases from mercury vapor, including passing the gas through a solid sorbent, characterized in that, in order to increase the degree of mercury recovery and the performance of the cleaning process, quartz sand is used as a sorbent, on which a layer of gold with a thickness of 3000-4000 A is applied. Thickness the flow of blood, A Residual FROM TI and (TswirfMTrOTOTWL P  DYPICH i jTfff jTTrOWTnr r5T5 | .tuvggztgppppug Fig2 about. about n5s about , § 5С  g I X B CD LM