RU2295583C1 - Demercurizer - Google Patents

Abstract

FIELD: heavy metal pollution elimination.

SUBSTANCE: invention is intended for use in technologies of purifying various media from mercury pollution. Demercurizer of invention contains elementary sulfur and sulfide ion source, the latter being a by-product in sodium hydroxide-mediated absorption of hydrogen sulfide and homologues thereof produced in synthesis of dialkyldithiophosphoric acid.

EFFECT: enhanced process efficiency and reduced expenses.

1 tbl, 8 ex

Description

The invention relates to the field of use of chemical reagents for environmental purposes and can be used in technological processes for the purification of various environments from mercury pollution.

As you know, those chemicals are those that are used to reduce the rate of evaporation (desorption) of mercury or its compounds from sources of secondary pollution and facilitates the mechanical removal of mercury, dust of its compounds and technological solutions (suspensions) contaminated with mercury and its compounds from the floor surface, foundations, equipment, working and laboratory furniture.

Physico-chemical processes that occur during the interaction of mercury or its compounds with demercurizators are the emulsification of mercury, oxidation of mercury, and the conversion of mercury or its compounds into non-volatile substances.

Among the demercurisers used in the conditions of "mercury" production, there are more than a dozen reagents, among which sulfur is also mentioned (Mercury. Normative and methodological documents / Reference book. - St. Petersburg, 1999. - P. 45).

In the same note, the editorial note notes that the use of most of the listed demercurisers in non-production rooms, in the absence of a mercury-resistant floor covering, the possibility of spillage, etc., is ineffective.

The use of sulfur as a demercurizator is based on the fact that it interacts with free mercury chemically binds it to sulfide, that is, converts it into a fixed, non-volatile and safe to handle compound. The advantage of using sulfur is that it can easily be reacted with mercury at room temperature.

But in the process of demercurization, in the case of the release of mercury vapor, sulfur itself is ineffective, since it does not emit hydrogen sulfide, which can interact with these vapors.

The use of sulfur as a demercurizer in various demercurization technologies is limited due to its relatively low efficiency, but at the same time it can be promising, since sulfur is not a scarce and expensive reagent and the problem is that, using the known advantages of sulfur, opportunities to strengthen its demercurizing properties.

Known demercurizator containing sulfur powder (Pugachevich P.I. Work with mercury in laboratory and industrial conditions. M .: Chemistry, 1972. - S.308). This reagent was used to demercurize the surfaces of stainless steel instruments, as well as from lightly amalgamating metals (copper, brass and bronze), and when sulfur is wiped with contaminated surfaces, heat is generated sufficient to form mercury sulfide, which is easily erased by paper.

The use of sulfur here is specific and is not the basis for its use with the same effect in the treatment of other environments contaminated with mercury.

A known demercurizator containing a 4-5% sodium polysulfide solution obtained by heating crystalline sodium sulfide to 105 ° C, followed by the gradual addition of sulfur with stirring until the sulfur is completely dissolved and the sodium polysulfide obtained is diluted with water to the desired concentration (ibid., P. 304-305). This reagent was used to treat surfaces contaminated with mercury in the second stage of demercurization.

The preparation of this demercurizer requires high temperatures and the use of a special reagent (sodium sulfide).

Known demercurizator containing sulfur and a solution of sodium sulfide (ibid., P. 304). This reagent was also used to clean surfaces from mercury and organic mercury compounds in the final stage of demercurization. Sulfur in an amount of up to 10% in this case was added to a 5-10% aqueous solution of sodium sulfide to accelerate the reaction due to the formation of sodium polysulfide.

The demercurizer thus obtained is intended for limited use and requires an additional chemical demercurization step using other reagents before using this demercurizer.

The problem to which the invention is directed, is to increase the efficiency of the processes of demercurization of various environments by expanding the functional and technological properties of the demercurizer.

This problem is solved in that the demercurizer contains elemental sulfur and a source of sulfide ions, while the latter uses a by-product obtained by the absorption of hydrogen sulfide and its homologues formed during the synthesis of dialkyldithiophosphoric acid, with sodium hydroxide solution.

The use of a demercurizator containing elemental sulfur and a source of sulfide ions makes it possible to obtain a synergistic effect from the combined action of the components of the demercurizator, which consists in both the action that they exert on each mercury and the effect on each other.

The use of a by-product as a source of sulfide ions allows the use of waste from the main production. Due to its relatively low cost, this waste does not need to be reactivated, and storage does not create significant environmental pollution.

Obtaining a by-product by absorption of hydrogen sulfide and its homologues resulting from the synthesis of dialkyldithiophosphoric acid with sodium hydroxide solution makes it possible to obtain a more affordable reagent, more active than other sources of sulfide ions, providing sulfur interacting with metallic mercury and / or its ions, more active state from a thermodynamic point of view.

The product’s action is based on the fact that in the process of interaction with sulfur and mercury it releases hydrogen sulfide, which binds mercury vapor, and also, due to the presence of alkali in it, removes the oxide film from mercury, leading the latter to a more reactive state and thereby accelerating the reaction . Also important is the fact that this product is safe both in the process of its receipt and storage, and in its intended use.

As a source of sulfide ions, the above product is used, including sodium sulfides and water in the following components, wt.%:

Sodium sulfides, not less 25 Water, no more 75 The ratio of sulfur to sodium is not in mass. parts, not less 1: 1.

The use of demercurizator is as follows. Analytically or experimentally, according to the results of experimental treatments, the necessary and sufficient amount of the components of the working solution is determined, the necessary volume of the aqueous solution is formed on the basis of the specified product (base solution) and sulfur is introduced into it with stirring. As sulfur, you can use technical sulfur (natural or gas; lump or ground) according to GOST 127-64.

Introduction to a 25-30% working solution of sulfur, taken in the amount required for processing a particular medium, provides a solution of a mixture of sodium polysulfides (multisulfur compounds) with different sulfur contents.

The resulting sulfide solution is used at room temperature or heated, and it is treated with a mercury contaminated medium.

The ratio between the components can vary widely depending on the type of medium treated with mercury contamination, processing conditions and MPC requirements for mercury in purified media and the type of mercury compound (inorganic or organic) or the state of the mercury in the elemental state.

The examples illustrating the effectiveness of the use of the demercurizer according to the invention are grouped so that in each pair of examples the effect on any of the mercury-contaminated media of the demercurizer based on sulfur and sulfur alone in a solution of the specified product is shown. In all cases, the temperature of both the demercurizer and the processed media was maintained at room temperature, which allows one to evaluate the effectiveness of the demercurizer even under conditions that are not optimal for one or another example.

Examples 1-2. Air is subjected to the treatment, contaminated with mercury vapor, under conditions simulating air pollution in a production room, for example, a broken mercury thermometer.

Demercurizators are prepared by introducing sulfur and water into the specified sulfur and water product to the desired concentration and mixing. Hydrogen sulfide desorbed from the working solution, interacting with mercury vapors in the air, condenses them with the formation of a stable protective film of mercury sulfide on drops of mercury.

The conclusion about the effectiveness of demercurization is made on the basis of analysis for mercury in the air of the working area (its content should not exceed the average shift maximum concentration limit - 0.005 mg / m ³ ).

Examples 3-4. The treatment is subjected to wastewater having a pH of 4, contaminated with mercury ions, placed in open glass vessels by adding a working solution with stirring for 5 minutes. A suspension of sulfur in water is added to one sample, and a solution of sulfur in the specified product is added to another.

A source of sulfide ions is introduced with an excess of 40% compared with the stoichiometric amount of mercury until pH 10 is formed. High alkalinity in the wastewater is necessary to reduce the emission of hydrogen sulfide from it and is ensured by the presence of caustic soda and sodium sulfides in the working solution. The high alkalinity of the solution ensures the presence of hydrogen sulfide compounds in the form of a molecularly dissolved H ₂ S gas, hydrosulfide ions HS ^- , and also sulfide ions S ^2- . Hydrosulfide and sodium sulfide are highly soluble in water.

In all cases, after the formation of mercury sulfides has ended, the precipitate is allowed to settle, the solution is drained from the vessels, and the sulfide is sent for washing, which is carried out by decantation with hot water. Washing is carried out to completely remove alkali and sulfides. The washed mercury sulfide is filtered and dried at 100-120 ° C.

The conclusion about the effectiveness of demercurization is made on the basis of analysis of mercury in wastewater (its content should not exceed the MPC 0.0005 mg / l).

Examples 5-6. The surface is treated in the form of a coating of linoleum, under conditions imitating contamination of the living room floor surface with metallic mercury, for example, from a broken mercury thermometer.

A suspension of sulfur in water and a solution of sulfur in the product and water are prepared in metal baths, and floor and flat horizontal surfaces are treated by pouring until the entire surface is wettable.

The conclusion about the effectiveness of surface demercurization is made on the basis of an analysis of the air environment for the content of mercury vapor one day after the end of processing (the average daily maximum concentration limit for mercury in residential air should not exceed 0.0003 mg / m ³ ).

Examples 7-8. Removable parts, for example, steel, dismantled equipment of the electrolysis shop, which operated for a long time under conditions of mercury contamination of their external surface, are subjected to treatment.

The resulting suspension of sulfur in water and a solution of sulfur in the product is used to process parts in a bath whose dimensions ensure complete immersion of products subjected to demercurization.

Details of a simple configuration with a medium degree of corrosion after their preliminary processing by cleaning them from visible mercury, corrosion products and old anti-corrosion coatings made by known methods are exposed to a 35% aqueous working solution for 2 hours with periodic raising and lowering into the solution . After completing the treatment cycle, the parts are washed in another bath with running water.

The conclusion about the effectiveness of the demercurization of equipment is made on the basis of an analysis of mercury flushing from the equipment surface (removable equipment should not contain more than 100 mg / m ^{2 of} mercury on the outer surfaces).

Comparative data indicating an increase in the processing efficiency of the proposed demercurisator in comparison with the known, are given in the table.

As can be seen from the table, the use of the proposed demercurizator provides a more efficient treatment of various media exposed to mercury contamination, which determines a more complete cleaning of these media from mercury and puts these media in a state where the mercury content in them does not exceed acceptable standards (MPC).

Thus, the proposed demercurizator provides an increase in the effect of sulfur treatment of various media subjected to mercury pollution, while reducing the cost of treatment and can significantly expand the scope of elemental sulfur in demercurization processes.

The use in the conditions of the city of Togliatti of a demercurizer, known as a preparation under the name "Polition" for cleaning various media, including waste not specified in the examples, showed its high efficiency, ease of use and safety in handling it.

Example No. Type of environment contaminated with mercury Processing Conditions Mercury content The composition of the demercurizer The ratio between the components of the demercurizer, volumetric parts Demercurizer consumption before processing after processing 1-2 Room air 1. Sulfur
2. Sulfur + product (according to the invention) ---
1: 1 0.2 l per 1 m ³
- // - 0.05 mg / m ³
0.05 mg / m ³ 0.08 mg / m ³
0,0003 mg / m ³ 3-4 Industrial drains 1. Sulfur
2. Sulfur + product (according to the invention) ---
1:10 1 liter per 1 m ³
- // - 0.5 mg / l
0.5 mg / l 0.5 mg / l
0,0005 mg / L 5-6 Hard surface indoors 1. Sulfur
2. Sulfur + product (according to the invention) ---
2: 1 0.5 l per 1 m ²
- // - 150 mg / m ²
150 mg / m ² 15 mg / m ²
3 mg / m ² 7-8 Hard surface equipment 1. Sulfur.
2. Sulfur + product (according to the invention) ---
5: 1 0.3 l per 1 m ²
- // - 250 mg / m ²
250 mg / m ² 200 mg / m ²
10 mg / ^m2

Claims (1)

A demercurizator containing elemental sulfur and a source of sulfide ions, characterized in that a by-product obtained by absorption of hydrogen sulfide and its homologues resulting from the synthesis of dialkyldithiophosphoric acid with sodium hydroxide is used as this source.