RU2175664C1 - Method for mercury removal from objects contaminated by mercury "e-2000" and mercury removal composition mercury "e-2000+" - Google Patents

Abstract

FIELD: sanitary. SUBSTANCE: invention relates to methods of removing mercury from industrial premises, research laboratories, patient care institutions, secondary schools, infant schools, and apartments. Proposed method consists in applying polysulfide solution onto mercury contaminated surfaces followed by removal of resulting mercury compounds or their deposition. More specifically, one first applies 10- 15% solution of oxyethylenated alcohol (polyethylene glycol monoalkyl ether C_nH_2n+1O(C₂H₄O)_m where n=16-18 and m= 21) and, after exposition for at least 15 min, applies polysulfide solution, in particular 4-10% calcium polysulfide solution, to which surface is exposed for at least 8 h. Composition "E-2000+" contains, wt %: above-indicated sulfur-containing substance 5- 9, above-indicated ether-type surfactant 10-15, complexing agent (diethylenetriaminepentaacetic acid) 0.2- 0.5, and water - the balance. EFFECT: enabled reduction of mercury vapor concentration in room air to its permissible values. 2 cl, 1 tbl, 6 ex

Description

 The invention relates to methods for cleaning objects from mercury, in particular to demercurization of industrial buildings, laboratories of research institutes, medical and medical institutions, schools, preschool institutions, apartments.

 Demercurization of urban environment objects - residential, public and industrial premises contaminated with mercury is an urgent environmental problem.

 Often the causes of mercury pollution are violations of the rules for working with mercury-containing devices, the rules for the transportation and storage of mercury, industrial accidents, which are the causes of foci of air pollution in residential and public buildings with mercury vapor or fumes of Hg-containing devices. In this regard, the elimination of mercury pollution, i.e. demercurization of urban environment facilities, which includes mechanical and chemical processing of the facility, strangulation and processing of demercurization products.

 One aspect of this problem is the question of the type and properties of the end products of the interaction of chemicals (hereinafter referred to as “demercurisers”) used for demercurization, with mercury vapor and mercury adsorbed on various surfaces. Since the effectiveness of demercurization is largely determined by the stability of the final reaction product, promising are the drugs that convert mercury to mercury sulfide, the most stable compound corresponding to the natural form of mercury-cinnabar.

 A comparative analysis of various demercurizators carried out in laboratory conditions (preparations were compared, the effects of which, in theory, result in the formation of mercury sulfide), performed using atomic absorption, X-ray diffraction, and chemical analysis methods, showed the following, see table.

 (A preparation based on calcium polysulfide is conventionally designated as "E-2000" - by the name of the method).

 As can be seen from the table, when treating materials contaminated with mercury with sodium sulfide solutions, the main form of mercury in demercurization products is water-soluble or unstable compounds. At the same time, a significant amount of free mercury remains - from 13.8 to 66.8%.

 When exposed to sodium polysulfide, the mercury sulfide content is 22.6%, and the free mercury content is reduced to 2.2%.

 Potassium persulfate-based preparation is comparable in effectiveness with sodium polysulfide - the content of free mercury is 2.2%. However, the sulfide form of mercury (its most stable compound) is absent in the products of demercurization.

 Despite the relatively high content of sulfide form (49.1%) in the products of demercurization formed using sodium thiosulfate, a significant amount of free mercury (20.5%) does not allow us to consider this drug as an effective demercurizer.

 In contrast to the above, the effect of the preparation based on calcium polysulfide provides the conversion of mercury mainly to mercury sulfide (up to 820%), in addition, the pre-sulfide form is present in the products of demercurization, i.e., mercury adsorbed by the sulfide ion transforms over time in mercury sulfide.

 From the prior art, a method is known for cleaning rooms from mercury by treating contaminated surfaces and places of accumulation of mercury with an aqueous solution of ferric chloride, followed by removal of water-soluble compounds of mercury with washing solutions (see Pugachevich P.P. Work with mercury in laboratory conditions.- M .: Chemistry, 1972, p. 305).

There is also a method of cleaning rooms from mercury by treating contaminated surfaces and places of accumulation of mercury with a 5% aqueous solution of hydrogen peroxide with a flow rate of 0.3 ... 0.5 l / m ² (see AS USSR N 266727 Mcl C. 22 B 43/00, 1968).

However, these methods are not effective enough, because do not provide a reduction in mercury vapor in indoor air to the maximum permissible concentration (MPC = 0.0003 mg / m ³ ).

 There is also a method of demercurization of premises, which consists in sequential surface treatment with solutions of copper sulfate, potassium iodide and sodium thiosulfate A.C. USSR, N 1157103, C 22 V 43/00, 1983

 The disadvantage of this method is the high aggressiveness of the drugs used: the gaseous iodine formed during the reaction is toxic and adversely affects instruments and equipment.

 As a prototype of the invention, the authors chose a method of treating surfaces contaminated with mercury with a solution of sodium polysulfide (see Pugachevich P.P. Work with mercury in laboratory conditions.- M., 1972, p. 304).

 The disadvantage of the prototype method is that the treatment of surfaces contaminated with mercury using sodium polysulfide leads to the formation of mercury sulfide, followed by its dissolution in excess reagent and the formation of a compound from which mercury can be regenerated, i.e. demercurization effect is short-lived. In addition, this preparation does not provide for the removal of adsorbed mercury from micro-cracks, pores and other defects of the treated surface.

 The technical problem solved by the invention is to increase the efficiency of demercurization of premises while achieving the long-term (indefinite) effect of mercury removal.

The solution to this problem is provided by the fact that the method of demercurization of objects contaminated with mercury - "E-2000", including applying to the surface contaminated with mercury, a polysulfide solution followed by removal of the obtained mercury compounds or their deposition on the treated surfaces, according to the invention, first on the surface is applied 10-15% solution of ethoxylated alcohol, which is a monoalkyl ether of polyethylene glycol C _n H _{2n + 1} O (C ₂ H ₄ O) _m , where n = 16-18; m = 21, and after exposure to this solution for at least 15 minutes, a 4-10% solution of calcium polysulfide is applied with exposure for at least 8 hours.

The technical result of using the proposed invention is the conversion of mercury, mainly, to mercury sulfide, which reduces the concentration of mercury vapor in indoor air to MPC (MPC = 0,0003 mg / m ³ ).

 In some cases (spilling a small amount of mercury in hospitals, domestic premises, when mercury from thermometers or broken fluorescent lamps falls on the floor surface of the room), it is advisable to have an effective demercurization drug to urgently remove mercury pollution and prevent mercury infection of the entire room.

With this in mind, the authors proposed a composition for demercurization under the code name "E-2000 ⁺ ", which is an analogue of "E-2000".

 From the prior art (in terms of composition) known composition for demercurization, including a sulfur-containing compound, ethylenediaminetetraacetic acid and water (see US patent N 2774736, Mcl 252-197, 1956).

However, this composition is not effective enough, i.e. its use does not reduce mercury vapor in indoor air to the maximum permissible concentration (MPC = 0.0003 mg / m ³ ).

 The closest analogue of the invention (in terms of the composition for demercurization) is a composition for demercurization of objects contaminated with mercury, containing a sulfur-containing compound, complexing agent and water (see AS USSR N 1051103, M. class. With 09 K 3/00, 81 g.).

 However, this composition is intended mainly for demercurization of metal surfaces and is not suitable for processing rooms.

 The technical problem solved by this embodiment of the invention is the creation of a composition for demercurization, which provides effective cleaning of rooms with relatively small, random spills of mercury, for example, in hospitals and apartments (destruction of thermometers, fluorescent lamps, etc.), while achieving a long duration (in limit - perpetuity) of the mercury removal effect.

The solution to this problem is provided by the fact that the composition "E-2000 ⁺ " for demercurization of objects contaminated with mercury, containing a sulfur-containing substance, a complexing agent and water, according to the invention, it additionally contains a surfactant - ethoxylated alcohol, as a sulfur-containing substance - calcium polysulfide and as a complexing agent - diethylenetriaminopentaacetic acid - HCOOCH ₂ N [CH ₂ CH ₂ N (CH ₂ COOH) ₂ ] ₂ , in the following ratios of components, wt.%:
Calcium Polysulfide - 5-9;
Ethoxylated alcohol - 10-15;
Diethylenetriaminopentaacetic acid (stabilizer) - 0.2-0.5;
Water - The rest.

 With a lower than indicated content of ingredients, the effectiveness of demercurization decreases, with a larger one, the efficiency increases slightly, however, the cost of the composition increases significantly and the consumption of components increases significantly.

 The technical result of the use of the proposed invention is the implementation of the conversion of mercury on the surface of objects, mainly, to mercury sulfide and thereby ensuring a reduction in the concentration of mercury vapor in indoor air to MPC.

 The proposed method of demercurization is as follows.

 A solution of ethoxylated alcohol is preliminarily applied to the surface contaminated with mercury, which moistens the surface and penetrates all its defects (microroughnesses, cracks, gaps). In this case, the dispersion of contaminants and stabilization of the resulting dispersion occur, as a result of which the contaminant film containing adsorbed mercury is pushed off the surface. Subsequent exposure to a solution of calcium polysulfide leads to the conversion of mercury to mercury sulfide - its most stable form. In this case, dissolution of the formed mercury sulfide in excess of the reagent (calcium polysulfide) does not occur.

 It was experimentally established that the minimum required time for dispersing contaminants is at least 15 minutes. The time of subsequent exposure to a solution of calcium polysulfide is at least 8 hours.

Note ^* Industrial hydroxyethylated alcohols are produced in Russia under the trademark "Oksanoly", in the USA - Brij, in France - Ukanil.

 The results of checking the effectiveness of the proposed method in domestic and industrial premises are given in examples 1-5.

When performing demercurization using the “E-2000 ⁺ ” composition, the surfactant included in its composition, ethoxylated alcohol, moistens the treated surface and disperses mercury contaminants into the solution solution layer, where mercury reacts with calcium polysulfide. The complexing agent - diethylenetriaminopentaacetic acid ensures the stability of the demercurization preparation, which increases the effect of purification from mercury. (The specified preparation is named by the authors - "E-2000 ⁺ ").

Thus, the effect of the drug "E-2000 ⁺ " is similar to the combined effect of the monoalkyl ether of polyethylene glycol and calcium polysulfide discussed above (when describing the method).

The result of verifying the action of the proposed composition is shown in Example No. 6 (part of the work on demercurization shown in Example No. 4 was carried out using the drug "E-2000 ⁺ " in classrooms of schools No. 1113; 7; 14; 50; 171; 397; 353 ; 518; 588; 1215).

Example 1. On the surface / linoleum, tile / contaminated with mercury, a solution of ethoxylated alcohol / monoalkyl ether of polyethylene glycol C _n H _{2n + 1} O (C ₂ H ₄ O) _m , where n = 16-18; m = 21, carefully processing cracks, surface defects. The content in the solution of the active substance is 10% by weight. After 15 minutes, a 5% solution of calcium polysulfide is applied, the effect of which is carried out for 8 hours. After this, the products of demercurization are removed with a rag moistened with water.

Example 2. On the surface / cement, concrete / contaminated with mercury, a solution of ethoxylated alcohol / monoalkyl ether of polyethylene glycol C _n H _{2n + 1} O (C ₂ H ₄ O) _m , where n 16-18; m = 21. The active substance content is 10% by weight. After 15 minutes, a 10% solution of calcium polysulfide is applied. Demercurization products from these surfaces are not removed. The final stage of demercurization is the implementation of cement screed.

 The use of the proposed method of demercurization at facilities contaminated with mercury (schools, industrial building, storage of mercury-containing aggregates for military purposes) has shown its high efficiency (see also Acts attached to this application).

 Example 3. (Production inspection carried out in the premises of the storage of the military unit).

 The neutralization of mercury-containing materials (cement dust, applied soil, garbage) was carried out by converting mercury into stable compounds that do not pose an environmental hazard.

Demercurization was carried out using the proposed technology "E-2000"; the total area subjected to demercurization is 3000 m ² .

As a result of the above set of demercurization works, the mercury vapor content in the air was reduced to MPC (MPC = 0.0003 mg / m ³ ) by converting mercury that contaminated the materials of the storage structure (wall plaster, floor cement, applied soil) to the most stable its compound is mercury sulfide, which is not an environmental hazard, which indicates the sufficient effectiveness of demercurization measures.

 Example 4

 In order to eliminate mercury pollution detected in physics and chemistry classrooms at schools of the Central Administrative District (Moscow) NN 19; 40; 123; 1240; 1258; 1323; 343; 1276; 643; 34:45; 232; 235; thirty; 82; 1113; 7; 14; fifty; 171; 397; 353; 518; 588; 1215; 1203; 414; 1278; 1652, a set of demercurization measures was carried out, which included: a detailed examination of objects for mercury pollution (determination of the gross content of mercury and its forms), chemical treatment of objects, neutralization of mercury-containing materials (backfilling of the underground space, cement screed) by converting mercury into stable compounds that do not represent environmental hazard.

Demercurization was carried out using the proposed E-2000 technology, as well as using the E-2000 ⁺ preparation.

 As a result of the above complex of demercurization works, the sanitary-ecological state of the facilities (in terms of mercury content) was brought into line with established standards, which indicates the sufficient effectiveness of demercurization measures.

 Example 5

 In order to eliminate mercury pollution in the premises of the factory building, converted to administrative premises, a set of demercurization measures was carried out, which included: examination of the object for mercury pollution (determination of gross mercury content and its forms); chemical treatment of the facility; neutralization of mercury-containing materials (construction waste, garbage, cement dust, applied soil) by converting mercury into stable compounds that do not pose an environmental hazard.

 Demercurization was carried out using the proposed E-2000 technology.

 As a result of the above complex of demercurization works, the sanitary-ecological state of the facility (in terms of mercury content) was brought into line with established standards, which indicates the sufficient effectiveness of demercurization measures.

Example 6. On the surface / linoleum, tile / contaminated with mercury, the composition "E-2000 ⁺ " is applied, carefully treating cracks and surface defects. After 8 hours, the products of demercurization are removed with a rag moistened with water.

 Determination of mercury vapor content in air after 6 months. and 1 year after demercurization showed that the condition of the facility (in terms of mercury content) complies with established standards.

 Thus, the above examples indicate the effectiveness of the proposed method of demercurization of premises and the proposed composition for demercurization.

It should be noted that the composition of "E-2000 ⁺ " is effective in the rapid elimination of relatively small mercury contaminants and demercurization with it can be carried out by staff of hospitals, clinics, etc. without the involvement of specialists.

 The main advantage of the proposed method and composition is the guaranteed indefiniteness of the demercurization effect (due to the formation of stable compounds as a result of demercurization).

Claims (2)

 1. The method of demercurization of objects contaminated with mercury "E-2000", including applying to the surface contaminated with mercury, a polysulfide solution followed by removal of the obtained mercury compounds or their deposition on the treated surfaces, characterized in that 10-15% is first applied to the surface - solution of ethoxylated alcohol, and after exposure to this solution for at least 15 minutes, a 4-10% solution of calcium polysulfide is applied with exposure for at least 8 hours. 2. The composition "E-2000 ⁺ " for the demercurization of objects contaminated with mercury, containing a sulfur-containing substance, a complexing agent and water, characterized in that it additionally contains a surfactant - ethoxylated alcohol, as a sulfur-containing substance - calcium polysulfide and as a complexing agent - diethylenetriaminopentaacetic acid HCOOCH ₂ N [CH ₂ CH ₂ N (CH ₂ COOH) ₂ ] ₂ in the following ratios of components,
weight.%:
Calcium Polysulfide - 5-9
Ethoxylated alcohol - 10-15
Diethylenetriaminopentaacetic acid - 0.2-0.5
Water - Else

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