RU2732025C1 - Composition containing potassium permanganate for use in chemical demercurization - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to a potassium permanganate-containing composition for use as an oxidant in demercurization using hydrochloric acid in order to chemically remove mercury from residential or industrial premises. Composition contains a mixture of potassium permanganate crystals in amount of 1–60 wt% and filler – the rest. Filler used is sodium sulphate or magnesium sulphate having an average crystal size which differs from the average size of potassium permanganate crystals in the mixture by not more than 10 %.

EFFECT: reduced oxidative activity of the composition while maintaining the ability to oxidise hydrochloric acid during demercurization, high safety of use thereof, as well as elimination of possibility of physical separation of composition with extraction of pure potassium permanganate.

5 cl, 1 tbl, 2 ex

Description

Technology area

The invention relates to a composition containing potassium permanganate, intended for use as an oxidizing agent in demercurization using hydrochloric acid for the purpose of chemical removal of mercury from residential or industrial premises.

State of the art

Potassium permanganate (potassium permanganate, KMnO ₄ ) is a dark violet, almost black crystals that, when dissolved in water, form a brightly colored crimson solution. The substance is a strong oxidizing agent. Depending on the pH of the solution, it oxidizes various substances, reducing to manganese compounds of various oxidation states.

Potassium permanganate in the form of a solution is widely used for demercurization of premises, which consists in adding hydrochloric acid to a solution and treating the sites of mercury spills with the resulting reaction product. In this case, oxidation with hydrochloric acid permanganate occurs with the release of free chlorine, which subsequently reacts with metallic mercury to form a safe chloride.

However, using pure potassium permanganate is not safe. Due to the high activity when interacting with the reducing agent, the mixture heats up, and sometimes it ignites or even explodes. In addition, in case of incomplete dissolution of potassium permanganate in water with careless use, it can cause tissue burns.

Thus, to reduce the risk of using potassium permanganate during demercurization, it seems advisable to dilute it with a dry filler, which reduces the oxidative activity of the mixture as a whole, but preserves the chemical properties of the substance separately.

A composition in the form of a dry mixture of potassium permanganate and 0.01-99.9 wt. % inert filler (see the publication of international application WO 2009028978, 05.03.2009). The inert filler is porous silicate, pumice, silica gel, aluminum oxide, carbon, or a combination of these. Despite the fact that the specified composition is claimed as a biocidal agent for corrosion protection, it can obviously be used for demercurization purposes. In this regard, this tool has been chosen as the closest analogue.

The disadvantage of the analog is that the composition with an inert filler can be subjected to physical separation, with the release of pure potassium permanaganate. This separation can be carried out by selectively dissolving potassium permanganate and its subsequent crystallization separately from the filler, or by sieving the composition with separation of permanganate crystals by particle size. Isolation of pure potassium permanganate from this composition is undesirable, since it can be further used for other purposes as a strong oxidizing agent, in particular, for the manufacture of explosives, pyrotechnics or illegal drugs.

Disclosure of invention

The object of the claimed invention is to eliminate the disadvantages of analogs and to develop a composition containing potassium permanganate, which is safe for its use in the demercurization process, and is also protected from use for other purposes requiring a strong oxidant.

The technical result of the invention consists in reducing the oxidative activity of the composition while maintaining the ability to oxidize hydrochloric acid during demercurization, increasing the safety of its use, as well as eliminating the possibility of physical separation of the composition with the release of pure potassium permanganate.

The specified technical result of the invention is achieved due to the fact that the composition for demercurization contains a mixture of crystals of potassium permanganate and filler in the ratio, wt. %: potassium permanganate 1-60, filler - the rest. The filler used is sodium sulfate or magnesium sulfate, which has an average crystal size that differs from the average crystal size of potassium permanganate in the mixture by no more than 10%.

According to particular embodiments of the invention:

- used a filler with an average crystal size that matches the average crystal size of potassium permanganate;

- filler crystals are dyed;

- food dye E151 was used to color the filler crystals;

- the size of the crystals of potassium permanganate and filler is from 1 μm to 10 mm.

Implementation of the invention.

The composition for demercurization is a mixture of potassium permanganate crystals and a filler at a ratio of components, wt. %: potassium permanganate 1 - 60, the rest filler.

Sodium sulfate or magnesium sulfate was used as a filler, which is due to the following:

- these salts are neutral (inert) with respect to potassium permanganate;

- salts do not interact with other substances involved in the demercurization process, in particular, hydrochloric acid;

- these salts are safe for humans;

- salts have a solubility in water and other solvents not lower than the solubility of potassium permanganate (6.36 g per 100 g of water at a temperature of 20 ° C), which does not allow the potassium permanganate to be separated from the filler by selective dissolution.

The choice of these intervals of the composition of the composition is due to the following. When the content of potassium permanganate is more than 60 wt. % the oxidizing ability of the composition increases to such an extent that it can be dangerous if used incorrectly (heating the mixture, its explosion, etc.). And when the content of potassium permanganate is less than 1 wt. %, the use of the composition is impractical from a technical and economic point of view, since to achieve the required oxidizing properties, large volumes of the composition will be required, which will increase the consumption of the filler and complicate its dissolution.

Most preferably, the content of potassium permanganate is up to 45 wt. %. This is due to the fact that at a potassium permanganate concentration of 45 wt. % or more, the substance falls under the definition of a precursor and its turnover is subject to control on the territory of the Russian Federation in accordance with List IV of the List of narcotic drugs, psychotropic substances and their precursors subject to control in the Russian Federation by the Standing Committee on Drug Control (PCCN). These circumstances impose additional obligations related to the reporting of activities and keeping a log when using the substance.

The filler must have an average crystal size that differs from the average crystal size of potassium permanganate in the mixture by no more than 10%. This property is guaranteed to prevent the separation of particles of the two substances by mechanical separation. Most preferably, the average particle sizes of the elements are the same. However, even in the case of differences in average sizes of up to 30%, the separation from a practical point of view is not. seems possible, since the resulting particles of both substances do not have the same size and shape, but are characterized by some scatter in the specified properties. A difference of no more than 10% has been chosen based on possible errors to ensure that no physical separation of substances is possible.

The size of the crystals of the filler and potassium permanganate can vary from 1 μm to 10 mm.

To create additional obstacles to the separation of substances in the composition, the filler crystals can be colored so that they have a color characteristic of potassium permanganate. For dyeing, food coloring E151 (brilliant black) or any other dyes of suitable color (black, dark purple) can be used. The concentration of the dye is selected empirically to obtain the required color shade corresponding to the crystals of potassium permanganate.

Getting a composition.

As an example, the technology of obtaining a composition for demercurization containing a mixture of 44 wt. % potassium permanganate and 56 wt. % colored sodium sulfate (filler). The size of the crystals of potassium permanganate and sodium sulfate is in the range of 50-100 microns. The average particle size of permanganate is 75 microns, sodium sulfate is 70 microns.

To obtain the composition, 44 kg of dry potassium permanganate, 55.16 kg of sodium sulfate and 0.84 kg of E151 dye were used.

First, the filler crystals were colored. For this, a 5% dye solution was prepared and 20% of the resulting solution was mixed with 80% sodium sulfate. After that, the colored filler was dried and ground in a mill to the desired granulometric composition. The crystals obtained were mixed with potassium permanganate crystals in a paddle mixer to obtain a composition.

Using composition.

The claimed composition is used for demercurization in the form of an aqueous solution in combination with hydrochloric acid. It should be noted that hydrochloric acid is not part of the claimed composition, but only serves as a source of chlorine in chemical interaction.

Example 1

A composition containing 20 wt. % potassium permanganate (average size 1 μm) and 80 wt. % magnesium sulfate (average size 1 μm), diluted with water to obtain a 1% solution (based on the total weight of the composition). In the resulting solution add hydrochloric acid, with a specific gravity with a specific gravity of 1.19, in the amount of 5 ml of acid per 1 liter of solution. Places of mercury spills (floors, walls, furniture, etc.) were treated with this solution.

As a result of chemical reactions, a low-toxic water-insoluble salt is formed - calomel:

2KMnO ₄ + 16HCl = 2KCl + 2MnCl ₂ + 5Cl ₂ + 8H ₂ O;

2Hg + Cl ₂ = Hg ₂ Cl ₂

The resulting mercury salt was collected mechanically with a rag. After demercurization, no metallic mercury was detected on the treated surfaces.

Example 2

A composition containing 44 wt. % potassium permanganate (average size 10 mm) and 56 wt. % sodium sulfate (average size 9.5 mm), diluted with water to obtain a 0.45% solution. Hydrochloric acid with a specific gravity of 1.19 is added to the resulting solution, in an amount of 5 ml of acid per 1 liter of solution. Places of mercury spills are treated with this mixture. The mercury salt was removed mechanically with a rag. After demercurization, no metallic mercury was detected on the treated surfaces.

Tests for the possibility of separating the composition.

To confirm the fact that it is impossible to physically separate the components of the mixture, experiments were carried out to separate three compositions:

# 1; Composition containing:

1 wt. % potassium permanganate with an average particle size of 10 mm,

99 wt. % sodium sulfate with an average particle size of 9.5 mm.

# 2: Composition containing:

44 wt. % potassium permanganate with an average particle size of 410 microns,

56 wt. % magnesium sulfate with an average particle size of 430 microns.

No. 3: Composition containing:

60 wt. % potassium permanganate with an average particle size of 1 μm,

40 wt. % sodium sulfate with an average particle size of 1.1 microns.

In the first experiment, the compositions were dissolved in water to obtain 5% solutions, the solution was separated and evaporated. As a result of the tests, all three compositions were completely dissolved in water.

In the second experiment, the compositions were sieved through sieves:

Composition No. 1 through a sieve with a mesh size of 9.8 mm,

Composition No. 2 through a sieve with a mesh size of 420 microns,

Composition No. 3 through a sieve with a mesh size of 1 micron.

As a result of sieving, 2 mixtures were obtained for each composition.

In the third experiment, each composition was subjected to air separation. As a result, 2 mixtures were obtained for each composition.

Table 1 shows the change in the compositions of the compositions after separation into components.

It can be seen from the results obtained that the separation of the components of the composition by physical means with the release of pure potassium permanganate is not possible, since the content of substances obtained as a result of the separation of the constituents does not practically differ from the initial one, which is associated with close values of the average particle size.

Thus, the claimed composition retains its ability to oxidize mercury, but has a significantly lower activity, which increases the safety of processing premises and prevents the direct use of the composition for the production of hazardous substances (explosive, narcotic, etc.). At the same time, the affinity of the physicochemical parameters of the potassium permanganate particles and the filler does not allow the mixture to be physically separated into substances for its indirect use for the indicated purposes as a strong oxidant.

Claims (6)

1. Composition for use as an oxidizing agent in chemical demercurization, containing a mixture of potassium permanganate crystals and a filler, characterized in that sodium sulfate or magnesium sulfate is used as a filler, having an average crystal size that differs from the average size of potassium permanganate crystals in the mixture. by more than 10%, with the components used in the following ratio, wt%: potassium permanganate 1 - 60 filler - the rest 2. A composition according to claim 1, characterized in that a filler is used with an average crystal size that matches the average crystal size of potassium permanganate. 3. Composition according to claim 1, characterized in that the filler crystals are colored with a dye. 4. Composition according to claim 3, characterized in that food dye E151 is used to color the filler crystals. 5. Composition according to claim 1, characterized in that the size of the crystals of potassium permanganate and filler is from 1 μm to 10 mm.