RU2723182C1 - Method of isolating oil in soil by chemical encapsulation - Google Patents

Abstract

FIELD: oil, gas and coke-chemical industries.

SUBSTANCE: invention relates to the field of environmental protection, in particular to processes of recycling oily wastes (sludges), and can be used in oil, petrochemical and other industries related to storage, transportation and processing of oil and oil products. Method of isolating oil in soil by chemical treatment involves introduction of acidic and alkaline agents which form compounds which are insoluble in water in a wet matrix. Process is carried out by adding to soil contaminated with soil an emulsifier - calcium stearate (StCa), calcium carbonate (CaCO₃) as an alkaline agent and iron (II) sulphate - FeSO₄ * 7H₂O - as acidic agent in weight ratio of 1.0:0.5:0.3:0.85 > Oil : StCa : CaCO₃ : FeSO₄ * 7H₂O ≥ 1.0:0.3:0.2:0.55.

EFFECT: technical result consists in creation of efficient, easy-to-process method of oil-containing soil recovery to produce environmentally safe product.

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Description

The invention relates to the field of environmental protection, in particular to processes for the disposal of oily waste (sludge). The invention can be used in the petroleum, petrochemical and other industries related to the storage, transportation and processing of oil and petroleum products.

One of the methods for the restoration of soils contaminated with oil and oil products is the method of reagent encapsulation in calcareous shells, the essence of which is the introduction of calcium oxide (quicklime) and water into contaminated soil [T. Litvinova. Modern methods of disposal and disposal of oily waste for the elimination of environmental pollution / Electronic scientific journal of the Kuban State Agrarian University. 2016].

In this case, lime is quenched with the formation of calcium hydroxide. In the process of quenching, wet soil forms with a strongly alkaline reaction, due to which the process of carbonization of calcium hydroxide occurs.

The resulting crystals of calcium carbonate envelop hydrophobic soil particles, impregnated with oil.

Thus, crystallization centers appear on these particles, where the growth of calcium carbonate crystals continues. With prolonged standing of moist soil in the air and a sufficient excess of lime, almost all particles of sludge are covered with a chalky waterproof "carapace".

This process is called reagent encapsulation.

When grinding the encapsulated soil, there are no oil black oil traces on the fingers, the soil does not smell like oil, the oil film does not appear on the surface of its water extract and it does not smell of oil.

Thus, the encapsulation technology isolates the soil oil inside the chalk capsules, which helps prevent soil oil from entering the environment, that is, isolate (deactivate) the oil as an environmental pollutant.

Such soil can be used for agriculture, subject to certain procedures to reduce its alkalinity.

The main problem of this technology is the increased alkalinity of deactivated soil.

Soil with high alkalinity (pH> 9) or acidity (pH <4) is toxic to plant roots. Within the range of pH> 7, iron, manganese, phosphorus, copper, zinc, boron and most trace elements become less accessible to plants due to the formation of insoluble hydroxides.

In acidic soils (pH = 4.0-5.5), iron, aluminum and manganese are in forms accessible to plants, and their concentration reaches a toxic level. At the same time, the entry of phosphorus, potassium, sulfur, calcium, magnesium, and molybdenum into plants is difficult. Therefore, in acidic soil, plants die.

The optimum is considered to be pH = 6.5 (slightly acid soil reaction). This does not lead to a lack of phosphorus and trace elements, most of the main nutrients become available to plants, i.e. are in soil solution. Such a soil reaction is favorable for the development of beneficial soil microorganisms that enrich the soil with nitrogen [/ http://www.agrotest.com/ru/info/2/23.html/].

To reduce the alkalinity of deactivated soil, surfactants from the class of fatty or sulfonic acids, as well as other high molecular weight natural and synthetic substances, are added to quicklime in addition to quicklime. When oil sludge is mixed with these components in a ratio of 1: 1 to 1:10, adsorption of waste occurs on the surface of calcium hydroxide. The result is a dry hydrophobic powder [1].

However, with prolonged contact of calcareous capsules in moist soil, their gradual destruction occurs due to the formation of water-soluble calcium bicarbonate and oil flows back into the soil:

A known method of restoring soil contaminated with oil [2. RF patent No. 2690425, 2019], by mixing the soil with calcium oxide and aluminum sulfate as an acid agent, which leads to the formation of water-insoluble compounds. The result is a neutral hydrophilic soil. Mass ratios of acid and alkaline agents to oil are:

The disadvantage of this method is the high cost of calcium oxide and aluminum sulfate. In addition, the storage and transportation of calcium oxide requires the observance of special sealing conditions to prevent its interaction with water vapor. This leads to a change in the chemical composition of the alkaline agent, as a result of which it is not possible to form a neutral soil.

Closest to the proposed invention is the "Method for the restoration of oil-containing soil by chemical treatment" [Application No. 2017139299, the decision to grant a patent for the invention of 07/02/2019], by mixing the soil with calcium oxide and an acid agent - spent sulfuric acid etching solutions (OTP) in mass ratio of components:

At the same time, water-insoluble compounds are formed in the soil: calcium sulfate and iron (II) and (III) hydroxides, on the active surface of which particles of oil-containing soil are sorbed.

With prolonged contact of moist soil with air, the following reactions occur:

Thus, oil droplets are involved (encapsulated) inside the crystalline coatings formed during the joint crystallization of gypsum and iron hydroxides (II) and (III). At the same time, the restored soil is moistened with water and drowns in it.

The disadvantage of this method is the use of OTP as an acidic agent.

In steel mills in the process of cleaning steel from rust with a solution of sulfuric acid. During long-term operation, these solutions are saturated with iron (II) and (III) sulfates and spent pickling solutions (OTP) with a density of 1.22-1.23 g / ml, containing sulfuric acid (up to 40 g / l), FeSO ₄ (180- 200 g / l) and Fe ₂ (SO ₄ ) ₃ (up to 10 g / l) are removed from the production cycle.

The composition of OTP is not constant and before their use, to select the appropriate amounts of reagents that provide neutral soil, it is necessary to analyze the composition of OTP. Transporting liquid OTP requires large volumes of corrosion resistant containers.

In addition, in the method for each ton of soil, it is necessary to use 2-3 tons of OTP.

The technical problem to which this invention is directed, the creation of an effective, easy-to-process method for the restoration of oil-containing soil to produce an environmentally friendly product, is solved by the method in which the process of restoration of oil-containing soil by the method of reagent encapsulation is carried out by adding carbonate as an alkaline agent calcium (chalk), an acid agent - iron (II) sulfate - FeSO ₄ * 7H ₂ O), an emulsifier - calcium stearate (StCa) in the following weight ratio of components:

The technical result is the simplification and improvement of the process of restoration of oily soil with the release of hydrophilic and neutral soil.

When StCa is introduced into wet soil contaminated with oil, an emulsion is formed in which hydrophobic oil molecules are collected in the internal hydrophobic micelle cavity of this emulsion.

When chalk and FeSO ₄ * 7H ₂ O are mixed with water in the soil, the reaction of neutralization of calcium carbonate occurs with the formation of insoluble compounds: - calcium sulfate and iron (II) hydroxide.

The hydrophilic - polar part of StCa serves as the crystallization center of the formed water-insoluble microcrystals of gypsum and iron (II) hydroxide.

To completely neutralize one mass unit of calcium carbonate with the formation of iron (II) hydroxide, it is necessary to expend 2.8 mass units of FeSO ₄ * 7H ₂ O

Saturated aqueous solutions of gypsum and iron (II) hydroxide are characterized by pH values of 7 and 9.7, respectively. As iron (II) hydroxide is oxidized to iron (III) hydroxide, water-insoluble iron metahydroxide, FeO (OH), is formed. At the same time, the pH of the water extract of the soil decreases and becomes neutral in time (7-7.5).

Thus, oil in the soil is emulsified using StCa, and the resulting emulsion micelles are coated with a water-insoluble coating of FeO (OH) and calcium sulfate. A capsule is formed - the center of crystallization, around this continues the process of crystal growth, and the walls of the capsules thicken.

The restored soil is wetted by water and drowns in it.

The soil restoration process is described below in the examples.

Example 1 (control, without emulsifier). To 100 g of contaminated soil (sand or loam) containing 20 g of oil, 18 g of calcium carbonate, 50 g of FeSO ₄ * 7H ₂ O and water were added until a mobile slurry formed, the mixture was homogenized by stirring and dried in the open air. After a week, a yellow-brown loose, uniform soil is formed that meets the requirements of the following sanitary and hygienic indicators.

1. Appearance: homogeneous loose powder from light brown to dark brown.

2. The wettability of the recovered soil with water: it gets wet and drowns in water.

3. No odor of oil from both the soil and the water extract.

4. The pH values of the aqueous extract of 6.5-7.5.

5. The absence of an oil film and a colored rainbow on the surface of an aqueous extract ;.

6. Lack of an oily black trace after grinding the soil between the fingers.

An aqueous extract was prepared by dissolving the soil in water in a ratio of 1: 5.

Example 2 was carried out as described in example 1, only calcium oxide and FeSO ₄ * 7H ₂ O were added in amounts of 16 g and 45 g, respectively. The formed gray oily mass does not meet the above hygiene requirements (1-6).

Therefore, the optimal conditions for encapsulating oil in the soil, without the use of an emulsifier, are:

Example 3 was carried out as described in example 1, only the emulsifier — calcium stearate — salts of higher fatty acids (E) was also introduced into the soil.

Satisfying the above sanitary and hygienic indicators, the soil was obtained with the following mass ratios of the components of the reagent mixture:

As can be seen, in comparison with example 2, the use of an emulsifier can reduce the consumption of reagents 3-4.5 times.

In the prototype, the consumption of calcium oxide per unit mass of contaminated soil is 0.2. In the present method, the consumption of alkaline agent calcium carbonate is 0.06, which in terms of calcium oxide is 0.033. Therefore, the consumption of calcium oxide in comparison with the prototype is reduced by 6 times.

Thus, the assigned technical task was fulfilled - the creation of an effective, easy-to-process restoration of oil-containing soil with the production of an environmentally friendly product.

This allows you to provide the expected technical result - simplification and improvement of the process of restoration of oily soil, with the release of hydrophilic and neutral soil.

Claims (2)

A method of isolating oil in soil by chemical treatment, introducing acidic and alkaline agents into it, forming water-insoluble compounds in a wet matrix, characterized in that the process is carried out by adding an emulsifier - calcium stearate (StCa), calcium carbonate (CaCO ₃ ) to the oil-contaminated soil as an alkaline agent and iron (II) sulfate - FeSO ₄ * 7H ₂ O - as an acidic agent in mass ratios: 1.0: 0.5: 0.3: 0.85> Oil: StCa: CaCO ₃ : FeSO ₄ * 7H ₂ O ≥ 1.0: 0.3: 0.2: 0.55.