RU2196114C2 - Hydrogen sulfide neutralizer in water-crude oil emulsions - Google Patents

Abstract

FIELD: crude oil treatment. SUBSTANCE: neutralizer contains 40-60% of mixture of mono-, di-, triethanolamine, and ammonia, 10-40% of bis- amine-formalin mixture, plus solvent (to 100%): water-soluble alcohol, water, or their mixture. EFFECT: enhanced hydrogen sulfide neutralization efficiency and improved workability due to lowered freezing temperature. 3 cl, 2 tbl, 2 ex

Description

 The invention relates to the field of non-neutralization of hydrogen sulfide with chemicals and can be used in the oil industry.

 It is known to use a mixture of blocked amines as hydrogen sulfide neutralizers [1. US Pat. USA 4894178, 1987], unblocked amines with the addition of highly blocked amine salts [2. US Pat. USA 4892674, 1987], an aqueous solution of aldehyde and quaternary ammonium [3. US Pat. Germany 3927763, 1989], a mixture of formaldehyde and ketone [4. A.S. USSR 1699546, 1990].

 However, the listed hydrogen sulfide neutralizers are not effective in water-oil environments.

 A hydrogen sulfide neutralizer consisting of an organic amine or ammonia and formaldehyde formalin or furfural was taken as a prototype. As the organic amine, ethanolamine, propanolamine, N-dimethylpropylenediamine, methylamine, ethylamine or mixtures thereof are used. The disadvantage of this Converter is the low efficiency in water-oil environments and low technology [5. US Pat. RF 2099631, 1997].

 The claimed technical solution is aimed at increasing the efficiency of neutralization of hydrogen sulfide in water-oil environments and improving manufacturability, i.e., lowering the pour point, which will allow to dose the hydrogen sulfide neutralizer with a pump in the winter.

In the claimed technical solution, this is achieved by preparing a composition for neutralizing hydrogen sulfide, including mixtures of monoethanolamine, diethanolamine, triethanolamine and ammonia, formaldehyde derivatives: formalin and the product of the interaction of formaldehyde with dimethylamine - bisamine (NN-tetramethylmethylenediamine) and water or water as a solvent; methyl, ethyl and propyl alcohols), or mixtures thereof in the following ratio of components, wt.%:
Mixtures of mono, di, triethanolamine and ammonia - 40-60
Mixtures of formalin and the product of the condensation of formaldehyde with dimethylamine - 10-40
Solvent (water, or alcohols, or mixtures thereof) - Else
The condensation product of formaldehyde with dimethylamine: the technical name is bisamine and the chemical name is N, N ¹ -tetramethylmethylenediamine is an intermediate reagent for the production of ionol at the Sterlitamak Petrochemical Plant. Bisamine is also a component of the corrosion inhibitor according to [6. A.S. 1431372, 1988].

The composition is prepared as follows. The calculated quantities of a mixture of monoethanolamine, diethanolamine, triethanolamine and ammonia, bisamine and solvent are loaded into a mixer with a stirrer and stirred at a temperature of 35-40 ^o C for 2-3 hours. Then, the calculated amount of formalin is gradually introduced into the resulting mixture, followed by stirring for another 2-3 hours. The resulting mixture is unloaded in an appropriate container. The finished product has the following parameters:
Light brown to dark brown liquid.

 Density 0.954-1.058 g / cm.

Pour point minus 40 - minus 55 ^o C.

Testing the effectiveness of the neutralization of hydrogen sulfide was carried out to RD 39-0147276-018094 [6]. A hydrogen-sulphide-containing medium was a water-oil mixture (oil: formation water model = 50:50) with a hydrogen sulfide content of 500-2000 mg / l as a formation water model (MPV), the composition model was used, g / l: CaSO ₄ • 2H ₂ O - 0.3; CaCl ₂ • 6H ₂ O - 10.8; NaCl - 111.5; MgCl ₂ • 6H ₂ O - 6.0. The hydrogen sulfide content in the test medium was determined using an Exxon Chemical indicator tube and the titrimetric method. The neutralization efficiency according to the above procedure [5] is determined by the reagent consumption coefficient (K), i.e. reagent consumption per 1 g of hydrogen sulfide in the test fluid. According to this technique, based on the results of determining the concentration of hydrogen sulfide in the liquid phase, reagent dosages corresponding to 25, 50, 75 and 100% neutralization of hydrogen sulfide are set so that a graphical dependence of the concentration of hydrogen sulfide on the dosage of the reagent can be constructed. From the obtained graphical dependence, the reagent consumption coefficient (K) is established, i.e. reagent consumption per 1 g of hydrogen sulfide in a liquid.

The effectiveness of the neutralization of hydrogen sulfide (γ) of the proposed composition was determined by the formula:
γ = K _n / K _k ,
where K _n - expenditure coefficient for the prototype;
To _to - expenditure coefficient for a particular composition.

 The essence of the technical solution is illustrated by the following examples of preparation (the number of components are given per 100 g of the composition) and testing the composition in water-oil media containing hydrogen sulfide.

 Example 1

50 g (50%) of triethanolamine, 10 g (10%) of ammonia, 5 g (5%) of formalin are loaded into a container with a stirrer, followed by stirring for 2 hours. The resulting product has the following parameters:
The liquid is dark brown.

Density 1,053 g / cm. ³
The pour point determined according to GOST 20287-81 is minus 46 ^o C, and in the prototype [5] the pour point is minus 25 ^o C.

 Testing the effectiveness of the neutralization of hydrogen sulfide by the obtained composition was carried out according to the above procedure [6]. The expendable coefficient (K) of this composition, obtained experimentally, in a hydrogen sulfide-containing (C = 500 mg / L) liquid (oil: MPV = 50:50) was K = 3.04, and in the prototype K = 4.7, the resulting composition 1.55 times more effective in neutralizing hydrogen sulfide compared to the prototype.

 Example 2

25 g (25%) of monoethanolamine, 25 g (25%) of ammonia, 15 g (15%) of formalin are loaded into a container with a stirrer, followed by stirring for 2 hours. The resulting product has the following parameters:
The liquid is brown.

 Density 0.954 g / cm.

Pour point minus 55 ^o C.

 The expenditure coefficient (K) of this composition under these conditions was 2.9, and in the prototype K = 4.75, i.e. the resulting composition in γ = 1.62 effectively neutralizes hydrogen sulfide compared with the prototype.

 Table 1 presents the remaining examples of the preparation of compositions for neutralizing hydrogen sulfide and its indicators.

 Table 2 presents the test results using the claimed compositions.

 The test results indicate the high efficiency of the claimed compositions as neutralizers of hydrogen sulfide in water-oil environments. The highest efficiency of the compositions is achieved at 40-60 wt.% A mixture of amines and 10-40 wt.% For a mixture of formaldehyde derivatives. Reducing the content of a mixture of amines below 40 wt.%, A mixture of formaldehyde derivatives below 10 wt. % leads to a sharp decrease in the efficiency of neutralization of hydrogen sulfide, i.e. increasing the content of formaldehyde derivatives above 40 wt.% is impractical. With an increase in the content of the mixture of amines above 60 wt.%, The efficiency of neutralizing hydrogen sulfide increases slightly, but the pour point decreases sharply, i.e. the increase in the content of the mixture of amines above 60 wt.% is impractical.

 The quantitative and qualitative ratio of the mixture of amines in the composition is not regulated, i.e. the mixture ratio of amines can fluctuate in the widest aisles.

 For a mixture of formaldehyde derivatives, the ratio of bisamine and formalin can vary widely except bisamine, a decrease in the content of which in the composition below 5 wt.% Is unacceptable, because leads to a sharp decrease in the effectiveness of neutralization of hydrogen sulfide in water-oil environments.

 In a solvent, the ratio of water to alcohols can vary widely, with the exception of alcohols, an increase in the content of which in the composition above 11% is impractical because does not affect the technological properties of the composition, i.e. on pour point.

The advantages of the claimed catalyst for hydrogen sulfide in comparison with the prototype:
1. The high efficiency of the neutralization of hydrogen sulfide in water-oil environments compared with the prototype: the inventive composition is 1.5-2.09 times more effective in neutralizing hydrogen sulfide in comparison with the prototype.

2. The high adaptability of the inventive catalyst freezing point from minus 40 to minus 55 ^o C, and the prototype minus 25 ^o C.

 The results obtained allow us to conclude that the claimed composition is an effective neutralizer of hydrogen sulfide in water-oil environments containing hydrogen sulfide, i.e. may find application in the oil industry.

Claims (2)

1. A hydrogen sulfide neutralizer in water-oil media containing a mixture of mono-, di-, triethanolamine with formalin, characterized in that it additionally contains ammonia, bisamine and a solvent — water-soluble alcohol, or water, or a mixture thereof in the following ratio of components, wt . %:
A mixture of mono-, di- and triethanolamine with ammonia - 40-60
A mixture of formalin with bisamine - 10-40
Solvent - Up to 100
2. The neutralizer according to claim 1, characterized in that it contains bisamine in an amount of not less than 5 wt. %  3. The neutralizer according to claim 1, characterized in that it contains water-soluble alcohol in an amount of not higher than 11 wt. %

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