RU2541018C2 - Hydrocarbon gas amine treatment method - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention is related to gas treatment methods and may be used in the oil and gas industry, oil processing and petrochemical industry at the amine treatment of hydrocarbon gases from acid components. The invention suggests a method for the treatment of industrial and refinery gases that includes the compression of the treated gas by a liquid-ring compressor using a mixture of an aqueous solution of alkanolamine and a hydrocarbon fraction with the mass ratio of components of 0.1-10:1 as the working liquid and further separation of the compressed gas with the production of the treated gas, Y-grade NGLs sent to further processing and the saturated aqueous solution of alkanolamine sent for regeneration.

EFFECT: invention allows preventing the pollution of a saturated absorbent by heavy hydrocarbons and mercaptans, reducing losses of hydrocarbons C₄₊ and energy costs.

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Description

The invention relates to methods of gas processing and may find application in the oil and gas, oil refining, petrochemical industries in the absorption treatment of fatty hydrocarbon gases from acidic components.

At present, absorption cleaning of hydrocarbon gases from acidic components using aqueous solutions of alkanolamines as the absorbent has become most widespread.

For example, there is a method of purifying hydrocarbon gases from acidic components, such as hydrogen sulfide and / or carbon dioxide [RF Patent No. 2087181, IPC B01D 53/14, B01D 53/52, B01D 53/62, publ. 08/20/1997,], including gas absorption of a 40-70% aqueous solution of dimethylethanolamine (absorbent) and subsequent regeneration of the saturated absorbent.

The disadvantage of this method is the difficulty of purification of fatty gases, characterized by a high content of hydrocarbons With ₄₊ and in many cases the presence of light mercaptans in their composition. Some C ₄₊ hydrocarbons and mercaptans condense in the alkanolamine solution, which leads to its foaming in the absorber and in the regeneration column, which in turn causes a decrease in the degree of gas purification from hydrogen sulfide due to a decrease in the absorption capacity of the absorbent and the degree of its regeneration. In addition, the accumulation of heavy hydrocarbons and mercaptans in the absorbent degrades the quality of the sulfur obtained in the sulfur production plant from acid gases for the regeneration of a saturated alkanolamine solution. The burning of part of C ₄₊ hydrocarbons and mercaptans together with acid gas at the sulfur production unit also leads to their irretrievable loss. Moreover, most of these components are carried away together with desulfurized gas and their condensation in the pipeline system complicates its operation and leads to the loss of valuable hydrocarbon feedstocks.

The closest analogue of the invention, adopted as a prototype, is a method and apparatus for processing refinery gases containing hydrogen sulfide [US 2006/0165575, publ. July 27, 2006, IPC B01D 53/50, C01B 17/20, B01J 8/04], which includes compressing the gas to be cleaned with a liquid ring compressor using an aqueous alkanolamine solution (absorbent) as a working fluid, and separating the compress to obtain a washed (desulfurized) gas, a hydrocarbon phase (a wide fraction of hydrocarbons) and an aqueous phase (absorbent saturated with hydrogen sulfide).

This method does not fully eliminate the disadvantages of the method adopted for the analogue: condensation of C ₄₊ hydrocarbons and mercaptans in a solution of alkanolamine (absorbent) pollutes it and degrades the quality, insufficiently high degree of C ₄₊ hydrocarbon recovery leads to a loss of C ₄₊ hydrocarbons due to entrainment along with desulfurized gas, lowering the quality of desulfurized gas. Gas compression requires a lot of energy.

The objective of the invention is to reduce pollution of the absorbent, improve the quality of the desulfurized gas, reduce the loss of hydrocarbons With ₄₊ and reduce energy consumption.

The technical result that can be obtained by implementing the method:

- reduction of absorbent contamination by eliminating the accumulation of heavy hydrocarbons and mercaptans in the alkanolamine solution;

- improving the quality of desulfurized gas by reducing the content of hydrocarbons With ₄₊ and mercaptans,

- reduction of losses of hydrocarbons With ₄₊ due to absorption,

- reduction of energy consumption by reducing the volume of compressible gas due to the dissolution of C ₄₊ hydrocarbons and mercaptans in the absorbent.

The specified technical result is achieved by the fact that in the known method, comprising compressing flare gases with a liquid ring compressor using an alkanolamine aqueous solution as a working fluid, separating the compress to obtain a desulfurized gas, a wide fraction of hydrocarbons, and an aqueous alkanolamine solution saturated with hydrogen sulfide, the feature is that the aqueous alkanolamine solution is pre-mixed with the hydrocarbon fraction in a ratio of 0.1-10: 1.

In the inventive method, preliminary mixing of an aqueous solution of alkanolamine with a hydrocarbon fraction makes it possible to obtain a working fluid in the hydrocarbon component of which C ₄₊ hydrocarbons and mercaptans are dissolved, thereby reducing the pollution of a saturated aqueous solution of C ₄₊ hydrocarbons and Mercaptans and reducing their losses. The mass ratio of the components of the mixture in the range of 0.1-10: 1 is selected by calculation based on the composition, temperature and pressure of the gas to be purified and the requirements for the composition of the acid gas released during the regeneration of an aqueous alkanolamine solution.

As the hydrocarbon fraction, gasolines, kerosene, diesel fuels and any other low viscosity hydrocarbon mixtures can be used.

The method is as follows. The gas to be purified (I) is compressed by a liquid-ring compressor 1, into which a mixture of an aqueous solution of alkanolamine (II) as an absorbent of hydrogen sulfide and a hydrocarbon fraction (III) as an absorbent of C ₄₊ hydrocarbons and mercaptans is supplied as a working fluid. The compressor (IV) is separated in separator 2 into purified gas (V), a wide fraction of hydrocarbons (VI), and a spent aqueous alkanolamine solution saturated with hydrogen sulfide (VII).

The performance of the proposed method is illustrated by the following example. 6000 nm ³ / h (6.32 t / h) of off-gas from a delayed coking unit, composition,% vol .: hydrogen 10.1%, nitrogen 1.92%, oxygen 0.85%, carbon monoxide 0.73%, hydrogen sulfide 5.14%, methane 48.9%, ethane 16.4%, C ₃ 9.92%, C ₄ 3.62%, C ₅₊ 0.9%, methyl and ethyl mercaptans 0.13%, at a temperature of 30 ° C and a pressure of 0.28 MPa, they are directed to the inlet of a NASH liquid ring compressor NAM-2500, into which 40 t / h of a 15% aqueous solution of monoethanolamine mixed with 10 t / h of light gas oil is fed as a working fluid, and compress to 0.5 MPa. The compressor is separated to obtain 5528 nm ³ / h of purified gas of the composition% vol .: hydrogen 10.9%, nitrogen 2.08%, oxygen 0.92%, carbon monoxide 0.79%, hydrogen sulfide 0.03%, methane 52, 7%, ethane 17.2%, C ₃ 9.81%, C ₄ 2.65%, C ₅₊ 0.47%, methyl and ethyl mercaptans 0.04%, sent to the fuel network of the refinery, 10.47 t / h of a wide fraction of hydrocarbons sent to the distillation column of the delayed coking unit, and an aqueous solution of monoethanolamine saturated with hydrogen sulfide, containing the sent for regeneration.

The loss of C ₄₊ hydrocarbons with fuel gas was 0.62 t / h. The content of methyl mercaptan and ethyl mercaptan in a saturated aqueous solution of monoethanolamine, sent for regeneration, amounted to, respectively, 4.2 and 4.4 kg. Electricity consumption amounted to 177 kW.

The loss of C ₄₊ hydrocarbons with fuel gas during utilization of the above gas by the method described in the prototype, when producing fuel gas with a pressure of 0.5 MPa, amounted to 0.95 t / h. The content of methyl mercaptan and ethyl mercaptan in a saturated aqueous solution of monoethanolamine sent for regeneration was 4.6 and 7.1 kg, respectively. Electricity consumption amounted to 188 kW.

Thus, the above example shows that the proposed method can reduce the pollution of a saturated aqueous alkanolamine solution with heavy hydrocarbons and mercaptans, reduce losses and return a significant portion of C ₄₊ hydrocarbons to the process cycle, as well as obtain fuel gas that complies with the industry standard. oil and gas, oil refining, petrochemical industries.

Claims (1)

A method of amine purification of hydrocarbon gases, comprising compressing gases with a liquid ring compressor using an alkanolamine aqueous solution as a working fluid, separating the compress to produce a desulfurized gas, a wide hydrocarbon fraction, and an aqueous alkanolamine saturated with hydrogen sulfide, characterized in that the aqueous alkanolamine solution is pre-mixed with a hydrocarbon fraction of low viscosity in a mass ratio of 0.1 ÷ 10: 1.

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