RU2381255C1 - Method for processing of benzene fractions - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention is related to chemical and petrochemical industries, namely, to methods for stabilisation of secondary benzene fractions. Invention is related to method of benzene fractions processing, including supply of unstable benzene fractions into benzene stabilisation tower, their separation into fractions: stabilisation head and stabilisation residue, stabilisation head is supplied to gas-fractionating installation with production of gas components. Saturated absorbent from lower part of absorption tower is supplied to unit of benzene stabilisation, where benzene fractions are also supplied, at the same time hydrocarbon gases from unit of benzene fractions and saturated absorbent stabilisation are exhausted into absorption tower, prior to supply of benzene to stabilisation tower, benzene fractions in mixture with saturated absorbent are heated due to heat transfer from stabilisation residue drained from stabilisation tower as commercial-grade benzene, some stabilisation residue is sent to absorption tower for absorption of propane-butane fraction from hydrocarbon gases of lower pressure with further supply of saturated absorbent into benzene stabilisation tower, and another part of stabilisation residue is drained as commercial-grade benzene.

EFFECT: provision of required extent of benzene stabilisation, reduced energy consumption, reduced losses of benzene fractions and liquefied gas.

2 ex, 1 dwg

Description

The invention relates to the chemical and petrochemical industries, and in particular to methods of processing secondary gasoline fractions.

The known method for the separation of hydrocarbon gases - the compression method used to topping the "fatty gas" does not provide a sufficient depth of extraction of the target components, requires high energy costs.

A known method of processing straight-run gasoline fractions (SU 1838378, publ. 30.08.93), including the introduction of heated gasoline fractions into the stabilization column, the supply of vapor from the top of the column to the condenser with the output as a distillate of the stabilization head and directing it to the gas fractionation unit. Stable gasoline is obtained as a distillation residue, while light components of gasoline are removed from the stabilization column in a side stream, light fractions are evaporated, which are mixed with stabilization distillate vapors, and the mixture is fed to a condenser.

The closest in technical essence to the claimed method is a method of processing gasoline fractions (RU 2064001, publ. 07/20/1996), according to which the gasoline fraction is fed to stabilization in the stabilization column, the stabilization head is separated, the stabilization residue and side stream light components of gasoline. The stabilization head is fed to a gas fractionation unit to produce gas components and gas gasoline. The remainder of the stabilization column is fed to the reforming unit. The obtained unstable reformate is fed into the stabilization column with the isolation of the stabilization head and stable reformate. The stable reformate is divided into light and heavy fractions, followed by mixing the light fractions with part of the heavy fraction to produce mid-octane gasoline. The remainder of the heavy fraction is mixed with gas gasoline to obtain high-octane unleaded gasoline.

However, the known method does not provide the required degree of stabilization of gasoline and the depth of extraction of the target components.

The objective of the present invention is to reduce the loss of gasoline fractions and liquefied gas, providing the required degree of stabilization of gasoline, reducing energy costs.

The solution to this problem is achieved by the fact that the method of processing gasoline fractions involves feeding unstable gasoline fractions to a gasoline stabilization column, dividing them into fractions: 80 ° C (stabilization head) and a fraction of 80-180 ° C (stabilization residue), feeding the stabilization head to a gas fractionation unit to produce gas components, and part of the fraction 80-180 ° C (stabilization residue) is sent to an absorption column for propane absorption -butane fraction from low-pressure hydrocarbon gases, followed by the supply of a saturated absorbent to the gasoline stabilization column, and the balance part is diverted as commercial gasoline. The gasoline fractions are fed to the stabilization column in a mixture with a saturated absorbent, and hydrocarbon gases from the mixing tank of the gasoline fractions and the saturated absorbent are removed to the absorption column. Before feeding the gasoline stabilization column, the gasoline fractions in a mixture with a saturated absorbent are heated by heat transfer from the stabilization residue removed from the stabilization column as commercial gasoline. The heating of the cube of the gasoline stabilization column is carried out by transferring heat from the coolant to the stabilization residue in the riboiler.

The proposed method allows to separate hydrocarbon mixtures without the use of compressors, to reduce the loss of target components.

The method is as follows (see drawing).

The gasoline fraction from the top of the distillation column (not shown in the drawing) is sequentially fed to heat exchangers for condensation and cooling. The cooled gasoline fraction is sent to a container where the gas-gas phase is separated into fuel gas, gasoline and water. The balance part of gasoline is diverted to the stabilization unit, and the required amount is supplied for irrigation of the top of the distillation column.

Hydrocarbon gases enter the lower part of the absorption column 1. In the upper part of the absorption column 1, to absorb the propane-butane fraction from the gas, a fraction of 80-180 ° C is supplied from the gasoline stabilization column 2, and the balance part of which is diverted to the freight fleet. Hydrocarbon gas from the upper part of the absorption column 1, passing through the droplet eliminator 3, is sent to the fuel network. A saturated absorbent (fraction 80-180 ° C) from the bottom of the absorption column 1 is fed into the tank 4 of the gasoline stabilization unit, which also receives gasoline fractions. Hydrocarbon gases from tank 4 are discharged to absorption column 1. Before feeding gasoline to the stabilization column, 2 gasoline fractions and saturated absorbent are heated in the heat exchanger 5. Heating is due to the transfer of heat from stable gasoline removed from the gasoline stabilization column 2. Inlet to the stabilization column 2 carried out on 20 and 25 plates. In the stabilization column of gasoline 2, the unstable gasoline is divided into fractions: fraction n.k. 80 ° C, fraction 80-180 ° C. From the bottom of the stabilization column of gasoline 2, the fraction of 80-180 ° C enters the reboiler 6, where it is heated with a coolant to maintain the temperature of the bottom of the stabilization column 2. The temperature of the bottom of the column is 191 ° C, the temperature of the top of the column is 80 ° C. After cooling in the refrigerator 9, part of the fraction 80-180 ° C is fed to the upper part of the absorption column 1, and the balance part is sent to the freight fleet. Fraction N.K. - 80 ° C from the upper part of the stabilization column of gasoline 2 is fed into the tank 7 after condensation and cooling in a water refrigerator 8. The required amount of fraction n.k. - 80 ° C serves for irrigation of the upper part of the stabilization column of gasoline 2, and the balance part is taken to a gas fractionation unit.

Example 1

The balance part of unstable gasoline having the following composition, wt.%: C ₁ - 0.1, C ₂ - 0.2, C ₃ - 3.0, C ₄ - 14.0, C ₅ - 32.0, C ₆ - the rest, from the rectification unit, is fed to the gas absorption and gasoline stabilization unit in the lower part of the absorber. A portion of the 80-180 ° C fraction is fed to the upper part of the absorber from the gasoline stabilization column, and the balance part is sent to the freight fleet. Saturated absorbent (fraction 80-180 ° C) and gasoline fractions enter the distillation column (stabilization column), where the unstable gasoline is divided into fractions: fraction n.k. - 80 ° C and a fraction of 80-180 ° C. The temperature of the bottom of the stabilization column is 191 ° C; the temperature of the top of the column is 80 ° C. The balance part of the fraction n.k. - 80 ° C is diverted to the HFC of the gas fractionation unit.

The yield of products: stable gasoline - 51.5 wt.%, Fraction n.k. - 80 ° C -47.5 wt.%, Gas - 1 wt.%.

A stable gasoline is obtained having an octane number of 92 (MI research method), a density of 765 kg / m ² , a saturated vapor pressure of 77 kPa, and the following fractional composition, wt.%: N.c. - 35 ° C, 10% - 68.5 ° C, 50% - 115 ° C, 90% - 163 ° C, K. - 200 ° C.

Qualitative composition of gasoline, wt.%: Aromatic hydrocarbons - 34.0, unsaturated hydrocarbons - 19.2, paraffins - 28.8, naphthenes - 18.0.

Example 2. Carried out under the conditions of example 1. Use unstable gasoline of the following composition, wt.%: C ₁ - 0.1, C ₂ - 0.2, C ₃ - 2.5, C ₄ - 15.0, C ₅ - 36.0, C ₆ - the rest.

The yield of products: stable gasoline - 53.5 wt.%, Fraction n.k. - 80 ° C - 45.5 wt.%, Gas - 1 wt.%.

A stable gasoline is obtained having an octane number of 95 (MI research method), a density of 776 kg / m ² , a saturated vapor pressure of 68 kPa, and the following fractional composition, wt.%: N.c. - 37 ° С, 10% - 62.5 ° С, 50% - 115 ° С, 90% - 162 ° С, c.k. - 200 ° C.

Qualitative composition of gasoline, wt.%: Aromatic hydrocarbons - 35.0, unsaturated hydrocarbons - 18.4, paraffins - 29.1, naphthenes - 17.5.

Thus, the proposed method allows to provide the required degree of stabilization of gasoline, reduce energy consumption, reduce the loss of gasoline fractions and liquefied gas.

Claims (1)

A method of processing gasoline fractions, including feeding unstable gasoline fractions to a gasoline stabilization column, separating them into fractions: stabilization head and stabilization residue, feeding the stabilization head to a gas fractionation unit to produce gas components, characterized in that the saturated absorbent from the bottom of the absorption column is fed into gasoline stabilization unit, which also receives gasoline fractions, while hydrocarbon gases from the gasoline fraction stabilization unit and saturated absorber nta is taken to the absorption column, before feeding gasoline to the stabilization column, the gasoline fractions mixed with a saturated absorbent are heated by heat transfer from the stabilization residue removed from the stabilization column as commercial gasoline, part of the stabilization residue is sent to the absorption column to absorb the propane-butane fraction from low-pressure hydrocarbon gases, followed by the supply of a saturated absorbent to the gasoline stabilization column, and the other part of the stabilization residue is taken as a tov Foot gasoline.