DE2329608A1 - Wash liquor regeneration in compressed gas purificn. - using waste gas from claus process - Google Patents

Abstract

The wash liquor is used for the purificn. of compressed gases by removing acid constituents, esp. H2S by physical absorption. It is purified by releasing to normal pressure, then treating with an inert gas at normal or elevated temp. using the waste gas from a Claus process, in which the S vapour and H2S have been converted to SO2 by after-burning, the SO3 and O2 removed by passing over a bed of coke at 200-500 degrees C and the SO2 removed by scrubbing with aq. alkali salt soln. The regenerated liquor is recycled and reused, whilst the H2S-rich gas is converted to SO2 in a subsequent Claus process. The process is economical and avoids stoppages caused by deposition of S in the pipes.

Description

METALLGESSLISCHAFT Frankfurt / Main, June 7th 1973

Aktiengesellschaft -DrLa / HSz-

No. 7199 lo

Process for the purification of gases under pressure

The invention relates to a method for cleaning under Gases under pressure due to the physical absorption of acidic gas components, especially hydrogen sulfide with subsequent regeneration of the detergent by releasing it to normal pressure, gassing the detergent with an inert gas at normal or elevated temperature, recycle and reuse of the regenerated Detergent and treatment of the hydrogen sulphide-rich waste gas of the regeneration to elemental sulfur in one downstream Claus process.

In gas cleaning technology, gases are removed by absorption processes, i.e. by washing with suitable solvents, cleaned. The impurities to be removed are primarily acidic in nature, v / ie e.g. hydrogen sulfide, Carbon dioxide and other compounds.

In the well-known cycle between absorption, in which the detergent _{absorbs the acidic gases H 2} S and CO ₂ from the gas to be cleaned in countercurrent, and regeneration, in which the dissolved acid gases are released again through desorption, the absorbers are the same in all of them Washing method largely. The main differences are in the type of desorption. This can be done by releasing the detergent loaded with the gaseous impurities to atmospheric pressure with subsequent expulsion (stripping) of the remaining dissolved constituents.

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The expulsion can be done by heating the detergent or with A vacuum or a foreign gas, e.g. nitrogen, can be used ("Chemie-Ingenieur-Technik", 40, (1968), pages 452 to 440). As a foreign gas, nitrogen has the advantage of being completely chemically neutral. Nitrogen is available however, it is often not available, or not available in sufficient quantities, apart from the fact that its provision comes at a cost connected is.

Other gases, such as air, carbon dioxide or their mixtures, or flue gases, which have already been proposed as stripping gas, are chemically not sufficiently neutral. Gases containing carbon dioxide would be more alkaline in the regeneration of chemicals Washing solutions cannot be used anyway. However, like air, they are already physically used for regeneration solvent detergents have been proposed.

It has also been shown in the leaching of sulfur compounds, in particular hydrogen sulfide, from gases that the Regeneration of the washing solution with air or flue gas leads to difficulties. In both cases it reacts in the gas contained oxygen with the hydrogen sulfide still contained in the washing solution to elemental sulfur, which precipitates in the solution and causes blockages in the lines and thus downtimes of the system.

DT-OS 1 801 539 describes a special type of regeneration in a process for the purification of industrial gases by absorbing the impurities contained therein especially the carbon dioxide under pressure in a high-boiling, water-miscible, organic solvent, which by Relaxation and / or stripping is regenerated with an inert gas and then returned to the absorption. The procedure is characterized in that from the

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emerging gas streams the water vapor is washed out with the absorbent that from the leaving the process Gas streams of the solvent vapor is washed out with V / ater and that the washing steps proceeding from these washing stages Mixtures of absorbent and water are worked up together in a stripping distillation, in the exhaust gas from the relaxation regeneration is used as a stripping agent, and from the pure absorbent as the bottom product is recovered. '

However, this procedure is not applicable in all cases, especially not when cleaning gases that Contain hydrogen sulfide because the flash gas always contains certain, albeit small, proportions of hydrogen sulfide, so that the detergent does not during regeneration can be completely freed from hydrogen sulfide. This means that even if this detergent is reused in the Absorption process does not achieve the required gas purity, especially freedom from hydrogen sulfide. Practically Therefore, this method of operation can only be used with hydrogen sulphide-free gases.

In order to circumvent these difficulties, attempts have been made to take advantage of the cheapness of flue gas in that through substoichiometric combustion of a sulfur-free fuel (e.g. natural gas, liquid gas) with air a practical oxygen-free flue gas is generated and this is used as a stripping gas in the regeneration process of the detergent (DT-OS 2 124 056).

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However, this mode of operation requires a special spreading device and an expense of fuel. Apart from this, the use of a sub-stoichiometric Combustion of the flue gas produced as stripping gas in an undesirable manner, still unburned hydrocarbons, mainly methane, in the hydrogen sulfide-containing exhaust gas from the regeneration, that of a Claus plant for conversion of the hydrogen sulfide in the elemental sulfur is supplied.

The invention aims to address these and others Avoid disadvantages of the known method. The proposed method aims to be simple and economical Way to purify pressurized gases by physical absorption, followed by the detergent regenerated and the hydrogen sulfide-rich stripping gas the regeneration is to be converted to elemental sulfur in a downstream Claus process.

According to the invention, this object is achieved in that for gassing the relaxed detergent, the exhaust gas of a Claus process used, in which the hydrogen sulfide was converted into sulfur dioxide by post-combustion, by passing over a layer of coke at temperatures of ' 200 to 500 ° C has been freed from sulfur trioxide and oxygen and from which the SO «by washing in a aqueous alkali salt solution is removed.

According to a further embodiment of the invention, a small portion of the detergent is continuously or intermittently Freed from dissolved sulfur by distillation and fed back into the detergent circuit.

The advantages achieved with the invention exist in particular that it succeeds in a simple and economical way, pressurized gases by physical To purify absorption and regenerate the detergent,

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without the regeneration through clogging due to excretion elemental sulfur is hindered »blockages in the lines and thus system downtimes avoided by the invention.

The method of operation according to the invention does not require any special combustion equipment and no expenditure on fuel. The new process prevents uncombusted hydrocarbons, e.g. methane, from entering the hydrogen sulfide Containing exhaust gas from the regeneration, which is fed to the Claus plant, arrive.

The traces of SOp contained in the exhaust gas are converted into elemental sulfur when the hydrogen sulfide-laden detergent is stripped with H ₂ S, which is at least up to 1% by weight soluble in the detergents used in practice at the detergent strip temperature used. According to the invention, a small part of the detergent, which is in the order of magnitude of less than 0.1 %, is cleaned continuously or intermittently by distilling off the dissolved sulfur and added to the main detergent flow so that the level of the sulfur dissolved in the detergent is constant and below the sulfur saturation concentration remain.

The invention is described in the following exemplary embodiment and in the drawing.

example

A natural gas which contains 6.2% by volume of CO ₂ and 7 »0 % by volume of H ₂ S and is under a pressure of 76 at, is fed through line 30 (see flow diagram) to a scrubbing tower 31, where the gas with N -Methylpyrrolidone is washed as a detergent to a residual content of 1 ppm H ₂ S. The detergent is fed to the washing tower through line 32. The loaded detergent is in a first expansion stage 33 to a pressure of

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6 at relaxed and degassed in the relaxation tower 34. The expansion gas released, mainly methane and some carbon dioxide and low concentrations of H ₂ S, is sucked in by a compressor 36 through line 35 and compressed by the latter to the operating pressure and returned to the sump of the washing tower 31 through line 37.

The V / aschinmittel expanded to 6 atm is then fed via line to a second expansion stage 39, in which it is expanded to atmospheric pressure and then passed through line 40 to the top of the regeneration tower 41. In the regeneration tower 41, the detergent is stripped free of the dissolved hydrogen sulfide and regenerated with the aid of heated stripping gas, which mainly consists of N _{2 and a small proportion of CO 2.} The stripping gas is fed to the regeneration tower 41 after previous heating to temperatures of 100 to 120 ° C. in a heater 42 through line 43. The expelled HpS-containing gas, after cooling by the cooling device 44, is fed through line 24 to the Claus plant, in which the hydrogen sulfide is converted with SO ₂ , which is fed in through line 23, to form elemental sulfur.

The gas used for the stripping is practically SO ₂ -free exhaust gas from the S0 ₂ scrubbing 6, which is part of the modified Claus plant and this is connected downstream. The Claus plant including SO ₂ post-wash consists essentially of the Claus reactor 1, the sulfur condenser 2, the sulfur separator 3, the post-combustion chamber 4, the coke filter 5, the absorption tower 6 and the regeneration tower 7.

The residual gas from the Claus process is transferred from the sulfur separator 3 in the line 8 to the post-combustion chamber 4 passed and there with the addition of a preferably gaseous

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Burned fuel from line 9 and excess air from line 10, with unseparated sulfur and unreacted hydrogen sulfide being converted into sulfur dioxide, but also small amounts of SO are formed. The exhaust gas from this afterburning is conducted in line 11, optionally with intermediate cooling, into the coke filter 5, in which the SO _{5 is} reduced to SO ₂ at temperatures between 200 and 500 ° C. and the excess oxygen is consumed with binding to COp. The gas has a higher temperature at the outlet of the coke filter 5 than at the inlet and now contains neither SO ₇ . still free oxygen. It is introduced with the line 12 through a heat exchanger 13 and a cooler 14 at approximately ambient temperature into the absorption tower 6 via its sump and washed with regenerated absorption solution. At the top of the absorption tower 6, an exhaust gas with a sulfur dioxide content of less than 200 ppm flows off. Unless it is discharged into the atmosphere through the chimney 15, it is fed through line 43 to the regeneration tower 41 of the natural gas scrubbing facility after it has been heated by the preheater 42.

The absorption solution loaded with SO «, which is an aqueous alkali salt solution of a weak acid, for example a solution of Na ₂ SO ,, NapHPO ·, NaAs Op, is transferred from the sump of the absorption tower 6 in the line 16 by means of the pump 17 through the heat exchanger 18 Head of the regeneration tower 7 and flows in this via packing down to the sump. There the solution is heated to boiling by means of the heating device 19, as a result of which the absorbed SO _{2 is} completely expelled and stripped from the solution trickling down by the rising steam. From the top of the regeneration tower 7, the exhaust gas consisting of sulfur dioxide and water vapor is passed in the line 20 to the condenser 21, from which the condensate that has been precipitated is returned to the regeneration tower in the line 22. _ ο

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The remaining concentrated sulfur dioxide is in the Line 23 passed through the heat exchanger 13 to the Claus reactor 1. This SOp stream is before entering the Y / heat exchanger 13 from line 24, the hydrogen sulfide-containing gas to be processed is added.

The Claus reactor 1 with the associated sulfur condenser and the sulfur separator 3 can be multi-stage in a known manner be trained.

The implementation of HpS and SOp in the Claus reactor takes place in in a known manner on a granular contact mass preferably made of bauxite. The elemental formed in the reaction Sulfur runs off in liquid form from this and is fed from the reactor 1 in a line 23 to the collecting container 26. This also contains the quantities of liquid sulfur that precipitate in the sulfur condenser 2 and in the sulfur separator 3, transferred through lines 27 and 28.

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Claims (2)

Claims 1) Methods of cleaning pressurized gases by physical absorption of the acidic gas components, in particular the hydrogen sulfide with subsequent Regeneration of the detergent by releasing it to normal pressure, gassing the detergent with an inert gas normal or elevated temperature, circulation and Recycle of the regenerated ash and processing of the hydrogen sulphide-rich stripping gas of the regeneration to elementary rock in a downstream Claus process, characterized in that the exhaust gas from a Claus process is used for gassing the relaxed V / ash medium used, in velcheii the sulfur vapor and the hydrogen sulfide were converted to sulfur dioxide by afterburning, then by passing sulfur trioxide and oxygen over a layer of coke at temperatures of 200 to 500 ° C has been freed and from which the sulfur dioxide is removed by washing with an aqueous alkali salt solution is, 2) Method according to claim 1, characterized in that _t aschmittels by distillation, freed continuously or intermittently a small fraction of V / dissolved sulfur and the detergent cycle of technical wash the gas supplies again. 409882/0474 Blank page COPY