DE102015202649A1 - Process and device for the regeneration of a hydrogen sulphide-containing washing medium - Google Patents

Abstract

The invention relates to a method for regenerating a hydrogen sulphide-containing washing medium (3), wherein the washing medium (3) flows through a regeneration stage (5) in which hydrogen sulphide contained in the washing medium (3) is precipitated as elemental sulfur, wherein the washing medium (3) Flow through the regeneration stage (5) with an oxygen-containing gas (27) is contacted, which flows through the regeneration stage (5) in one of the flow direction (22) of the washing medium (3) opposite flow direction (28), wherein the oxygen-containing gas (27) when flowing through the regeneration stage (5) with cooling of the washing medium (3) is heated by this, and wherein the oxygen-containing gas (27) flows automatically as a result of heating in the regeneration stage (5). Furthermore, the invention relates to a device (1) by means of which such a method can be carried out.

Description

The invention relates to a process for the regeneration of a hydrogen sulphide-containing washing medium. Furthermore, the invention relates to a device for the regeneration of a hydrogen sulfide-containing washing medium.

Natural gas is a fossil fuel with a relatively low emission of carbon dioxide (CO ₂ ) and a relatively low emission of other waste products during combustion. Its contribution as one of the most important energy resources of the world is steadily increasing. In view of the scarcity of raw materials, the permanently increasing energy demand and environmental protection reasons, the treatment and utilization of natural gas thus represents a promising possibility for the efficient and low-emission generation of energy.

However, the direct use of natural gas is sometimes only possible to a limited extent. Due to the acidic components, in particular hydrogen sulfide (H ₂ S), raw natural gas often can not be used directly in a gas turbine, for pipeline transport or in a combined heat and power plant (CHP). Therefore, natural gas streams with a high content of hydrogen sulphide are often flared unused. Accordingly, there is a major challenge in the treatment of acid gases, especially in the separation of hydrogen sulfide.

For this purpose, various deposition techniques are known in which physical or chemical absorption media, which are also called wash media, are used to ensure the required for a further use of the respective gas purities.

In addition to the separation of the hydrogen sulfide from the respective gases in particular, a regeneration of the respective washing medium is necessary in order to use its use in the context of H ₂ S separation as efficiently as possible. A common method for targeted removal of hydrogen sulfide from a washing medium is, for example, in its targeted heating. By heating the hydrogen sulfide is expelled from the washing medium. Such processes usually require a costly post-treatment of the hydrogen sulfide, for example in a so-called Claus process, where the hydrogen sulfide is converted to elemental sulfur.

As an alternative to such a thermal process, liquid-reducing sulfur recovery processes, so-called liquid redox processes, can be used. Here, a redox agent is used to convert hydrogen sulfide contained in a washing medium into sulfur and to remove the hydrogen sulfide so from the washing medium. The redox agent is reduced by the hydrogen sulfide, then oxidized by contacting with an oxygen-containing gas and regenerated accordingly. The supply of the gas takes place, for example, via specially designed blower or by the gassing with compressed oxygen-containing air.

The invention is based, as a first object, on a method by means of which the separation of hydrogen sulphide from a washing medium can be carried out more efficiently and more cost-effectively than conventional methods.

A second object of the invention is to specify a device in which a corresponding method can be carried out economically.

The first object of the invention is achieved by a method for regenerating a hydrogen sulfide-containing washing medium, wherein the washing medium flows through a regeneration stage, is precipitated in the hydrogen sulfide contained in the washing medium as elemental sulfur, wherein the washing medium is contacted when flowing through the regeneration stage with an oxygen-containing gas , which flows through the regeneration stage in a flow direction of the washing medium opposite flow direction, wherein the oxygen-containing gas is heated as it flows through the regeneration stage with cooling of the washing medium, and wherein the oxygen-containing gas flows as a result of heating automatically in the regeneration stage.

The invention is based on the fact that the necessary for the regeneration of a washing medium by the separation of hydrogen sulfide throughput of oxygen-containing gases sometimes only with high energy requirements, such as by the targeted heating of the washing medium or by means of a previously compressed oxygen-containing gas can be implemented. The required air flow was achieved with an additional energy input into the process, which in turn adversely affects the energy efficiency and thus the efficiency of the overall process.

The invention now recognizes that it is possible to reduce the energy requirement of a regeneration process if the oxygen-containing gas required for the regeneration of a washing medium flows into the regeneration stage without additional aids. The dosage of the gas is carried out accordingly preferably uncompressed or uncompressed, so that in particular is dispensed with the use of compressors for gas metering. In other words, the necessary gas throughput is achieved without additional energy input.

The process uses the so-called chimney effect. The washing medium and the oxygen-containing gas flow through the regeneration stage in opposite directions of flow, so they are guided in countercurrent through the regeneration stage. In the regeneration step, the gas phase, the oxygen-containing gas, and the liquid phase, the washing medium, are brought into contact with each other, the warmer washing medium heating the oxygen-containing gas. The heated gas rises within the regeneration stage upwards in the direction of the head of the regeneration stage and draws in this case fresh cold gas. In other words, the gas is "sucked" by the heating due to the resulting negative pressure in the regeneration stage, so that the gas flows in automatically and in particular under ambient pressure, so that no compression is required. The regeneration stage is open in this respect and is in exchange with the environment.

The oxygen-containing gas thus flows without additional energy input from the outside, in particular under ambient pressure in the regeneration stage. In other words, the heat of the washing medium is used selectively to dose without additional expenditure of energy required for the regeneration of the washing medium oxygen-containing gas in the regeneration stage. Furthermore, due to the associated cooling of the washing medium is preferably dispensed with the use of additional heat exchanger.

Conveniently, the oxygen-containing gas flows into the bottom of the regeneration stage in this. The hydrogen sulfide-containing wash medium preferably flows into the head of the regeneration stage in this. As a result, the chimney effect is used particularly efficiently.

The washing medium itself, which is fed to the regeneration stage, is expediently taken from an absorber in which the hydrogen sulfide to be separated has been absorbed in the washing medium. The washing medium is in this case passed either to the head of the regeneration stage due to the pressure prevailing in the absorber or by means of a pump.

Conveniently, the hydrogen sulfide contained in the washing medium reacts after the feed to the regeneration stage within the regeneration stage with a catalytically active component to elemental sulfur. It is thus a catalyzed hydrogen sulfide reaction. In principle, there is the possibility that the catalytically active component is contained within the regeneration stage. For example, solid particles in the regeneration stage are conceivable. It is also possible that the regeneration stage is structurally such that, for example, the walls of the regeneration stage itself act as a catalyst.

It is particularly advantageous, however, if the catalytically active component is contained in the washing medium. Accordingly, a washing medium with a catalytically active component is expediently used. Such a washing medium allows a homogeneous reaction of the two dissolved reactants, ie the hydrogen sulfide and the catalytically active component itself. Preferably, a metal salt is used as the catalytically active component. In principle, all metal salts of which the metal ions can be present in several oxidation states are suitable here. Preferably, the salts of the metals iron, manganese or copper are used. These metal salts are inexpensive to acquire and have the desired catalytic properties.

Expediently, a washing-active substance which serves to absorb hydrogen sulfide is also present in the washing medium. Accordingly, a washing medium is preferably used which contains a detergent-active substance and the catalytically active component. As the washing-active substance, an amino acid salt is preferably used.

To improve the solubility of the respective metal salt or salts, it is advantageous if a washing medium is used to which a complexing agent has been added. The complexing agent prevents precipitation of the metal ions as metal sulfides (MeS). In principle, all complexing agents that are able to keep the metal ions in solution are suitable. Preferably, EDTA, citrate ions or chloride ions are used.

In principle, the oxidation of the hydrogen sulfide to elemental sulfur takes place with simultaneous reduction of the metal ion. For example, in a washing medium which contains iron (III) chloride (FeCl ₃ ) dissolved as a catalytic active component, elementary sulfur (S) is formed by reaction of the Fe (III) ions in solution with the hydrogen sulfide (H ₂ S). and Fe (II) ions. The Fe (III) ions are thus reduced by the reaction with hydrogen sulfide, whereby the hydrogen sulfide is oxidized to sulfur. The sulfur precipitates as a solid and the Fe (II) ions remain in solution. To prevent the Fe (II) - Forming ions iron sulfide (FeS) is added to the washing medium EDTA as a complexing agent.

For reuse of the catalytically active component, this must be regressed again. The recovery of the catalytically active component preferably takes place by reaction with the oxygen-containing gas flowing into the regeneration stage. Here, the oxygen-containing gas is understood as meaning any gas whose oxygen content is high enough to rebuild the catalytic active components. As an oxygen-containing gas, for example, ambient air, oxygen-enriched air or pure oxygen can be used.

When the washing medium comes into contact with the gas, the oxygen contained in the gas passes from the gas phase into the liquid phase, ie into the washing medium. In the liquid phase, the oxidation of the metal ion previously reduced in sulfur formation takes place, as described above, for example, Fe (II) ions to Fe (III) ions, so that they are again available for the separation of hydrogen sulfide, ie for repeated oxidation.

In principle, it is possible to spray the washing medium into the regeneration stage from the head. To ensure the necessary air movement, for example, fans could be used.

It is particularly advantageous if a fixed bed reactor is used as the regeneration stage. In a fixed bed reactor, one or more fluids typically flow through a packed bed or packing. In the case of a liquid and a gaseous phase one speaks of trickle beds or trickle bed reactors. Fixed bed reactors are common standard systems, especially in the water industry. However, the use for aeration or the fumigation of washing media in the context of the separation of hydrogen sulfide is not yet common. Due to their robust construction, the small number of moving components and in particular the fact that the air flow can take place without additional input of energy, however, fixed bed reactors are surprisingly also suitable for the separation of hydrogen sulfide from a washing medium.

The fixed bed reactor is preferably designed as a reactor with a tubular base body in which expediently packing are. The packing, the packed bed, provide a large surface area for the mass transfer between the liquid phase and the gas phase, ie between the washing medium and the oxygen-containing gas. As a filler, for example, plastic particles can be used.

In a further advantageous embodiment, the purified of hydrogen sulfide wash medium is withdrawn at the bottom of the regeneration stage. Conveniently, the purified from hydrogen sulfide wash medium from the regeneration stage is fed into the absorber. There it is preferably used again for the absorption of hydrogen sulfide, for example from an acidic natural gas, an associated gas of oil production or biogas.

The second object of the invention is achieved by a device for regenerating a hydrogen sulfide-containing washing medium, comprising a regeneration stage for precipitating hydrogen sulfide contained in the washing medium as elemental sulfur by means of an oxygen-containing gas, wherein the regeneration stage comprises a supply line for the washing medium and a supply of fresh air is formed to an automatic inflow of the oxygen-containing gas in the regeneration stage.

A device to which the oxygen-containing gas can be supplied automatically, in particular under ambient pressure, allows the separation of hydrogen sulfide and thus the regeneration of the washing medium without additional energy consumption. Due to the chimney effect, in which the oxygen-rich gas rises in the regeneration stage and flows out at the top of the regeneration stage, creates a negative pressure, which is compensated by a subsequent flow of gas through the supply air. The supply of the oxygen-rich gas thus takes place without the use of additional aids, such as compressors or compressors.

For supplying the oxygen-containing gas, the supply air is expediently formed at the bottom of the regeneration stage. The supply air is preferably formed in the form of supply openings in the regeneration stage. The regeneration stage itself is preferably fluidly downstream of an absorber with respect to the supply line for the washing medium. Thus, the washing medium taken from or discharged from an absorber can be supplied to the regeneration stage. The absorber is preferably coupled via a discharge line with a supply line of the regeneration stage. The supply line is expediently connected to the head of the regeneration stage, so that the washing medium from the head can flow downwards through the regeneration stage, ie in the direction of the bottom of the regeneration stage.

Preferably, a catalytically active component is used to precipitate the hydrogen sulfide contained in the washing medium. In particular, a metal salt is used as the catalytically active component.

As the washing medium itself, an aqueous amino acid salt solution is preferably used. The catalytically active component is added to the washing medium expediently.

The regeneration stage is formed in a further advantageous embodiment as a fixed bed reactor. The fixed bed reactor is expediently formed with a reactor tube, are arranged in the packing. The packing increases the mass transfer area between the liquid washing medium and the oxygen-containing gas.

Appropriately, the regeneration stage with respect to the discharge line fluidly downstream of an absorber. Thus, the purified of hydrogen sulfide wash medium can be returned to the absorber. For this purpose, the discharge line of the regeneration stage is expediently coupled to a supply line of the absorber. The washing medium is thus conducted in a circuit.

In the following an embodiment of the invention will be explained in more detail with reference to a drawing.

In 1 is a device 1 shown the separation of in a washing medium 3 absorbed hydrogen sulfide and thus a regeneration of the washing medium used 3 allows. The device 1 includes a trained as a fixed bed reactor regeneration stage 5 , which fluidly with an absorber 7 is coupled.

The absorber 7 is via a supply line 9 a hydrogen sulfide containing gas stream 11 fed and there with the unloaded washing medium 3 brought into contact. As a washing medium 3 is an aqueous solution of amino acid with dissolved ferric chloride as the catalytically active component 15 used. The amino acid salt is the detergent component that absorbs in the wash medium 3 contained contained hydrogen sulfide.

The hydrogen sulfide gets inside the absorber 7 in the washing medium 3 absorbed. The purified from hydrogen sulfide gas stream 9 is about an absorber 7 connected withdrawal line 16 removed from the process.

The loaded with hydrogen sulfide wash medium 3 is then from the absorber 7 the regeneration stage 5 fed. The absorber 7 this is via a discharge line 17 with a supply line 19 the regeneration stage 5 coupled. The feed line 19 is especially on the head 21 the regeneration stage 5 connected so that the washing medium 3 from the head 21 starting from the regeneration stage 5 down, so in the flow direction 22 to the ground 23 the regeneration stage 5 can flow.

In the regeneration stage 5 The hydrogen sulfide reacts with the dissolved iron (III) chloride, the catalytically active component 15 , The reaction of the Fe (III) ions with the hydrogen sulfide forms elemental sulfur and Fe (II) ions. In order to prevent the Fe (II) ions from forming iron sulfide (FeS), EDTA is added as a complexing agent to the washing medium.

To the catalytically active component 15 to rebuild, becomes the wash medium 3 within the regeneration stage 5 with an oxygen-containing gas 27 , in the present case air, brought into contact. For this purpose, the chimney effect is exploited. The air 27 flows in one of the flow direction 22 of the washing medium 3 opposite flow direction 28 via an air supply 29 , here in the form of two feed openings 30 from the ground 23 the regeneration stage 5 starting in this one. The washing medium 3 and the air 27 are thus within the regeneration stage 5 conducted in countercurrent.

The washing medium 3 heats the incoming air 27 , The heated air 27 rises within the regeneration stage 5 upwards in the direction of the head 21 the regeneration stage 5 and draws due to the resulting negative pressure fresh cold air 27 through the feed openings 30 to. In addition, in the present case at one of the feed opening 30 another fan 31 arranged, by means of which the air in the regeneration stage 5 is blown. The fan 31 this has only supportive effect. For the purposes of the invention can also be dispensed with.

By the air 27 contained oxygen, the previously reduced in the oxidation of the hydrogen sulfide to Fe (II) ions iron ions are re-oxidized to Fe (III) ions. To encourage this reaction is the regeneration step 5 as a fixed bed reactor 32 educated. The fixed bed reactor 32 is with a reactor tube 33 formed in the filler 33 are made of plastic. The packing 33 serve the enlargement of the surface and thus the improvement of the mass transfer between the liquid phase, so the washing medium 3 and the gas phase, ie the air 27 ,

From between the packing 33 , ie the air flowing through the bulk bed 27 oxygen enters from the gas phase 27 in the liquid phase 3 above. The dissolved oxygen oxidizes the Fe (II) ions present in the solution to Fe (III) ions, so that they can be used again for the actual separation process of hydrogen sulfide. The exhaust air flows at the head 21 the regeneration stage 5 via a corresponding exhaust air line 39 out.

The regenerated, so freed from hydrogen sulfide wash medium is on the ground 23 the regeneration stage 5 collected and in the absorber 7 recycled. This is one of the regeneration stage 5 connected discharge line 41 with a supply line 43 coupled to the absorber. The purified by hydrogen sulfide washing medium 3 can then be within the absorber 7 be used again for the absorption of hydrogen sulfide from a gas stream.

Claims (16)

Process for the regeneration of a hydrogen sulphide-containing washing medium ( 3 ), whereby the washing medium ( 3 ) a regeneration stage ( 5 ), in which in the washing medium ( 3 ) hydrogen sulfide is precipitated as elemental sulfur, wherein the washing medium ( 3 ) when flowing through the regeneration stage ( 5 ) with an oxygen-containing gas ( 27 ) contacting the regeneration stage ( 5 ) in one of the flow direction ( 22 ) of the washing medium ( 3 ) opposite flow direction ( 28 ), whereby the oxygen-containing gas ( 27 ) when flowing through the regeneration stage ( 5 ) while cooling the washing medium ( 3 ) is heated by this, and wherein the oxygen-containing gas ( 27 ) as a result of heating automatically in the regeneration stage ( 5 ) flows in. Process according to claim 1, wherein the oxygen-containing gas ( 27 ) on the ground ( 23 ) of the regeneration stage ( 5 ) flows in. Process according to claim 1 or 2, wherein the hydrogen sulphide-containing washing medium ( 3 ) on the head ( 21 ) of the regeneration stage ( 5 ) is supplied. Method according to one of the preceding claims, wherein the in the washing medium ( 3 ) contained hydrogen sulfide within the regeneration stage ( 5 ) with a catalytically active component ( 15 ) reacts to elemental sulfur. Process according to claim 4, wherein as the catalytically active component ( 15 ) a metal salt is used. Process according to claim 4 or 5, wherein the catalytically active component ( 15 ) by reaction with the in the regeneration step ( 5 ) inflowing oxygen-containing gas ( 27 ) is regressed. Method according to one of the preceding claims, wherein as regeneration stage ( 5 ) a fixed bed reactor ( 31 ) is used. Process according to any one of the preceding claims, wherein the washing medium purified by hydrogen sulphide ( 3 ) on the ground ( 23 ) of the regeneration stage ( 5 ) is deducted. Process according to any one of the preceding claims, wherein the washing medium purified by hydrogen sulphide ( 3 ) from the regeneration stage ( 5 ) in an absorber ( 7 ) to be led. Contraption ( 1 ) for the regeneration of a hydrogen sulphide-containing washing medium ( 3 ), comprising a regeneration stage ( 5 ) for precipitation in the washing medium ( 3 ) containing hydrogen sulfide as elemental sulfur by means of an oxygen-containing gas ( 27 ), whereby the regeneration stage ( 5 ) a supply line ( 19 ) for the washing medium ( 3 ) and an air supply ( 29 ), which leads to an automatic inflow of the oxygen-containing gas ( 27 ) into the regeneration stage ( 5 ) is trained.. Contraption ( 1 ) according to claim 10, wherein the supply air ( 29 ) in the area of the soil ( 23 ) of the regeneration stage ( 5 ) is formed and / or wherein the supply line ( 19 ) on the head ( 21 ) of the regeneration stage ( 5 ) opens. Contraption ( 1 ) according to claim 10 or 11, wherein the regeneration stage ( 5 ) with respect to the supply line ( 19 ) fluidically an absorber ( 7 ) is connected downstream. Contraption ( 1 ) according to any one of claims 10 to 12, wherein the precipitate in the washing medium ( 3 ) contained a catalytically active component ( 15 ) is used. Contraption ( 1 ) according to claim 13, wherein as the catalytically active component ( 15 ) a metal salt is used. Contraption ( 1 ) according to any one of claims 10 to 14, wherein the regeneration step ( 5 ) as a fixed bed reactor ( 31 ) is trained. Contraption ( 1 ) according to any one of claims 10 to 15, wherein the regeneration stage ( 5 ) a discharge line ( 41 ) for purified washing medium ( 3 ), and wherein the regeneration stage ( 5 ) with respect to the discharge line ( 41 ) fluidically an absorber ( 7 ) is connected downstream.

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