DE102009037460A1 - Method for separating hydrogen sulfide from a gas stream using supersonic cyclone separator, by condensing the gas stream and then conducting through the cyclone separator, in which the hydrogen sulfide is separated from the gas stream - Google Patents

Abstract

The method for the separation of hydrogen sulfide from a gas stream using supersonic cyclone separator, comprises condensing the gas stream and then conducting through the cyclone separator, in which the hydrogen sulfide is separated from the gas stream. The gas is conducted through a laval nozzle (LD) by which the gas stream is supplied in supersonic speed. The gas stream before the laval nozzle is supplied by a flow directing element (FG) to a spin. The gas behind the laval nozzle flows axially through a separation chamber (SC) and is compacted into hydrogen sulfide condensed for fluid. The method for the separation of hydrogen sulfide from a gas stream using supersonic cyclone separator, comprises condensing the gas stream and then conducting through the cyclone separator, in which the hydrogen sulfide is separated from the gas stream. The gas is conducted through a laval nozzle (LD) by which the gas stream is supplied in supersonic speed. The gas stream before the laval nozzle is supplied by a flow directing element (FG) to a spin. The gas behind the laval nozzle flows axially through a separation chamber (SC) and is compacted into hydrogen sulfide condensed for fluid in sequence of its inertia from the gas flow at an external diameter. The gas portion of the gas flow from a radial interior area, and condensed fluid from a radial external area of the separation chamber are stripped. Independent claims are included for: (1) a method for conveying natural gas loaded with hydrogen sulfide, from a source; and (2) a device for separating hydrogen sulfide from a gas stream.

Description

The The invention relates to the separation of hydrogen sulfide from a Gas flow, in particular during the transport of natural gas.

funded Natural gas is often contaminated with hydrogen sulfide, which when using the extracted natural gas as fossil Fuel for the protection of the environment from the gas stream is to be separated.

For this it is already known to apply the two-step Claus process, wherein first one third of the hydrogen sulfide to sulfur dioxide is burned and in the second step the remaining two-thirds of the hydrogen sulphide with the sulfur dioxide to sulfur and water react. The sulfur can finally act as a liquid be separated. This process is exothermic, however, requires a huge expenditure on equipment.

Another way to get rid of hydrogen sulfide gas is already in the DE 196 03 837 C2 which proposes that sodium hydroxide solution is added as a washing agent in countercurrent to the hydrogen sulphide-containing gas, wherein the hydrogen sulphide washing agent is purified for enrichment in a downstream distillation apparatus for repeated use. This method is particularly energy consuming.

The Invention has set itself the task of the separation of hydrogen sulfide from to carry out a gas flow with only a small amount of equipment.

to Solution is proposed according to the invention for the separation of hydrogen sulfide from the gas stream to a supersonic spin separator use. In addition, the invention proposes a method for separating hydrogen sulphide according to the Claim 2 before and a method for conveying natural gas according to claim 4.

decisive Advantages result from the fact that according to the invention no chemical reactions (catalysts) are required.

Corresponding supersonic spin separators are already out of the EP 0 496 128 A1 or the DE 699 10 829 T2 known.

Of the special advantage of the invention lies in the only low energy Effort and the extremely compact and simple Appendix on the one hand and on the other hand in the presence of the deposited Hydrogen sulfide in the liquid phase, which is advantageous for subsequent process steps. For example, can the liquid hydrogen sulfide with only low energy Effort due to the reduced specific volume by means of pumps pumped back into the source in the extraction of natural gas become. The supersonic spin separator points above it In addition, an excellent separation efficiency, so that, for example about 15% by weight loading of the gas stream with hydrogen sulfide before the supersonic spin separator on a 6% weight% Reduced load after supersonic spin separator can be. This process can be performed at an inlet pressure of 100 bar and an outlet pressure of about 70 bar take place. In the the supersonic spin separator takes place relaxation cools the gas flow so far from that much of the hydrogen sulfide condensed into the liquid phase and reliable is separated by centrifugal forces.

expedient The first compressed gas stream is first a cooling and then subjected to water separation, so that the separated hydrogen sulfide is not excessive diluted with water or ice is formed. This is special important in natural gas production, because here significant amounts of water from the subsidized Natural gas to be transported.

Farther it is advantageous to the gas stream or the natural gas before entry to cool in the supersonic spin separator, so that in this phase of the deposition already first amounts of hydrogen sulfide fail. These can be done by means of conventional Gravity separators are eliminated from the gas stream.

A advantageous development provides that after the supersonic spin separator a second gravity separator is provided, in which the hydrogen sulfide with its impurities in a liquid and a gaseous Phase is disconnected.

to Increasing the purity of the hydrogen sulfide can expedient after the second gravitational separator to undergo the liquid phase of a distillation, to eliminate any impurities. With these impurities For example, these may be hydrocarbons that are unscheduled excreted from the gas stream through the supersonic spin separator were, so a reunion with the purified gas stream is appropriate to natural gas.

Since the expanded gas in the supersonic spin separator is strongly cooled, this can be used in heat exchangers for cooling the incoming Gas stream can be used before entering the supersonic spin and / or before entering the water separator.

in the Interest in an additional concentration of hydrogen sulfide or a higher purity of the gas stream in terms A liberation of hydrogen sulphide can be part of the liquid Phase deposited from the supersonic spin separator has been recirculating the entering into the system gas stream be supplied.

to Clarification of the invention is an embodiment in the episode described with reference to a drawing. It shows:

1 a schematic view of a method for separating hydrogen sulfide H2S from a natural gas stream.

1 shows a schematic representation of a method for separating hydrogen sulfide H2S from a main stream MS loaded with hydrogen sulfide H2S natural gas CxHy from a source W. The funded from the source W mainstream MS is compressed by a compressor CO to 100 bar and heats up to 40th ° C. The compressor used here is preferably a seal-free compressor, so that no toxic H2S can reach the environment via shaft seals. Essential components of the main stream MS, which is also referred to as feed FD, hydrocarbons CXHY of different chain length and about 30% share is hydrogen sulfide H2S. The main flow MS passes downstream of the compressor CO a first heat exchanger HE1 and then a first separator S1, which largely separates entrained water shares. The main flow MS, which is reduced by the water H2O transported along, then reaches a second heat exchanger HE2 and a third heat exchanger HE3 and a cooler CH, which is operated by means of an external heat sink, before it reduces fractions condensed into a second separator S2, in particular by condensed hydrogen sulphide H2S becomes. The gaseous remaining compartment of the main flow MS reaches downstream a supersonic spin separator SSS, in which the flow is first swirled by flow elements FG, which are arranged on a large diameter, and then accelerated to supersonic by means of a Laval nozzle LD, so that heavier fractions of the Mainstream MS on an outer diameter of the assembly by centrifugal forces - this is mainly condensed hydrogen sulfide H2S. The main flow as the core flow in the supersonic spin separator SSS is collected by means of a central diffuser retarded CP and the separation flow SF1 in outer chambers. The cooled to about -18 ° C main flow, which has only 6% hydrogen sulfide H2S, is still used on the secondary side of the first heat exchanger HE1 for cooling the main stream 40 ° C hot MS downstream of the compressor CO, before he subjected further process steps not shown becomes.

The first separation stream SF1 reaches downstream of the supersonic spin separator SSS a third separator S3, in which essentially gaseous fractions of liquid fractions are separated under the effect of gravity g, the liquid fraction being fed as second separation stream SF2 and the gaseous fraction as third separation stream SF3 being fed to further process steps becomes. The second separation stream SF2 reaches a distillation unit REB, in which the hydrogen sulfide H2S is concentrated to about 80%, the concentrated hydrogen sulfide H2S being pumped back into the source W by means of a third pump PE3. The gaseous medium expelled in the distillation plant REB is fed to a third separator S3 as the sixth separation stream SF6, where it is at least partially supplied as a third separation stream SF3 together with the gaseous fractions of the first separation stream SF1 to a cooling plant HE4. This cooling system HE4 is operated by means of an external cooling medium. Downstream of this cooling, in a fourth separator S4, the third separating stream SF3 is repeatedly divided into a gaseous fifth separating stream SF5 and a liquid fourth separating stream SF4. The fourth separation stream SF4 is conveyed by means of a first pump P1 on the secondary side of the third heat exchanger HE3 in order to cool down the main stream MS prior to entry into the cooler CH and finally combined with the seventh separation stream SF4 from the second separator S2 into the third separator S3 to become. From the distillation unit REB a portion of the second separation stream SF2 is diverted to recirculation REC and fed to the main flow MS before the second heat exchanger HE2. The temperatures, pressures and proportions of hydrogen sulfide H2S are for different stations of the main flow MS and the separation flows SF1 to SF7 the 1 removable.

The supersonic spin separator SSS initially has flow elements which impart a twist to the flow. Downstream of the flow elements, a Laval nozzle LD is arranged, by means of which the main flow MS is accelerated to supersonic speed. In a subsequent deposition chamber SC round cross-section, condensed portions of the main stream MS, which consist essentially of hydrogen sulphide H2S, collect on the radia due to the rapid cooling len outer diameter of the deposition chamber SC and reach a separation opening with a pressure of about 70 bar and a temperature of about -29 ° C. The still gaseous main stream MS is removed by means of a central diffuser CP from the deposition chamber SC.

The individual separators S1-S4 each use gravity g for separating the liquid components from the gaseous.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 19603837 C2 [0004]
• EP 0496128 A1 [0008]
• - DE 69910829 T2 [0008]

Claims (11)

Use of a supersonic spin separator (SSS) for separating hydrogen sulphide (H ₂ S) from a gas stream. A method of separating hydrogen sulphide (H ₂ S) from a gas stream, wherein the gas stream is compressed and passed through a supersonic spin separator (SSS) in which the hydrogen sulphide (H ₂ S) is separated from the gas stream. The method of claim 2, wherein the gas is passed through a Laval nozzle (LD), by means of which the gas flow is superimposed supersonic velocity, wherein the gas flow in front of the Laval nozzle (LD) by means of flow guide elements (FG) is imparted a twist, wherein the gas behind the Laval nozzle (LD) flows axially through a separation chamber (SC) is forced in the condensed hydrogen sulfide (H ₂ S) due to its inertia of the gas stream to an outer diameter, wherein the gas portion of the gas stream from a radially inner region and condensed liquid a radial outer region of the deposition chamber (SC) is withdrawn. Method for conveying natural gas loaded with hydrogen sulfide (H2S) from a source (W), wherein the natural gas is compressed in a - first step, - second step takes place by means of a supersonic spin separator (SSS) a separation of hydrogen sulfide (H ₂ S). Process according to claim 4, wherein separated liquid hydrogen sulfide (H ₂ S) is pumped back to the source (W). Method according to one of claims 4 or 5, wherein downstream of the supersonic spin precipitator (SSS) separated hydrogen sulfide (H ₂ S) in a third separator (S3) is cleaned of foreign matter. Method according to one of claims 4 to 6, wherein downstream of the supersonic spin separator (SSS) or the third separator (S3) for purifying the hydrogen sulfide (H ₂ S) of foreign matter by means of heating in a boiler foreign matter from the hydrogen sulfide (H ₂ S) become. Method according to one of claims 4 to 7, wherein after the compression upstream of the supersonic spin separator (SSS) a water separation is provided. Method according to one of claims 4 to 8, wherein after the compression upstream of the supersonic spin separator (SSS) a cooling in a first heat exchanger (HE1) is provided. The method of claim 9, wherein before the supersonic spin separator (SSS) and after cooling in the first heat exchanger (HE1), a separation of hydrogen sulfide (H ₂ S) is provided in a separator. Device for separating hydrogen sulphide (H ₂ S) from a gas stream, in particular from a natural gas stream, in particular by a method according to claims 1-10, characterized by: at least one compressor for compressing the natural gas, at least one heat exchanger (HE1) for cooling the compressed natural gas, at least one second separator (S2) for separating condensed hydrogen sulfide from the natural gas before, at least one supersonic spin separator (SSS) having a Laval nozzle (LD) is passed, by means of which the gas flow is supersonic velocity impressed, at least one flow guide ( FG), by means of which the gas flow in front of the Laval nozzle (LD) is imparted swirl, at least one axially flowed Abscheidekammer (SC) downstream of the Laval nozzle (LD) and the flow guide (FG), in the condensed to the liquid hydrogen sulfide (H ₂ S) in Follow its inertia from the gas stream to one Outside diameter is urged, wherein the gas portion of the gas stream from a radially inner region by means of at least one central exhaust pipe (CP) and the liquid from a radially outer region by means of at least one outer discharge (EE) from the deposition chamber (SC) are deducted.

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