DE1494785B1 - Process for processing natural gas - Google Patents

Description

The invention relates to a method for processing natural gas by means of adsorption and absorption, in which the acidic gas components are removed.

Methods for cleaning gas mixtures are known. To remove acidic gas components, such as. B. hydrogen sulfide and carbon dioxide from a hydrocarbon stream, such as. B. from a natural gas stream coming from the borehole, both absorption and chemical reaction methods have been known to have been used. For example, in German patent specification 535 763, a process for cleaning gas mixtures is described in which the process is carried out in stages and the gas mixture is treated with an adsorbent to hold back the mercaptans and similar compounds, and then with another adsorbent, namely with solid Hydroxide is brought into contact in order to bring the oxygen-containing gaseous hydrocarbons to the polymerization and to adsorb the polymerization products. This has the disadvantage that in particular the adsorbent in the second adsorption stage is difficult and expensive to clean, if at all, because of the contamination with the polymerization products. It is also known from German patent specification 851106 that sulfur compounds can be removed from gas mixtures by adsorption on activated carbon, but the other interfering products cannot be eliminated. The known chemical reaction methods, e.g. B. those in which the gas stream is brought into contact with monoethanolamine or diethanolamine as absorbent, do not lead to fully satisfactory results, quite apart from the fact that the absorbent is expensive and the necessary equipment is associated with high operating costs.

In addition, many of the known absorption methods use a considerable amount of the hydrocarbons absorbed by the plant itself are lost during the regeneration of the absorption liquid. Unless the crowd of absorbed hydrocarbons is not so great that such a process This alone is economical, is caused by these hydrocarbons In any case, the hydrogen sulfide removed from the gas contaminates, so that this must first be subjected to further treatment before it can be used to produce elemental sulfur can be used, which is also uneconomical.

The invention is based on the object described above Fix cons.

This object is achieved by means of a work-up process of natural gas of the type mentioned above by means of adsorption and absorption, wherein the acidic gas components are removed, which is characterized according to the invention is that the natural gas in a first process stage of an adsorption treatment is subjected to the heavy hydrocarbons by adsorption on adsorbents adsorbed in the cold and removed from the adsorbent by means of hot regeneration gas are released again, in a second process stage that of the proportion of heavy hydrocarbons freed residual natural gas from the adsorption of an absorption treatment is supplied, in which by bringing it into contact with an absorption liquid the acidic constituents are absorbed and, if desired, by heating from the absorption liquid to be released again, and then from the absorption one of serious Hydrocarbons and acidic gas components freed from light hydrocarbons existing residual gas flow is withdrawn, which optionally with a partial flow of the heavy hydrocarbon gas released from adsorption is combined to form a product gas stream.

It can be used advantageously as that used in the first stage of the process Regeneration gas, the residual natural gas flowing off from the adsorption or even that from the absorption, consisting only of light hydrocarbons Use restgs.

As an adsorbent in the first process stage, with which the Propane and other heavy hydrocarbons from natural gas, e.g. B. natural gas, can be eliminated in the method according to the invention, for example, active ones Clay, silica gel or activated carbon and especially under the technical term »Sovabeads« known desiccants, which are chemically inert, solid material Base of silicon compounds in the form of pearl-like molded bodies more uniform Size is about a bulk weight of 22.7 kg per 28.317 liters, a specific one Heat of 0.25 and an average diameter of the individual pearl particles 0.35 cm.

As the absorption liquid used in the second process stage can expediently aliphatic alcohols, ethers or esters in the invention Use this method as this has a considerable absorptive capacity for the acidic Have gas components in natural gases. So far, such absorbents could They cannot be used for this purpose because they also have a considerable absorption capacity for propane and other heavy components of natural gas. Only with the invention Process in which these components can be removed prior to absorption the most economical absorbent liquids used for the acidic gas components without these in turn being contaminated or without the desired ones heavy hydrocarbon components of natural gas are lost.

The inventive method has the particular advantage that the work-up of a gas stream depending on the requirements for the following Use of the gas can be adjusted. For example, if a certain heating or a certain calorific value of the gas flow to be processed is required, the regeneration gas can be controlled so that sufficient amounts of propane or other hydrocarbons remain in the regeneration gas. In addition, can the composition of the heavy hydrocarbons through the choice of adsorbents and by construction details of the plant in which the process is carried out will control. No heavy hydrocarbons are lost, and both those obtained hydrocarbons on the one hand as well as the separated acidic components, especially the hydrogen sulfide, fall free of impurities at, and the hydrogen sulfide can be readily converted into pure by known methods Sulfur are implemented.

An example embodiment of the method according to the invention will be explained in more detail below with reference to the accompanying schematic drawing described.

In the method illustrated, the natural gas stream to be processed, which contains some acidic gas components and some gaseous hydrocarbons such as methane, ethane, propane, butane, as well as pentanes and heavy hydrocarbons, is passed through line 1 via one of the valves 2 or 3 into one of the adsorption towers 4 or 5 initiated. In the towers 4 and 5 there is the adsorption medium, on which the propanes and other heavier hydrocarbons and any water vapor contained in the gas stream are adsorbed. The gas freed from the heavy hydrocarbons is discharged from the adsorption tower 4 or 5 through the outlet valves 6 and 7 and flows through the inlet 9 below into the contact tower 8 , in which it passes through a number of stages, not shown, in which it is brought into contact with the liquid absorbent flows upward. Any known constructions, such as, for. B. bubble caps, bubble plates or packs can be used. The absorbent liquid is fed through an upper absorbent inlet 10 and through a middle absorbent inlet 11 to the contact tower 8, flows in countercurrent to the gas stream to be processed and is discharged again through the liquid outlet 15 via a valve 16 and fed to an expansion separator 17 , while the Treatment gas is passed out at the top of the contact tower 8 through a gas outlet 12 and via a pressure reducing valve 113 into an outlet line 14 . The gas discharged into the outlet line 14 is freed from heavy hydrocarbons and acidic gas components or contains only a negligibly small amount of acidic gas components and represents the residual gas stream consisting of light hydrocarbons which is withdrawn. The valve 16 is set by a liquid level controller 18.

The heavy hydrocarbons adsorbed in the first process stage are released by regeneration of the adsorbent present in tower 4 or 5. For this purpose, regeneration gas, which can consist of residual gas removed from the gas outlet 12 of the contact tower 8 at a point in front of the Druckminderventi113, is passed through a heater 37 and a valve 38 or 39 into the tower 4 or 5 after the valves 2 or 3 have been set in the locked position. When the hot regeneration gas is passed through the tower 4 or 5, the heavy hydrocarbons previously adsorbed therein are evaporated and flow together with the regeneration gas through the tower and are passed through the valve 42 or 40 into the line 41 , through which they are via a The cooler 43 enters the separator 44 . In the separator 44 the heavy hydrocarbons are separated from the regeneration gas and discharged via a liquid outlet 45 and fed into a storage device (not shown) for storage or for direct further processing. If it is desired that the heavier hydrocarbons remain in the processed gas stream and only the acidic gas components are removed from this, the cooling capacity of the cooler 43 is adjusted accordingly and, if necessary, the separator 44 is omitted entirely, and the regeneration gas is fed directly from the cooler 43 into the Line 14 and the residual gas contained therein. In this way, all originally separated hydrocarbons are added back to the natural gas after the acidic components have been removed. The regeneration gas leaves the separator 44 through an outlet 46 and flows back into the line 14 at a point below the pressure reducing valve 13.

Depending on the temperature at which the regeneration gas flowing into the separator 44 is kept, its composition and thus the calorific value of the product gas flow leaving the system can be controlled in the desired manner. The temperature can be set by appropriate control of the cooler 43 or by installing a bypass line (not shown). In addition, the composition of the hydrocarbons obtained from the first process stage can be controlled by the selection of the adsorbents and the design of the adsorption device.

The heating of the regeneration gas takes place in the heater 37 or can take place in that the regeneration gas is passed through the heater bypass line 47 , valves 48 and 49 being provided for controlling the regeneration gas flow.

If it is desired that the gas for the regeneration of the adsorbents in the towers 4 or 5 is taken from the inlet 9 , the pressure reducing valve 13 can be arranged in the inlet line 9 instead of in the outlet line 14.

The absorption medium, which is loaded with the acidic constituents and carried into the expansion separator 17 , is evaporated as a result of the low pressure prevailing there, and the vapors escaping from the liquid are discharged through the vapor outlet 19 and by means of a pump 20 through a line 21 back into the lower area of the Contact tower 8 promoted. These vapors consist essentially only of methane and ethane with small amounts of acidic gas components. The liquid flowing out through the liquid outlet 22 of the separator 17 passes through a valve 23 via a heat exchanger 24 into an expansion separator 25, in which a substantial amount of the gas constituents absorbed in the liquid absorbent evaporates. These vapors leave the separator through the vapor outlet 27, while the liquid absorbent, which is essentially free of acidic gas components, emerges from the liquid outlet 28 and can be pumped at least partially back into the contact tower 8 by means of a pump 29 through the central liquid inlet 11.

The remaining part of the liquid absorbent passes through a heat exchanger 30 and a heater 31 in the upper area of a rectification vessel in the form of a container for gas-liquid contact 32. Through the line 31a , this rectification vessel is a treatment gas for removing hydrogen sulfide, which is predominantly consists of methane, ethane, or is only natural gas containing hydrocarbons, and which is taken from the heater 31, is supplied. Within the rectification vessel 32 , this warm treatment gas is brought into contact in countercurrent with the heated, partially regenerated liquid absorbent. The regenerated liquid absorbent leaves the rectification vessel through the liquid outlet 33 and is passed by means of a pump 34 through the heat exchanger 30 and the heat exchanger 24 or the auxiliary service 35 equipped with the valve 36 through the upper inlet 10 into the contact tower 8 . The treatment gas leaves the rectifying vessel 32 through the gas outlet 32 a together with the acidic gas components which have been removed from the liquid absorbent within the rectifying vessel.

The valve 23 is set by a liquid level control 26.

Claims (3)

Claims: 1. Process for processing natural gas by means of Adsorption and absorption, whereby the acidic gas components are removed, d a -characterized in that the natural gas in a first process stage of an adsorption treatment is subjected, the heavy hydrocarbons by adsorption on adsorbents, such as activated carbon, activated alumina or silica gel, adsorbed in the cold and means hot regeneration gas can be released again from the adsorbent, in a second process stage that of the proportion of heavy hydrocarbons Released residual natural gas from the adsorption is fed to an absorption treatment is, in which by bringing into contact with an absorption liquid such as aliphatic alcohols, ethers or esters, the acidic constituents and absorbed if desired, released again from the absorption liquid by heating and then from absorption one of heavy hydrocarbons and acidic gas components, consisting of light hydrocarbons Residual gas stream is withdrawn, optionally with a partial stream of the heavy Hydrocarbons existing gas that has been released from adsorption is combined to form a product gas stream. 2. The method according to claim 1, characterized characterized in that as the regeneration gas used in the first process stage the residual natural gas flowing off from the adsorption is used. 3. The method according to claim 1, characterized in that it is used as that in the first process stage Regeneration gas is the one flowing out of the absorption, made up only of light hydrocarbons existing residual gas is used.