DE102015009818A1 - Process and apparatus for regenerating the detergent in a physical gas scrubber - Google Patents

Abstract

The invention relates to a method and a device for gas scrubbing, wherein at least one substance is scrubbed out of a gas mixture (1) guided in countercurrent to physically active detergent (4, 5), so that a detergent (13) is charged with the at least one scrubbed substance ), which is regenerated (R) and reused as detergent (4) in the scrubbing, wherein the at least one scrubbing substance in the loaded detergent (11) has a crystallization temperature which is higher than the crystallization temperature of the detergent. The invention is characterized in that at least part of the detergent (13) loaded with the at least one substance is cooled to below the crystallization temperature of the at least one washed-out substance (E1, E2), so that at least a subset of the at least one washed-out substance Solid is present, which is separated from the liquid detergent.

Description

The invention relates to a method for gas scrubbing in which at least one substance is scrubbed out of a gas mixture conducted in countercurrent to physically active detergent so that a detergent laden with the at least one scrubbed substance is produced, which is regenerated and reused as scrubbing agent in the gas scrubber wherein the at least one leached substance in the loaded detergent has a crystallization temperature which is higher than the crystallization temperature of the detergent.

Moreover, the invention relates to a device for carrying out the method according to the invention.

The crystallization temperature of a substance present in a substance mixture is to be understood as meaning the temperature below which the formation of crystals, which consist predominantly of this substance, begins.

Physical gas scrubbing utilizes the property of liquids to absorb gaseous substances differently well to separate gas mixtures. The liquids used as detergents are loaded with separated substances which are kept in solution without chemical bonding.

How well a gas is absorbed by a liquid can be expressed by the solubility coefficient: the better the gas dissolves in the liquid, the greater its solubility coefficient. The solubility coefficient is temperature dependent and generally increases with decreasing temperature. If the solubility coefficients of the components of a gas mixture are sufficiently different, the components having the greater solubility coefficients are predominantly washed out during physical gas scrubbing, while the gas components with the smaller solubility coefficients predominantly remain in the gas phase.

The scrubbed from the gas mixture gas components are removed after the gas scrubbing from the loaded detergent, whereby the detergent is regenerated. The regenerated detergent is normally reused in gas scrubbing while the scrubbed gas components are either disposed of or recycled for commercial use.

For the purification of synthesis crude gases, which are produced on an industrial scale in gasification plants of coal and / or hydrocarbons, for example by reforming with steam or by partial oxidation and usually some undesirable components such as water, carbon dioxide (CO ₂ ), hydrogen sulfide (H ₂ S ) and carbon dioxide sulfide (COS), preferably physical gas washes are used. These methods make sense, since today's synthesis gases are usually produced under high pressure and the effectiveness of physical gas scrubbers increases linearly with the operating pressure to a first approximation.

Of particular importance for the purification of synthesis gas is the methanol wash. It exploits the fact that the solubility coefficients of H ₂ S, COS and CO ₂ in liquid, cryogenic methanol differ by several orders of magnitude from those of hydrogen and carbon monoxide. Usually, the crude synthesis gas is washed at temperatures of about -60 ° C and pressures between 30 and 80 bar. In order to separate the substances absorbed in this case and to regenerate the detergent, methanol is expanded to a pressure which is typically in the range of 2 bar. The regenerated detergent is then pumped back to a pressure between 30 and 80 bar and used again for the scrubbing of synthesis gas. Also, the gas fractions separated during regeneration accumulate at the low pressure level and must be compressed to allow their release as a product. The cost of the necessary pressure increases have a negative impact on the economics of physical gas scrubbing, especially methanol scrubbing from.

Object of the present invention is therefore to provide a method and an apparatus of the type described above, through which the described disadvantages of the prior art are overcome.

This object is achieved procedurally according to the invention in that at least a portion of the laden with the at least one detergent detergent is cooled to below the crystallization temperature of the at least one washed out substance, so that at least a subset of at least one washed out substance is present as a solid consisting of the liquid Detergent is separated.

By means of the method according to the invention, it is possible to separate at least a subset of the washed-out substance from the loaded detergent, without a reduction in the detergent pressure being required for this purpose. Although in carrying out the process unavoidable pressure losses will result, however, by an appropriate design of the device used to carry out the method as desired so that both the detergent and the separated fabric after the separation step are at a pressure substantially equal to the pressure of the loaded detergent before the separation step. If, before the separation step according to the invention, a relaxation of the loaded detergent is dispensed with, both the detergent and the separated substance can be obtained with a pressure which is substantially equal to the pressure prevailing in the gas scrubbing.

The separation of the resulting from the cooling of the invention solids from the liquid detergent can be done in several ways. For example, the solid / liquid mixture formed during the cooling can be passed through a filter whose pores are sufficiently small to be able to retain solids. It is also conceivable to separate the solids by means of gravity and / or centrifugal force, for which purpose the solid / liquid mixture is passed through a gravity separator, a centrifuge or a cyclone. It is also possible to bring the loaded detergent with a cold surface in contact, through which the detergent is cooled, and adhere to the solids formed upon cooling. It may also be useful to apply two or more of the proposed methods in succession.

A preferred variant of the method according to the invention provides to carry the loaded detergent through a heat exchanger and thereby cool by indirect heat exchange via a cooling medium to below the crystallization temperature of the at least one leached substance. In this case, solids are formed predominantly in the immediate vicinity of the heat exchanger surfaces, where they grow up to a solid layer and are thus held. The growing solid layer leads to a narrowing of the flow cross-section in the heat exchanger and thus to an increasing pressure loss over time via the heat exchanger. In addition, the solid layer also hinders the heat transfer between the cooling medium and loaded detergent. It is therefore proposed to interrupt the flow of the loaded detergent through the heat exchanger as soon as the pressure drop across the heat exchanger exceeds a predetermined limit, and by a second, preferably with the first identical, but redirect from solid deposits heat exchanger, then on the inventive Cooling takes place. While the loaded detergent is cooled by the second heat exchanger, the first heat exchanger is heated to the extent that the solid layer adhering to its surfaces evaporates, so that a gas stream can be obtained at a pressure which largely corresponds to the pressure prevailing during gas scrubbing pressure.

In order to avoid interrupting the flow of detergent or pressure peaks during switching between the heat exchangers, the flow through the first heat exchanger restricted by the solids layer can be steadily reduced while at the same time the flow through the second heat exchanger is increased accordingly.

The total or a partial amount of the detergent treated according to the invention is subsequently used directly, ie without further modification of the composition, again for gas scrubbing, preferably directly. If the substance (s) dissolved in the loaded detergent can not be completely removed by the process according to the invention, it is provided to use the still partially loaded detergent as so-called semilean at a suitable point in the gas scrubbing, as described, for example, in the patent application DE 10 2007 051 181 is known. Only the non-Semilean used part of the inventively treated detergent is then subjected to one or more further regeneration steps to obtain fully regenerated detergent.

The inventive method is suitable for the separation of various substances from different physical detergents. With particular preference, however, it can be used to separate at least carbon dioxide with the aid of methanol by gas scrubbing from synthesis crude. Under the pressure prevailing in the laundry printing, which, as indicated above, typically between 30 and 80 bar, the crystallization temperature of carbon dioxide is about -60 to -95 ° C, while methanol freezes only at about -98 ° C. It is thus possible to cool the methanol loaded with carbon dioxide in the gas scrubbing to below the crystallization temperature of the dissolved carbon dioxide and thus to obtain at least part of the carbon dioxide in solid form, without solidifying the methanol.

Furthermore, the invention relates to a device for gas scrubbing, with a washing device through which a physically acting detergent in countercurrent to a gas mixture is feasible, as well as standing in fluid communication with the washing means in which in the washing device with at least one leached from the gas mixture loaded detergent for regeneration initiated and can be recycled from the regenerated detergent in the washing device.

The stated object is achieved on the device side according to the invention in that the regeneration device comprises a separating device in which at least part of the detergent laden with the at least one washed substance is cooled below the crystallization temperature of the at least one washed-out substance and solids formed are separated from the loaded detergent can.

For separation of solids formed on cooling, the separator may for example comprise a filter whose pores are sufficiently small to retain solids. Other variants, however, provide a gravity separator, such as a settling tank, or a cyclone or centrifuge, over which solids contained in the detergent can be separated by the action of gravity or centrifugal force. In a further variant of the device according to the invention, the separating device has a cold surface which can be brought into contact with the detergent to be cooled, in order to cool it, and freeze on the formed solids and thus be separated from the detergent. It is also possible to carry out the separating device with two or more of the proposed separating means, which are then preferably arranged serially.

A preferred embodiment of the device according to the invention provides that the separating device has at least two heat exchangers arranged in parallel, via which the loaded detergent can be cooled below the crystallization temperature of the at least one washed-out substance. Valves arranged in the flow path of the detergent make it possible to separate each of the at least two heat exchangers completely from the detergent stream, independently of the one or other heat exchangers, while at the same time at least one heat exchanger with detergent remains permeable at all times. Each of the heat exchangers is expediently designed with a heating device, by means of which its temperature can be raised above the crystallization temperature of the at least one washed-out substance independently of the temperature or temperatures of the other heat exchangers. Furthermore, each of the heat exchangers is connected to a discharge device, can be withdrawn from the heat exchanger via the transition at a temperature increase in the gas phase substances.

The separating device is preferably in fluid communication with the washing device such that at least part of the detergent treated in the separating device can be returned directly to the washing device as a washing agent. Furthermore, the separating device can be fluidly connected to other parts of the regenerating device in order to be able to subject at least one further regeneration step to detergent treated in the separating device.

In the following, the invention is based on a in the 1 schematically illustrated embodiment.

The 1 shows a gas scrubber in which carbon dioxide and sulfur components are selectively separated by washing with cryogenic liquid methanol in two washing steps from a synonymous for the most part of hydrogen and carbon monoxide synthesis gas.

Via wire 1 the synthesis gas to be treated is introduced at a pressure between 30 and 80 bar in the executed as a column washing device W, in which, separated by the fireplace floor K from each other, the two washing sections S1 and S2 are arranged one above the other. The synthesis raw gas flows upwards in the first washing section S1, being brought into intensive contact with methanol used from top to bottom, acting as a physically acting detergent, and freed from sulfur components. For the detergent, at the top of the washing section S1 via line 2 in an amount adapted to the solubility coefficient of the sulfur components, it is a part of the methanol scrubbing agent loaded with carbon dioxide in the second washing section S2 but free of sulfur components, which is passed via line 3 is deducted from the fireplace floor K.

The cleaned of sulfur components, but still containing carbon dioxide gas mixture flows through the chimney tray K in the second washing section S2, in which it continues upwards and thereby with countercurrently directed physically acting detergent 4 and 5 washed and freed from carbon dioxide. Via wire 6 the purified gas mixture is withdrawn as synthesis gas from the head of the washing device W and a recovery (not shown) supplied.

From the bottom of the washer W is loaded with sulfur components and carbon dioxide methanol 7 discharged, expanded via the throttle body a to a pressure between 15 and 25 bar, passed into the separator D1 and there separated into a gas and a liquid phase. The gas phase, which consists mainly of co-absorbed in the gas scrubbing hydrogen and carbon monoxide, is via line 8th withdrawn from the separator D1 and via line 9 returned to the washing device W. The liquid phase 10 is introduced into the regenerator R, from the complete regenerated, largely free from both sulfur components and carbon dioxide methanol 19 withdrawn at a pressure of typically 1 and 3 bar and via the pump P1 as a detergent 5 is returned to the head of the wash column W.

The second part of the loaded with carbon dioxide, sulfur components free methanol detergent 3 , which is not needed as a detergent in the first washing section S1, is via line 11 and relaxed via the throttle body c to an intermediate pressure in the separator D2. The gas phase formed during the relaxation, which consists predominantly of co-absorbed in the gas scrubbing hydrogen and carbon monoxide, is transferred via line 12 withdrawn from the separator and just like the gas phase 8th via wire 9 forwarded. Via wire 13 the liquid phase is withdrawn from the separator D2 and forwarded to the separating device T belonging to the regenerating device R, in order to separate off carbon dioxide from the methanol washing agent.

The separator T comprises a first E1 and a second recuperative heat exchanger E2, both independently of each other via external cooling 14 and 15 can be cooled. The total amount of carbon dioxide loaded methanol 13 is passed through the first heat exchanger E1 and thereby cooled to a temperature between -75 and -95 ° C. At this temperature, the carbon dioxide dissolved in the methanol freezes and deposits as a solid layer on the exchange surfaces, so that the free flow cross section through the heat exchanger E1 continuously lower and the pressure loss is higher. Since the solid layer acts as a thermal insulator and therefore decreases the effectiveness of the cooling over time, the current 13 of the loaded methanol is interrupted by the heat exchanger E1 and passed through the second heat exchanger E2, as soon as the pressure loss exceeds a specified limit. As soon as he gets from the methanol stream 13 is isolated, the heat exchanger E1 is warmed up to above the crystallization temperature of the carbon dioxide, so that carbon dioxide passes into the gas phase and via line 16 is withdrawn at a pressure which is practically equal to the pressure of the loaded methanol 13 is. If the solid layer has evaporated from the exchange surfaces of the heat exchanger E1 and the pressure loss via the heat exchanger E2 has risen to the predetermined limit, the roles of the two heat exchangers E1 and E2 are reversed, so that the loaded methanol stream 13 is cooled again via the heat exchanger E1, while the heat exchanger E2 is heated to remove the solid layer formed and gaseous carbon dioxide 17 to obtain.

In the separation device T is only a part of the loaded methanol 13 contained carbon dioxide, so that a partially loaded methanol 18 the separator T leaves. As the pressure of the partially loaded methanol 18 largely the pressure of the loaded methanol 13 corresponds, it can be returned with comparatively low pump power through the pump P and via line 4 the washing device W are supplied at a suitable location as a detergent.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102007051181 [0015]

Claims (9)

Process for gas scrubbing, in which a countercurrent to physically active detergent ( 4 . 5 ) guided gas mixture ( 1 ) at least one substance is washed out so that a detergent loaded with the at least one washed-out substance ( 13 ), which regenerates (R) and again as a detergent ( 4 ) is used in the gas scrubbing, wherein the at least one washed-out substance in the loaded detergent ( 11 ) has a crystallization temperature which is higher than the crystallization temperature of the detergent, characterized in that at least a part of the laundry detergent loaded with the at least one material ( 13 ) is cooled to below the crystallization temperature of the at least one leached substance (E1, E2), so that at least a portion of the at least one leached substance is present as a solid which is separated from the liquid detergent. A method according to claim 1, characterized in that in the cooling (E1, E2) resulting solids via a filter and / or a gravity separator and / or a centrifuge and / or a cyclone and / or a cold surface is separated from the liquid detergent. Method according to one of claims 1 or 2, characterized in that the loaded with the at least one leached fabric detergent ( 13 ) alternately passed through at least two heat exchangers (E1, E2) and thereby cooled. Method according to one of claims 1 to 3, characterized in that at least a part of the detergent ( 18 ) after separation of solids formed on cooling directly as detergent ( 4 ) is used in the gas scrubber (W). Method according to one of claims 1 to 4, characterized in that it is in the gas mixture ( 1 ) is synthesis gas from which at least carbon dioxide with the aid of methanol ( 4 . 5 ) is washed out. Apparatus for washing gas, having a washing device (W) through which a physically acting detergent ( 4 . 5 ) in countercurrent to a gas mixture ( 1 ) and a regenerating device (R) in fluid communication with the washing device (W), into which in the washing device (W) at least one of the gas mixture ( 1 ) Washed-out substance loaded laundry detergent ( 10 . 13 ) for regeneration and from the regenerated detergent ( 5 ) can be returned to the washing device (W), characterized in that the regenerating device (R) comprises a separating device (T), in which at least one part ( 13 ) of the detergent loaded with the at least one washed-out substance is cooled below the crystallization temperature of the at least one washed-out substance, and solids formed thereby from the loaded detergent ( 13 ) can be separated. Apparatus according to claim 6, characterized in that the separating device (T) has a filter and / or a gravity separator and / or a centrifuge and / or a cyclone and / or a cold surface in order to cool with the at least one leached substance separated laden detergent to separate. Device according to one of claims 6 or 7, characterized in that the separating device (T) comprises at least two mutually parallel heat exchangers (E1, E2), Device according to one of claims 6 to 8, characterized in that the separating device (T) is so fluidly connected to the washing device, that at least a part of the in the separating device (T) treated detergent ( 18 ) directly as a detergent ( 4 ) can be returned to the washing device (W).

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