This is a Non-Provisional of U.S. Provisional Patent Application No. 61/390,399 filed Oct. 6, 2010, entitled CARBON DIOXIDE REMOVAL PROCESS.
The present invention relates to a process for efficiently removing carbon dioxide from a hydrocarbon containing feed stream utilizing a membrane separation unit in conjunction with a heat exchanger and a carbon dioxide separation unit wherein the streams obtained in the carbon dioxide separation unit are utilized to provide the cooling effect in the heat exchanger.
Membranes have been used to remove carbon dioxide and other acid/polar gases from natural gas. Membrane processes have been used to serve as a bulk cut separation of carbon dioxide. In such processes the carbon dioxide permeates through the membrane thereby giving rise to a carbon dioxide enriched permeate gas which is vented at low pressure and a hydrocarbon (HC) enriched product gas at high pressure. In addition, there are a variety of carbon dioxide removal processes utilizing two membranes stages. U.S. Pat. No. 4,130,403 provides a method for removing hydrogen sulfide and carbon dioxide from a natural gas by using acid-gas selective membranes. This two-stage process is taught for reducing HC losses. The rich carbon dioxide stream produced may be used in flooding processes for enhanced oil recovery. This staged permeate process is illustrated in
Additional patents have disclosed the cryo-separation of carbon dioxide from hydrocarbons. In these cases, the membrane is used to increase the efficiency of the main cryogenic separation process. For this processing, all the feed gas has to be cooled to the cryo temperature. Two examples of these schemes are provided in French Patent Application 2917982 and U.S. Pat. No. 4,936,887. French Patent Application 2917982 provides for pretreating natural gas (I) having hydrocarbon, hydrogen sulfide and water that comprises (a) cooling (I) and introducing the cooled natural gas to a separation device (B1) to separate a liquid aqueous phase from (I); (b) contacting (I) with a liquid (11) rich in hydrogen sulfide to obtain a gas (6) that is free of water and an effluent liquid (4); (c) separating the gas, obtained in step (b), to obtain a permeate (8) rich in hydrogen sulfide and a retentate (7) free of hydrogen sulfide; and (d) partially condensing the permeate by cooling to obtain a liquid (10) rich in hydrogen sulfide, and a gas (12) that is free of hydrogen sulfide. Pretreating natural gas (I) having hydrocarbon, hydrogen sulfide and water, comprises (a) cooling (I) and introducing the cooled natural gas to a separation device (B1) to separate a liquid aqueous phase from (I); (b) contacting (I) with a liquid (11) rich in hydrogen sulfide, obtained in step (d), to obtain a gas (6) that is free of water and an effluent liquid (4) rich in water and hydrogen sulfide; (c) separating the gas, obtained in step (b), through a membrane (M) to obtain a permeate (8) rich in hydrogen sulfide and a retentate (7) free of hydrogen sulfide; and (d) partially condensing the permeate by cooling to obtain a liquid (10) rich in hydrogen sulfide, which is recycled to step (b), and a gas (12) that is free of hydrogen sulfide.
U.S. Pat. No. 4,936,887 provides a membrane separation incorporated into a distillation cycle for efficient recovery of carbon dioxide from a stream containing natural gas along with carbon dioxide. Methane and carbon dioxide are separated from a feed stream in a first distillation to produce a process stream containing essentially methane and carbon dioxide and which is substantially free to ethane and higher molecular weight hydrocarbons. The process stream consisting essentially of methane and carbon dioxide is subjected to further distillation to produce a carbon dioxide-rich product stream and a process stream enriched in methane. The methane-enriched process stream is then passed to a membrane separation unit for separating methane and carbon dioxide and for producing a high purity methane product stream.
U.S. Pat. No. 5,647,227 teaches a membrane separation process combined with a cryogenic separation process for treating a gas stream containing methane, nitrogen and at least one other component. The membrane separation process works by preferentially permeating methane and the other component and rejecting nitrogen. The process is particularly useful in removing components such as water, carbon dioxide or C3+ hydrocarbons that might otherwise freeze and plug the cryogenic equipment. In this scheme, the residue stream from the membrane is sent on to the cryogenic separator.
When the carbon dioxide permeate from the first membrane stage contains high hydrocarbon concentrations, these losses can be reduced by re-pressurizing the carbon dioxide permeate and feeding this repressurized carbon dioxide permeate to a second membrane stage. The carbon dioxide permeate from the second membrane stage is vented while the recovered hydrocarbon residue stream is often recycled to be added back to the original hydrocarbon feed methane containing feed gas. These two membrane stage processes have become increasingly important with regarding to the increasing value of the hydrocarbons. However, while the hydrocarbon losses are decreased by using such processes, there is an increase in the separation process costs. Furthermore, the carbon dioxide that is vented in such processes is typically obtained at low pressures so that additional high costs are incurred when the desire is to sequester the carbon dioxide or use it in enhanced oil recovery applications.
U.S. Pat. No. 4,639,257 discloses recovery of carbon dioxide from a gas mixture using a combination of membrane separation and distillation. The process teaches two embodiments. With regard to the preferred embodiment, the membrane separation preferably employs at least two stages with intermediate recompression. The final CO2 concentrated permeate is subjected to distillation to produce liquid CO2 with the required cooling provided by a separate vapor compression refrigeration unit. The process scheme is not integrated in terms of energy requirements making this uneconomical. In the second embodiment, membrane separation is only utilized on the overhead stream from the distillation column.
Accordingly, there is a need to provide a process which not only minimizes the loss of hydrocarbons but also allows for the efficient recovery of the carbon dioxide at high pressure.
The present invention provides a process for treating a hydrocarbon containing feed stream which minimizes the loss of hydrocarbons while at the same time allowing for the recovery of a high pressure carbon dioxide stream. The process involves utilizing a membrane separation unit in conjunction with a heat exchanger and a carbon dioxide separation unit. The various streams (carbon dioxide rich liquid stream and carbon dioxide lean overhead stream) isolated in the carbon dioxide separation unit are then used to provide the cooling effect in the heat exchanger and as fuel for the compressors utilized in the process.
By utilizing the process of the present invention, it is possible to minimize the hydrocarbon loss in the production of carbon dioxide, produce a carbon dioxide stream that is at a higher pressure than achieved when a membrane vent is utilized thereby enabling a more cost effective means of sequestration of carbon dioxide, provide a lower capital investment for recovering the carbon dioxide, and a lower operating cost for permeate compression compared to prior art two-stage membrane productions. Accordingly, the process of the present invention allows for recovery of carbon dioxide from a hydrocarbon feed stream in a cost effective and efficient manner.
The overall process of the present invention involves passing a hydrocarbon containing feed stream through a membrane separation unit that uses a carbon dioxide selective membrane, compressing the carbon dioxide rich permeate stream obtained and then cooling this stream using a heat exchanger, further isolating the carbon dioxide in a carbon dioxide separation unit to obtain a carbon dioxide rich liquid stream and a carbon dioxide lean overhead stream and then using each of these streams to provide the cooling effect in the heat exchanger. By utilizing this process, it is possible to recover/recuperate the heat often wasted in such processes and utilize this heat to promote the functioning of the heat exchanger.
The present process will be further described with reference to
The second embodiment of the present invention, as set forth in
With regard to each of the above embodiments and alternatives, each of these embodiments and alternatives may include a variety of different carbon dioxide separations units. More specifically, the carbon dioxide separation units for each of the above embodiments and alternatives may be selected from carbon dioxide separation units that comprise: 1) one or more flash drums operated at gradually decreasing pressures/temperatures (see
With regard to the first embodiment of the present process, as depicted in
As used herein with regard to the present invention, the phrase “high pressure hydrocarbon containing feed stream” refers to a hydrocarbon containing feed stream that is at a pressure from about 125 psi to 1500 psi, preferably from about 150 psi to about 1400 psi. The pressure at which the hydrocarbon containing feed stream is introduced will often be determined by the process by which the hydrocarbon containing feed stream has already been subjected. More specifically, in certain instances such as geologic natural gas fields, the hydrocarbon containing feed stream will already be at high pressure. In those instances where the hydrocarbon containing feed stream is at less than what has been defined as “high pressure”, it is possible to further compress the hydrocarbon containing feed stream utilizing one or more compressors (not shown) such as those known in the art to reach the desired pressure level. Such compression can be carried out utilizing any compressor that is known in the art.
The next step of the process of the present invention involves introducing the high pressure hydrocarbon containing feed stream into the membrane separation unit 2. Depending upon the source 1 of the high pressure feed stream, prior to the introduction of such feed stream into the membrane separation unit 2, it is often desirable to remove condensibles from the feed stream by introducing the feed stream via line 3 into a dew point chiller 4. By optionally using such dew point chillers 4, it is possible to remove a portion of the heavy hydrocarbons via line 16 found in the high pressure hydrocarbon containing feed stream before the feed stream is treated in the membrane separation unit 2. This is often desirable as such isolated heavy hydrocarbons are considered to be valuable. Dew point chillers 4 such as those contemplated for use in the present process are known in the art and include propane chillers or cooling water for the condensation and removal of the higher hydrocarbons. Such dew point chillers 4 typically operate around −30° C. The manner in which the dew point chillers 4 is operated are known to those skilled in the art.
Alternatively, a temperature swing adsorption (TSA) unit or a pressure swing adsorption (PSA) unit may be used to remove the condensibles from the feed stream.
Depending upon the degree of cooling achieved by the dew point chillers 4, it may also be desirable to pre-heat the high pressure hydrocarbon containing feed stream that has been processed in the dew point chiller 4 in order to obtain the optimal temperature for introducing the feed stream into a membrane separation unit 2. The optimal temperature for introducing the high pressure hydrocarbon containing feed stream into the membrane separation unit 2 will depend upon the type of membrane in place but will be above the liquefaction temperature of carbon dioxide. Preferably the temperature will range from about −45° C. to about 50° C., more preferably from about −30° C. to about 50° C. While lower temperatures are possible, in such cases there is a risk of having a high pressure hydrocarbon containing feed stream that includes condensate. Those of ordinary skill in the art will recognize that high pressure hydrocarbon containing feed streams including high levels of condensate may cause problems in a membrane separation unit 2. Accordingly, in addition to the dew point chiller 4, it may also be desirable to further treat the high pressure hydrocarbon containing feed stream by preheating the feed stream in a preheater 6 in order to achieve the about −45° C. to about 50° C. The high pressure hydrocarbon containing feed stream that was treated in the dew point chiller 4 is introduced into the preheater 6 via line 5. Such preheaters 6 and the conditions under which they are operated are known to those skilled in the art.
The membrane separation unit 2 utilized in the process of the present invention contains at least one membrane 7 that is selective for acid gases such as carbon dioxide and hydrogen sulfide over the other components in the hydrocarbon containing feed stream (the methane, higher hydrocarbons, nitrogen, etc.). The membrane is also selective for helium over the methane, higher hydrocarbons and nitrogen. With regard to each of the membranes 7 utilized in the present process, each membrane 7 has a permeate side 8 and a residue side 9. Since the membrane 7 is selective for acid gases such as carbon dioxide, it allows for the passing of carbon dioxide through the membrane 7 to the permeate side 8 of the membrane 7. While the membrane is selective for carbon dioxide, those skilled in the art will recognize that a minor portion of the other components in the high pressure hydrocarbon containing feed stream will also pass through the membrane 7 to become a part of the permeate. Accordingly, with regard to the present process, the permeate stream that is obtained will generally contain from about 40% to about 90% carbon dioxide with the remaining part of the permeate stream comprising the other components contained in the high pressure hydrocarbon containing feed stream. As a result of passing the high pressure hydrocarbon containing feed steam into the membrane separation unit 2 via line 10 and through the membrane 7, this stream is separated into two streams—one which is considered to be carbon dioxide rich and one which is considered to be carbon dioxide lean. For purposes of the present process, the stream that results from the portion of the high pressure hydrocarbon containing feed steam that permeates the membrane 7 and thereby forms a permeate stream is referred to as the first membrane stream. The remaining components which do not permeate the membrane 7 and which are retained on the residue side 9 of the membrane 7 are referred to as the second membrane stream. Those skilled in the art will recognize that while the membrane is selective for carbon dioxide, that some of the carbon dioxide in the high pressure hydrocarbon containing feed stream will also be retained as a portion of the residue stream (in the second membrane stream).
While a variety of different types of membranes 7 may be utilized in the membrane separation unit 2 of the process of the present invention, the preferred membrane 7 is a polymer membrane that is selective for acid gases such as a carbon dioxide over hydrocarbons. Such carbon dioxide selective membranes 7 may be made of any number of polymers that are suitable as membrane materials. With regard to the membranes of the present invention, this includes substituted or unsubstituted polymers selected from polysiloxane, polycarbonates, silicone-containing polycarbonates, brominated polycarbonates, polysulfones, polyether sulfones, sulfonated polysulfones, sulfonated polyether sulfones, polyimides and aryl polyimides, polyether imides, polyketones, polyether ketones, polyamides including aryl polyamides, poly(esteramide-diisocyanate), polyamide/imides, polyolefins such as polyethylene, polypropylene, polybutylene, poly-4-methyl pentene, polyacetylenes, polytrimethysilylpropyne, fluorinated polymers such as those formed from tetrafluoroethylene and perfluorodioxoles, poly(styrenes), including styrene-containing copolymers such as acrylonitrile-styrene copolymers, styrene-butadiene copolymers and styrene-vinylbenzylhalide copolymers, cellulosic polymers, such as cellulose acetate-butyrate, cellulose propionate, ethyl cellulose, methyl cellulose, cellulose triacetate, and nitrocellulose, polyethers, poly(arylene oxides) such as poly(phenylene oxide) and poly(xylene oxide), polyurethanes, polyesters (including polyarylates), such as poly(ethylene terephthalate), and poly(phenylene terephthalate), poly(alkyl methacrylates), poly(acrylates), polysulfides, polyvinyls, e.g., poly(vinyl chloride), poly(vinyl fluoride), poly(vinylidene chloride), poly(vinylidene fluoride), poly(vinyl alcohol), poly(vinyl esters) such as poly(vinyl acetate) and poly(vinyl propionate), poly(vinyl pyridines), poly(vinyl pyrrolidones), poly(vinyl ketones), poly(vinyl ethers), poly(vinyl aldehydes) such as poly(vinyl formal) and poly(vinyl butyral), poly(vinyl amides), poly(vinyl amines), poly(vinyl urethanes), poly(vinyl ureas), poly(vinyl phosphates), and poly(vinyl sulfates), polyallyls, poly(benzobenzimidazole), polyhydrazides, polyoxadiazoles, polytriazoles: poly(benzimidazole), polycarbodiimides, polyphosphazines, and interpolymers, including block interpolymers containing repeating units from the above such as terpolymers of acrylonitrile-vinyl bromide-sodium salt of para-sulfophenylmethallyl ethers, and grafts and blends containing any of the foregoing. The polymer suitable for use is intended to also encompass copolymers of two or more monomers utilized to obtain any of the homopolymers or copolymers named above. Typical substituents providing substituted polymers include halogens such as fluorine, chlorine and bromine, hydroxyl groups, lower alkyl groups, lower alkoxy groups, monocyclic aryl, lower acyl groups and the like.
With regard to one embodiment of the present invention, the preferred polymers include, but are not limited to, polysiloxane, polycarbonates, silicone-containing polycarbonates, brominated polycarbonates, polysulfones, polyether sulfones, sulfonated polysulfones, sulfonated polyether sulfones, polyimides, polyetherimides, polyketones, polyether ketones, polyamides, polyamide/imides, polyolefins such as poly-4-methyl pentene, polyacetylenes such as polytrimethysilylpropyne, and fluoropolymers including fluorinated polymers and copolymers of fluorinated monomers such as fluorinated olefins and fluorodioxoles, and cellulosic polymers, such as cellulose diacetate and cellulose triacetate. An example of a preferred polyetherimide is Ultem 1000, P84 and P84-HT polymers, and Matrimid 5218.
Of the above noted polymeric membranes, the most preferred membranes 7 are those made of polyimides. More specifically, polyimides of the type disclosed in U.S. Pat. Nos. 7,018,445 and 7,025,804, each incorporated herein in their entirety by reference. With regard to these types of membranes, the process of the present invention preferably utilizes a membrane comprising a blend of at least one polymer of a Type 1 copolyimide and at least one polymer of a Type 2 copolyimide in which the Type 1 copolyimide comprises repeating units of formula I
in which R2 is a moiety having a composition selected from the group consisting of formula A, formula B, formula C and a mixture thereof,
Z is a moiety having a composition selected from the group consisting of formula L, formula M, formula N and a mixture thereof; and
R1 is a moiety having a composition selected from the group consisting of formula Q, formula S, formula T, and a mixture thereof,
in which the Type 2 copolyimide comprises the repeating units of formulas IIa and IIb
in which Ar is a moiety having a composition selected from the group consisting of formula U, formula V, and a mixture thereof,
in which
X, X1, X2, X3 independently are hydrogen or an alkyl group having 1 to 6 carbon atoms, provided that at least two of X, X1, X2, or X3 on each of U and V are an alkyl group,
Ar′ is any aromatic moiety,
Ra and Rb each independently have composition of formulas A, B, C, D or a mixture thereof, and
Z is a moiety having composition selected from the group consisting of formula L, formula M, formula N and a mixture thereof
The material of the membrane consists essentially of the blend of these copolyimides. Provided that they do not significantly adversely affect the separation performance of the membrane, other components can be present in the blend such as, processing aids, chemical and thermal stabilizers and the like.
In a preferred embodiment, the repeating units of the Type 1 copolyimide have the composition of formula Ia.
Wherein R1 is as defined hereinbefore. A preferred polymer of this composition in which it is understood that R1 is formula Q in about 16% of the repeating units, formula S in about 64% of the repeating units and formula T in about 20% of the repeating units is available from HP Polymer GmbH under the tradename P84
In another preferred embodiment, the Type 1 copolyimide comprises repeating units of formula Ib.
Wherein R1 is as defined hereinbefore. Preference is given to using the Type 1 copolyimide of formula Ib in which R1 is a composition of formula Q in about 1-99% of the repeating units, and of formula S in a complementary amount totaling 100% of the repeating units.
In yet another preferred embodiment, the Type 1 copolyimide is a copolymer comprising repeating units of both formula Ia and Ib in which units of formula Ib constitute about 1-99% of the total repeating units of formulas Ia and Ib. A polymer of this structure is available from HP Polymer GmbH under the tradename P84-HT325.
In the Type 2 polyimide, the repeating unit of formula IIa should be at least about 25%, and preferably at least about 50% of the total repeating units of formula IIa and formula IIb. Ar′ can be the same as or different from Ar.
The polyimides utilized to form the membranes of the present process will typically have a weight average molecular weight within the range of about 23,000 to about 400,000 and preferably about 50,000 to about 280,000.
The blend of Type 1 and Type II copolyimides should be uniform and can be formed from the component copolyimides in conventional ways. For example, the Type 1 and Type 2 copolyimides can be synthesized separately and melt compounded or mixed in solution by dissolving each copolyimide in one or more suitable solvents. If the blend is solvent mixed, the solution can be stored or used directly in subsequent membrane fabrication steps or the solvent can be removed to provide a solid blend for later use. If the blend is prepared by melt compounding, the resulting blend can be dissolved in a suitable solvent for subsequent membrane fabrication. Uniformity of the dry (i.e., solvent-free) blend either before or after membrane formation can be checked by detecting only a single compositional dependent glass transition temperature lying between the glass transition temperatures of the constituent components. Differential scanning calorimetry and dynamic mechanical analysis can be used to measure glass transition temperature.
Preferably, the blend is formed by dissolving the Type 1 and Type 2 copolyimides in separate solutions, combining the solutions and agitating the combined solutions to obtain a dissolved blend. Mild heating to temperatures in the range of about 50 to 100° C. can optionally be used to accelerate dissolution of the components. The polyimide blend is sufficiently soluble in solvents typically used for processing into suitable gas separation membranes. The ratio of Type 1 copolyimide to Type 2 copolyimide in the blend is preferably greater than about 0.2, and more preferably at least about 1.0.
The polyimides described herein are made by methods well known in the art. Type 1 polyimides can conveniently be made by polycondensation of an appropriate diisocyanate with approximately an equimolar amount of an appropriate dianhydride. Alternatively, Type 1 polyimides can be made by polycondensation of equimolar amounts of a dianhydride and a diamine to form a polyamic acid followed by chemical or thermal dehydration to form the polyimide. The diisocyanates, diamines and dianhydrides useful for making the Type 1 copolyimides of interest are usually available commercially. Type 2 polyimides are typically prepared by the dianhydride/diamine reaction process just mentioned because the diamines are more readily available than the corresponding diisocyanates.
The preferred Type 1 and Type 2 polyimides are soluble in a wide range of common organic solvents including most amide solvents, that are typically used for the formation of polymeric membranes, such as N-methyl pyrrolidone (“NMP”) and m-cresol. This is a great advantage for the ease of fabrication of industrially useful gas separation membranes.
The membranes 7 of the present invention can be fabricated into any membrane form by any appropriate conventional methods. To be economically practical, the separation membrane 7 usually comprises a very thin selective layer that forms part of a thicker structure. This may be, for example, an integral asymmetric membrane, comprising a dense skin region that forms the selective layer and a micro-porous support region. Such membranes 7 are described, for example, in U.S. Pat. No. 5,015,270 to Ekiner. As a further, and preferred, alternative, the membrane 7 may be a composite membrane 7, that is, a membrane 7 having multiple layers. Composite membranes 7 typically comprise a porous but non-selective support membrane 7, which provides mechanical strength, coated with a thin selective layer of another material that is primarily responsible for the separation properties. Typically, such a composite membrane 7 is made by solution-casting (or spinning in the case of hollow fibers) the support membrane 7, then solution-coating the selective layer in a separate step. Alternatively, hollow-fiber composite membranes 7 can be made by co-extrusion spinning of both the support material and the separating layer simultaneously as described in U.S. Pat. No. 5,085,676. The polyimide blends are utilized in the selectively permeable layer of the membrane 7 according to the present invention. The support layer of a composite membrane can be free of the copolyimide blend.
The membranes 7 of the invention can be fabricated into any membrane form by any appropriate conventional methods. For illustrative purposes, a method to prepare membranes in accordance with this invention is generally described as follows. Type 1 and Type 2 copolyimide compositions are selected and are combined in dry particulate form in a dry mix of desired proportion, e.g., 65% Type 1 and 35% Type 2. The solid polymer powder or flake is dissolved in a suitable solvent such as N-methylpyrrolidone at approximately 20-30% polymer content. The polymer blend solution is cast as a sheet at the desired thickness onto a flat support layer (for flat sheet membranes), or extruded through a conventional hollow fiber spinneret (for hollow fiber membranes). If a uniformly dense membrane is desired, the solvent is slowly removed by heating or other means of evaporation. If an asymmetric membrane is desired, the film or fiber structure is quenched in a liquid that is a non-solvent for the polymer and that is miscible with the solvent for the polyimide. Alternatively, if a composite membrane is desired, the polymer is cast or extruded over a porous support of another material in either flat film or hollow fiber form. The separating layer of the composite membrane can be a dense ultra-thin or asymmetric film.
The membrane separation unit 2 includes at least one of the above noted membranes 7. With regard to the actual configuration of the membrane separation unit 2, the membrane separation unit 2 can take on any number of configurations. In one embodiment, there is only one membrane 7 element in the membrane separation unit 2. In an alternative embodiment, the membrane separation unit 2 comprises a series of membrane elements 7 within a single membrane housing (not shown). With regard to this embodiment, the series of membranes 7 can be made up of membranes 7 of the same type selected from the membranes 7 detailed above or of two or more different membranes 7 selected from the membranes 7 detailed above. In a still further embodiment concerning the configuration of the membrane separation unit 2, the membrane separation unit 2 comprises two or more membrane housings with each of the housings having one or more membranes 7 as described hereinbefore. More specifically, in this embodiment, there can be two or more membrane housings, with each of the housings having either one membrane 7 or two or more membranes 7 of the same type or two or more membranes 7 of two of more different types. The resulting membranes 7 may be mounted in any convenient type of housing or vessel adapted to provide a supply of the hydrocarbon containing feed stream, and removal of the permeate stream and residue stream. The housing also provides a high-pressure side (for the hydrocarbon containing feed stream and the residue stream) and a low-pressure side of the membrane (for the permeate stream). For example, flat-sheet membranes can be stacked in plate-and-frame modules or wound in spiral-wound modules. Hollow-fiber membranes 7 are typically potted with a thermoset resin in cylindrical housings. The final membrane separation unit 2 comprises one or more membrane modules or housings, which may be housed individually in pressure vessels or multiple elements may be mounted together in a sealed housing of appropriate diameter and length.
As a result of treating the high pressure hydrocarbon containing feed stream in the membrane separation unit 2, two membrane streams result—a first membrane stream which is at a lower pressure (the carbon dioxide rich permeate stream) and a second membrane stream which is still at high pressure (the carbon dioxide lean residue stream). Note that with regard to the present discussion, the term membrane 7 is used in the singular but in practice, since the membrane separation unit 2 may contain multiple membranes 7, more than one residue and permeate stream may be obtained and combined to form the streams that will be further directed as noted.
The next step in the process of the present invention is the withdrawal of the second membrane stream from the residue side 9 of the membrane 7 of the membrane separation unit 2. Note that since the membrane 7 is selective for carbon dioxide, the residue stream (second membrane steam) typically contains a higher concentration of the remaining components in the second membrane stream. Once this residue stream is withdrawn from the membrane separation unit via line 11A/11, it is then directed for further use as this stream is considered valuable due to the higher concentration of higher hydrocarbons. In one alternative of the present invention, the residue stream is withdrawn and directly used as product (not shown in
The first membrane stream is withdrawn from the permeate side 8 of the membrane 7 of the membrane separation unit 2 and directed along line 12 where it will eventually be subjected to carbon dioxide separation. As the permeate crosses the carbon dioxide selective membrane (or membranes) 7 a pressure drop in the permeate obtained from the high pressure hydrocarbon containing feed stream is observed. More specifically, when the hydrocarbon containing feed stream is introduced into the membrane separation unit 2, it is introduced at a pressure from about 125 psi to 1500 psi. When the first membrane stream is withdrawn from the permeate side 8 of the membrane 7, it is withdrawn at a pressure from about 5 psi to about 300 psi. Accordingly, the next step in the process involves compressing and cooling the first membrane stream. With regard to the compression, the compression may be carried out utilizing one or more compressors 13. The compressors may be multistage devices with intercooling by air or water between stages. Utilizing these one or more compressors 13, it is possible to compress the first membrane stream which will typically be at from about 5 psi to about 300 psi to a specific pressure range, more specifically, from about 50 psi to about 550 psi, preferably from about 75 psi to about 450 psi.
After the first membrane stream is compressed in compressor 13, it is then directed along line 14/14A to a heat exchanger 15 in order to be cooled to a temperature ranging from about 5° C. to about −57° C., preferably from about −20° C. to about −50° C. in order to form a compressed, cooled, two phase (liquid and gas) first membrane stream. As used herein with regard to the process of the present invention, the phrase “heat exchanger” refers to a heat exchanger block which may comprise one or more heat exchangers. Accordingly, the one or more heat exchangers 15 may be any heat exchangers 15 that are known in the art that are a multi-stream heat exchangers 15. In the process of the present invention, the heat exchanger block can comprise either one multi-stream heat exchanger 15 or two or more multi-stream heat exchangers 15 that are arranged and used in a series. Furthermore, as used herein, the phrase “multi-stream heat exchanger” refers to a heat exchanger 15 that has two or more zones which allow for the passage of various streams through the heat exchanger 15 (streams from different sources or the same source). With regard to the present multi-stream heat exchanger 15 to be used in the process of the present invention, while being able to have any number of heat exchanger zones, preferably the heat exchanger has 2 to 5 zones. The cooling may be performed by one or more multi-stream heat exchangers 15. The heat exchanger 15 may be any conventional heat exchanger 15, such as a plate fin, shell-in-tube, spiral wound, or brazed aluminum plate heat exchanger 15, or it may be a falling film evaporator as disclosed in EP Patent 1008826, a heat exchanger 15 derived from an automobile radiator as disclosed in pending U.S. Patent Application No. 2009/211733, or plate heat exchangers manufactured as disclosed in pending French Patent Application No. 2,930,464, French Patent Application No. 2,930,465 and French Patent Application No. 2,930,466, and combinations thereof. The noted patents regarding the heat exchangers 15 are all incorporated herein by reference in their entireties.
More specifically, the cooling of the first membrane stream within the heat exchanger 15 is accomplished through utilization of the latent heat of the carbon dioxide rich liquid stream, the sensible heat of the expansion of a portion of the carbon dioxide lean vapor stream, the sensible heat of at least a portion of the carbon dioxide lean vapor stream without prior expansion, the sensible heat of a fully expanded and vaporized portion of the carbon dioxide rich liquid stream; and/or the latent and sensible heat of a partially expanded and vaporized portion of the carbon dioxide rich liquid stream.
Of the various streams (the carbon dioxide rich stream provides cooling by expansion and evaporation and the carbon dioxide lean vapor stream provides cooling by expansion) obtained in the carbon dioxide separation unit 18 as will be described herein below.
During the carbon dioxide separation process step, a carbon dioxide rich liquid stream (via line 19) and a carbon dioxide lean overhead stream (via line 23) are obtained. The degree of refrigeration required for cooling the carbon dioxide in the first membrane stream to obtain the two phase stream 17 is obtained by utilizing the carbon dioxide rich liquid stream and the carbon dioxide lean overhead stream in two manners. First, as shown in
In a still further alternative to the present process, the compressed first membrane stream may be further cooled prior to its introduction into the heat exchanger 15 by using a heat exchanger 45. In this embodiment, additional pre-cooling of the compressed first membrane stream of line 14A can be obtained by heat exchange with the second membrane stream 11A which is directed to the heat exchanger 45 before being pulled off as product. Note that the streams of lines 12 and 11A are typically cooler than the incoming hydrocarbon containing feed stream of line 10 because of Joule-Thomson cooling associated with the pressure drop from feed stream to permeate side in the membrane 7. As a result, the carbon dioxide rich stream which is the cooled, compressed first membrane stream is routed to the heat exchanger 15 via line 14, while the product gas stream which is at a warmer temperature is withdrawn via line 11.
As noted, the cooling of the compressed, first membrane stream is carried out utilizing the streams produced in the carbon dioxide separation unit 18. Accordingly, the first membrane stream that is a compressed, cooled, two-phase stream from the heat exchanger 15 is then separated and purified in the carbon dioxide separation unit 18 to produce the two streams utilized to cool the first membrane stream in the heat exchanger 15. The cooled, compressed, first membrane stream is fed to the carbon dioxide separation unit 18 via line 17. The objective of the carbon dioxide separation unit 18 is to separate and purify the carbon dioxide from the stream 17 and to then utilize the streams obtained (the carbon dioxide rich liquid streams and the carbon dioxide lean overhead streams) to provide cooling in the multi-stream heat exchanger 15 by running these streams back through the heat exchanger 15 to capture the energy released from the streams. This separation and purification in the carbon dioxide separation unit 18 is accomplished through multiple or single step partial condensation and/or distillation steps. These multiple or single step partial condensation and/or distillation steps can be carried out in one of a number of manners: 1) by using one or more flash drums 35 operated at gradually decreasing pressures/temperatures (see
As a result of the above steps, the cold energy from the carbon dioxide rich liquid streams and the carbon dioxide lean vapor streams is transferred and utilized to cool the incoming cooled, compressed, first membrane stream to the level necessary to achieve a two phase (liquid/gas) stream.
Note that the pressure of the carbon dioxide rich liquid recycled to the heat exchanger 15 can be fixed by sequestration or re-injection requirements. Also with regard to the heat exchanger 15, a defrosting step may occasionally be utilized to remove any condensation and/or crystallization products from the heat exchanger 15 whenever pressure drop or heat transfer limitations become uneconomical and/or inefficient. During the defrosting step, the first membrane stream which is rich in carbon dioxide flows through the heat exchanger at a temperature ranging from approximately 0° C. to approximately 40° C. This stream is warmer than the temperature at which the first membrane stream is normally treated in the carbon dioxide separation unit 18 and accordingly is removed prior to reaching the carbon dioxide separation step.
The first embodiment for the carbon dioxide separation unit 18 is set forth in
The carbon dioxide lean overhead stream 23A obtained from the first flash drum 35A of the carbon dioxide separation unit 18 is recycled to the heat exchanger 15 and further cooled to a typical temperature range of about −45° to about −55° C. This stream 17B is then sent to the second flash drum 35B to produce a second carbon dioxide rich liquid stream and a second carbon dioxide lean vapor stream. As with the first carbon dioxide rich liquid stream, this second carbon dioxide rich liquid stream may be withdrawn as a carbon dioxide product stream via lines 19B and 19 with the remaining portion of the faction begin recycled to the heat exchanger via lines 22B, and 29B through expansion device 27B which allows for further cooling of the carbon dioxide rich stream before it is introduced into the heat exchanger 15 via line 29B. In this particular alternative, once the carbon dioxide rich stream is passed through the heat exchanger 15, it is it recycled to the compressor 13 via line 32B to be combined into stream 14A. As shown in
As illustrated in
Note that while
The remaining embodiment with regard to the carbon dioxide separation unit 18 is depicted in
In an alternative to
A still further embodiment of the process of the present invention is set forth in
A further embodiment of the process of the present invention is set forth in
Those of ordinary skill in the art will recognize that the process of the present invention can be utilized as it is presented herein or it may be utilized as a portion of a broader process application. More specifically, the process of the present invention can be coupled with EOR, sequestration, pipeline applications, or other processes that require the production of a carbon dioxide product.
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