Raw natural gas comprises primarily methane and also contains numerous minor constituents which may include water, hydrogen sulfide, carbon dioxide, mercury, nitrogen, and light hydrocarbons typically having two to six carbon atoms. Some of these constituents, such as water, hydrogen sulfide, carbon dioxide, and mercury, are contaminants which are harmful to downstream steps such as natural gas processing or the production of liquefied natural gas (LNG), and these contaminants must be removed upstream of these processing steps. The hydrocarbons heavier than methane typically are condensed and recovered as natural gas liquids (NGL) and fractionated to yield valuable hydrocarbon products.
The first step in the NGL recovery process utilizes a distillation column or scrub column to separate the hydrocarbons heavier than methane from the pretreated natural gas feed to yield purified methane for liquefaction and NGL for separation and recovery. This process utilizes cooling, partial condensation, and fractionation steps that require significant amounts of refrigeration. This refrigeration may be provided by work expansion of pressurized natural gas feed and vaporization of the resulting condensed hydrocarbons. Additional refrigeration typically is provided by external closed-loop refrigeration using a refrigerant such as propane and/or a mixed refrigerant to liquefy the methane in the main heat exchanger. Reflux for the NGL scrub column may utilize a portion of the partially-liquefied natural gas from the main heat exchanger.
It is desirable to recover NGL from pressurized natural gas without reducing the natural gas feed pressure significantly. This allows the natural gas product (for example, pipeline gas or LNG) to be provided at or slightly below the feed pressure so that feed and/or product recompression is not required. It is also desirable to eliminate the need for scrub column overhead compression and to simplify the main heat exchanger design when a portion of the liquefied natural gas is withdrawn from the main heat exchanger for use as scrub column reflux. These needs are addressed by the embodiments of the present invention described below and defined by the claims that follow.
There are several aspects of the method and apparatus as outlined below.
Aspect 1: A process for the liquefaction of natural gas and the recovery of components heavier than methane from the natural gas, wherein the process comprises:
(a) introducing a natural gas feed into a first distillation column and separating in the first distillation column the natural gas feed into an overhead vapor enriched in methane and a bottoms liquid enriched in components heavier than methane;
(b) withdrawing from the first distillation column a first overhead vapor stream enriched in methane and a bottoms liquid stream enriched in components heavier than methane;
(c) cooling the first overhead vapor stream enriched in methane to provide a cooled overhead stream enriched in methane, combining the cooled overhead stream enriched in methane with a liquefied natural gas reflux stream to provide a two-phase mixture, and separating the two-phase mixture to provide a liquid reflux stream and a second overhead vapor stream enriched in methane;
(d) introducing the liquid reflux stream into the first distillation column to provide reflux to the distillation column;
(e) introducing the second overhead vapor stream enriched in methane into a main heat exchanger comprising only two tube bundles, said bundles consisting of a warm bundle and a cold bundle, and cooling and liquefying the second overhead vapor stream in the warm bundle to provide a single-phase, liquefied natural gas product; and
(f) subcooling at least a portion of the liquefied natural gas product in the cold bundle of the main heat exchanger to provide a subcooled liquefied natural gas product, and withdrawing the subcooled liquefied natural gas product from the main heat exchanger.
Aspect 2: The process of Aspect 1, wherein the liquefied natural gas reflux stream comprises: a portion of the single-phase, liquefied natural gas product, withdrawn from the main heat exchanger between the warm and cold bundles; a portion of the subcooled liquefied natural gas product; and/or liquefied natural gas obtained from processing and/or storing at least a portion of the subcooled liquefied natural gas product.
Aspect 3: The process of Aspect 1 or 2, wherein the method further comprises the step of withdrawing from the main heat exchanger, between the warm and cold bundles, a first portion of the liquefied natural gas product, the liquefied natural gas reflux stream comprising said first portion of the liquefied natural gas product; and wherein step (f) comprises subcooling a second portion of the liquefied natural gas product in the cold bundle of the main heat exchanger to provide a subcooled liquefied natural gas product, and withdrawing the subcooled liquefied natural gas product from the main heat exchanger.
Aspect 4: The process of any preceding Aspects, wherein the method further comprises the steps of: separating the bottoms liquid stream in one or more additional distillation columns to provide one or more hydrocarbon product streams selected from the group consisting of a residual vapor stream comprising methane, a liquid stream enriched in ethane, a liquid stream enriched in propane, a liquid stream enriched in butane, and a liquid stream enriched in pentane; and withdrawing as recovered hydrocarbons all or a portion of any of the one or more hydrocarbon product streams.
Aspect 5: The process of Aspect 4, wherein step (c) comprises: combining the first overhead vapor stream enriched in methane with a stream of unrecovered hydrocarbons, cooling the combined stream to provide the cooled overhead stream enriched in methane, combining the cooled overhead stream enriched in methane with the liquefied natural gas reflux stream to provide the two-phase mixture, and separating the two-phase mixture to provide the liquid reflux stream and the second overhead vapor stream enriched in methane.
Aspect 6: The process of Aspect 5, wherein the stream of unrecovered liquid hydrocarbons comprises any of: (I) a portion of the liquid stream enriched in ethane, (II) a portion of the liquid stream enriched in propane, (Ill) a portion of the liquid stream enriched in butane, (IV) a portion of the liquid stream enriched in pentane, and (V) all or a portion of the residual vapor stream dissolved in a portion of the liquid stream enriched in propane and/or a portion of the liquid stream enriched in butane and/or a portion of the liquid stream enriched in pentane.
Aspect 7: The process of any preceding Aspects, wherein in step (c) the first overhead vapor stream is cooled to a temperature of from −20 to −70° F. (−29 to −57° C.).
Aspect 8: The process of any preceding Aspects, wherein the natural gas feed is cooled prior to being introduced into the first distillation column.
Aspect 9: The process of Aspect 8, wherein the natural gas feed is cooled to a temperature of from 10 to −30° F. (12 to −34° C.) prior to being introduced into the first distillation column.
Aspect 10: The process of Aspects 8 or 9, wherein the cooling of the first overhead vapor stream enriched in methane to provide the cooled overhead stream enriched in methane, and the cooling of the natural gas feed prior to said natural gas feed being introduced into the first distillation column, is carried out using the same refrigerant.
Aspect 11: The process of any preceding Aspects, wherein the liquid reflux stream is introduced into the top of the first distillation column.
Aspect 12: The process of any preceding Aspects, wherein boilup for the first distillation column is provided by vaporizing a portion of the bottoms liquid in a reboiler.
Aspect 13: The process of any preceding Aspect, wherein the cooling and liquefying of the second overhead vapor stream in the warm bundle of the main heat exchanger is effected by indirect heat exchange with a first vaporizing refrigerant provided by reducing the pressure of a first cooled multicomponent liquid refrigerant.
Aspect 14: The process of Aspect 13, wherein the first cooled multicomponent liquid refrigerant is provided by cooling a first multicomponent refrigerant in the warm bundle of the main heat exchanger.
Aspect 15: The process of any preceding Aspects, wherein the subcooling of the at least a portion of the liquefied natural gas product in the cold bundle of the main heat exchanger is effected by indirect heat exchange with a second vaporizing refrigerant provided by reducing the pressure of a second cooled multicomponent liquid refrigerant.
Aspect 16: The process of Aspect 15, wherein the second cooled multicomponent liquid refrigerant is provided by cooling a second multicomponent refrigerant in the warm and cold bundles of the main heat exchanger.
Aspect 17: The process of any preceding Aspects, wherein the flow rate of the cooled overhead stream enriched in methane is greater than the flow rate of the liquefied natural gas reflux stream, such that the cooled overhead stream provides the majority of the two-phase mixture.
Aspect 18: The process of Aspect 17, wherein the flow rate of the liquefied natural gas reflux stream is less than 10% of the sum of the flow rates of the liquefied natural gas reflux stream and the cooled overhead stream.
Aspect 19: An apparatus for the liquefaction of natural gas and the recovery of components heavier than methane from the natural gas, wherein the apparatus comprises:
(a) a first distillation column adapted to separate a natural gas feed into an overhead vapor enriched in methane and a bottoms liquid enriched in components heavier than methane and thereby provide a first overhead vapor stream enriched in methane and a bottoms liquid stream enriched in components heavier than methane;
(b) a cooling system adapted to cool the first overhead vapor stream enriched in methane to provide a cooled overhead stream enriched in methane;
(c) a reflux drum adapted to receive a two-phase mixture, formed from the combination of the cooled overhead stream enriched in methane and a liquefied natural gas reflux stream, and adapted to separate the two-phase mixture to provide a liquid reflux stream and a second overhead vapor stream enriched in methane;
(d) piping adapted to introduce the cooled overhead stream and the liquefied natural gas reflux stream, as separate streams or as a combined stream, into the reflux drum;
(e) piping adapted to introduce the liquid reflux stream into the first distillation column to provide reflux to the distillation column;
(f) a main heat exchanger comprising only two tube bundles, said bundles consisting of a warm bundle and a cold bundle, the warm bundle being adapted to cool and liquefy the second overhead vapor stream to provide a single-phase, liquefied natural gas product, and the cold bundle being adapted to subcool at least a portion of the liquefied natural gas product to provide a subcooled liquefied natural gas product;
(g) piping adapted to introduce the second overhead vapor stream into the warm bundle of the main heat exchanger; and
(h) piping adapted to withdraw the liquefied natural gas product stream from the cold bundle of the main heat exchanger.
Aspect 20: The apparatus of Aspect 19, wherein said piping adapted to introduce the liquefied natural gas reflux stream into the reflux drum is adapted to withdraw a portion of the liquefied natural gas product from the main heat exchanger between the warm and cold bundles, to withdraw a portion of the subcooled liquefied natural gas product and/or to withdraw liquefied natural gas obtained from processing and/or storing at least a portion of the subcooled liquefied natural gas product, the liquefied natural gas reflux stream comprising said portion of the liquefied natural gas product, said portion of the subcooled liquefied natural gas product and/or said liquefied natural gas obtained from processing and/or storing at least a portion of the subcooled liquefied natural gas product.
Aspect 21: The apparatus of Aspect 19 or 20, wherein the apparatus further comprises:
(i) one or more additional distillation columns adapted to separate the bottoms liquid stream in provide one or more hydrocarbon product streams selected from the group consisting of a residual vapor stream comprising methane, a liquid stream enriched in ethane, a liquid stream enriched in propane, a liquid stream enriched in butane, and a liquid stream enriched in pentane; and
(j) piping adapted to withdraw as recovered hydrocarbons all or a portion of any of the one or more hydrocarbon product streams.
Aspect 22: The apparatus of Aspect 21, wherein the apparatus further comprises piping adapted to introduce a stream of unrecovered hydrocarbons into the first overhead vapor stream enriched in methane prior to the resulting combined stream being cooled in the cooling system, wherein the stream of unrecovered liquid hydrocarbons is withdrawn from one of the additional distillation columns and comprises any of: (I) a portion of the liquid stream enriched in ethane, (II) a portion of the liquid stream enriched in propane, (III) a portion of the liquid stream enriched in butane, (IV) a portion of the liquid stream enriched in pentane, and (V) all or a portion of the residual vapor stream dissolved in a portion of the liquid stream enriched in propane and/or a portion of the liquid stream enriched in butane and/or a portion of the liquid stream enriched in pentane.
Aspect 23: The apparatus of any one of Aspects 19 to 22, wherein the apparatus further comprises a precooling system adapted to cool the natural gas feed prior to said feed being introduced into the first distillation column.
Aspect 24: The apparatus of Aspect 23, wherein said cooling system, adapted to cool the first overhead vapor stream enriched in methane to provide a cooled overhead stream enriched in methane, and said precooling system, adapted to cool the natural gas feed prior to said feed being introduced into the first distillation column, are adapted to utilize the same refrigerant.
Aspect 25: The process or apparatus of any preceding Aspect, wherein the main heat exchanger is a wound coil heat exchanger comprising only two wound coil tube bundles, said bundles consisting of said warm bundle and said cold bundle.
The embodiments of the invention provide improved integrated processes for NGL recovery in the production of LNG that simplify the equipment configuration by eliminating the need for feed expansion and scrub column overhead compression. In addition, when the scrub column utilizes reflux comprising scrub column overhead that is condensed in a wound coil main heat exchanger, there is no need for splitting the warm bundle of the heat exchanger to partially condense the column overhead, and a phase separator to recover the liquid required for reflux is not required. In addition, there is no need for compression and condensation of deethanizer overhead vapor to provide scrub column reflux.
Reflux for the scrub column in the embodiments described below is provided by various combinations of condensed scrub column overhead vapor and unrecovered liquid hydrocarbons from the NGL recovery system. In the present disclosure, the terms “recovered hydrocarbon” and “recovered hydrocarbons” are equivalent and mean any hydrocarbon stream withdrawn from the integrated LNG production and NGL recovery system as a product that is exported from the integrated system. The recovered hydrocarbons may be exported as one or more product streams enriched in any of the hydrocarbons in the natural gas feed. The exported streams may include, for example, any of an enriched ethane stream, an enriched propane stream, an enriched butane plus isobutane stream, an enriched pentane plus isopentane stream, and a mixed methane-ethane stream enriched in ethane. The LNG product may be considered as a recovered hydrocarbon. The term “unrecovered liquid hydrocarbon” and “unrecovered liquid hydrocarbons” are equivalent and mean any liquid portion of the hydrocarbons separated in the NGL recovery system that are not immediately present in the product streams of the recovered hydrocarbons that are exported from the integrated LNG production and NGL recovery system. Unrecovered liquid hydrocarbons may be considered as internal recycle streams within the integrated LNG production and NGL recovery system.
The term “enriched” as applied to any stream withdrawn from a process means that the withdrawn stream contains a concentration of a particular component that is higher than the concentration of that component in the feed stream to the process. Reflux is defined as a stream introduced into a distillation column at any location above the location at which the feed is introduced into the column, wherein the reflux comprises one or more components previously withdrawn from the column. Reflux typically is liquid but may be a vapor-liquid mixture.
The indefinite articles “a” and “an” as used herein mean one or more when applied to any feature in embodiments of the present invention described in the specification and claims. The use of “a” and “an” does not limit the meaning to a single feature unless such a limit is specifically stated. The definite article “the” preceding singular or plural nouns or noun phrases denotes a particular specified feature or particular specified features and may have a singular or plural connotation depending upon the context in which it is used. The adjective “any” means one, some, or all indiscriminately of whatever quantity. The term “and/or” placed between a first entity and a second entity means one of (1) the first entity, (2) the second entity, and (3) the first entity and the second entity.
A first embodiment of the invention is shown in the integrated LNG production and NGL recovery system illustrated by
Heat exchanger 110 may include multiple stages of cooling by evaporating propane at different pressures; alternatively or additionally, other means of cooling may be used, such as vaporizing mixed refrigerant in a single exchanger. This stream, which may be further cooled in optional economizer heat exchanger 114, is introduced via line 116 to first distillation column or scrub column 118.
Scrub column 118 separates the feed provided via line 116 into a bottoms liquid product in line 134 that is enriched in hydrocarbons heavier than methane and an overhead vapor product in line 120 that is enriched in methane. A portion of the bottoms liquid may be withdrawn via line 130 and vaporized in reboiler 132 to provide boilup for the scrub column. The reboiler may cool a portion (not shown) of stream 100 to provide heat therein for vaporizing the liquid in line 130. The scrub column may also have an intermediate reboiler (not shown) above the bottom of the column and below the location of feed line 116, and this reboiler also may be heated by a portion of the feed stream.
The bottoms liquid in line 134 flows to generic NGL fractionation system 136. The NGL feed stream typically is reduced in pressure (not shown) and separated in or more additional distillation columns including any of a demethanizer, a deethanizer, a depropanizer, a debutanizer, and a depentanizer to provide two or more hydrocarbon fractions. In the exemplary generic NGL fractionation system of
The overhead vapor stream enriched in methane is withdrawn from scrub column 118 via line 120 and may be warmed by indirect heat exchange with the feed stream in line 112 in economizer heat exchanger 114. The resulting warmed overhead vapor stream in line 122 is cooled, totally condensed, and optionally subcooled in passage 123 of the first or warm (lower) bundle of wound coil main heat exchanger 124 to provide a condensed methane-enriched stream in line 125. A first portion of the liquid in line 125 is withdrawn from line 125 downstream of passage 123 and pumped by pump 127 to provide a liquefied methane-containing reflux stream. The liquefied methane-containing reflux stream is combined with the unrecovered liquid hydrocarbons in line 138 and returned to the top of scrub column 118 as a combined liquid reflux steam. Alternatively, liquefied methane-containing reflux stream from pump 127 may be introduced into the top of scrub column 118 and the unrecovered liquid hydrocarbons in line 138 may be introduced into scrub column 118 at a separate location (not shown) below the top of the column and above the location at which the cooled feed is introduced into the column via line 116. In another alternative, the liquefied methane-containing reflux stream from pump 127 and the unrecovered hydrocarbons in line 138 may be introduced into the top of scrub column 118 as separate streams (not shown).
Typically, depending on the composition of the feed in line 100, the molar flow rate of the unrecovered liquid hydrocarbons in line 138 is less than about 25% of the molar flow rate of the methane-rich stream in line 126. If the natural gas feed in line 100 does not contain a sufficient amount of the components needed to provide the unrecovered liquid hydrocarbon stream in line 138, the necessary components may be imported from any appropriate source.
The second portion of the condensed methane-enriched stream in line 125 is further cooled in passage 128 the second or cold (upper) bundle of wound coil main heat exchanger 124 and withdrawn as LNG product via line 129. The LNG may be reduced in pressure before and/or after subcooling in the cold bundle if desired. If the LNG product is stored at high pressure (PLNG), there is no need for subcooling, and the cold bundle is not required. It is possible to use a portion of the LNG product in line 129 as a methane-rich reflux to scrub column 118 if desired, but such a configuration would waste refrigeration by providing reflux at a temperature much lower than required.
The temperature of the liquefied methane-containing reflux stream withdrawn from main heat exchanger 124 via line 126 and pump 127 in
Refrigeration to main heat exchanger 124 may be provided by any known refrigeration system used in the production of LNG. For example, as shown in
The refrigerant streams are completely vaporized and leave main heat exchanger 124 as refrigerant vapor via line 150. The mixed refrigerant vapor flows to a refrigeration system (not shown) where it is compressed, cooled by multiple stages of vaporizing propane, and separated to provide liquid refrigerant 152 and lighter vapor refrigerant 156.
Any other refrigeration system or a combination of systems known in the art may be used to provide refrigeration to main heat exchanger 124. For example, the pure fluid cascade and isentropic vapor expansion process may be used as described in U.S. Pat. No. 6,308,531, which is incorporated herein by reference.
Using a portion of condensed scrub column overhead as methane-enriched reflux via line 126 in the embodiment of
The use of unrecovered liquid hydrocarbons via line 138 as additional reflux to scrub column 118 eliminates the need for expanding the column feed and recompressing the column overhead. To minimize power consumption, the natural gas feed pressure should be significantly above the critical pressure of methane. At the same time, the scrub column must be operated below the critical pressure of the feed mixture in order to achieve separation. A common solution known in the art is to isentropically expand the scrub column feed and then to recompress the overhead vapor product. Work obtained from the isentropic expansion of the feed can be used to at least partially drive the overhead compressor or compressors. Such a solution is shown, for example, in U.S. Pat. No. 4,065,267 and in
Another embodiment of the invention is illustrated in
Alternatively, the liquefied methane-containing reflux stream from heat exchanger 200 may be introduced into the top of scrub column 118 and the unrecovered liquid hydrocarbons in line 138 may be introduced into scrub column 118 at a separate location (not shown) below the top of the column and above the location at which the cooled feed is introduced into the column via line 116. In another alternative, the liquefied methane-containing reflux stream from heat exchanger 200 and the unrecovered liquid hydrocarbons in line 138 may be introduced into the top of scrub column 118 as separate streams (not shown).
Refrigeration for main heat exchanger 124 is provided in the same manner as described above with reference to
In an alternative version of the process described above with reference to
An alternative embodiment of the invention is illustrated in
Alternatively, the condensed methane-rich stream from heat exchanger 300 may be introduced into the top of scrub column 118 and the unrecovered hydrocarbons in line 138 may be introduced into scrub column 118 at a location (not shown) below the top of the column and above the location at which the cooled feed is introduced into the column via line 116. In another alternative, the liquefied methane-containing reflux stream from heat exchanger 300 and the unrecovered liquid hydrocarbons in line 138 may be introduced into the top of scrub column 118 as separate streams (not shown). All other process features of
In an alternative version of the process described above with reference to
Throttling valve 426 and drum 427 can be avoided by detecting liquid in line 126 (for example with a thermocouple) and redirecting vapor or two-phase flow from the main heat exchanger 124 at a startup situation (at normal operation it is subcooled liquid) to another existing drum such as helium recovery or fuel gas flash drum or simply by flaring it. In another alternative, the system can be simplified by using a type of pump 127 that can tolerate two-phase flow at off-design conditions, such as a cryogenic gear or screw pump or a centrifugal pump with a high-performance inducer.
An exemplary NGL recovery system that can be used with embodiments of the present invention is illustrated in
High purity ethane vapor is withdrawn from the column via line 523 and is condensed in overhead condenser 525. A portion of the condensed liquid is returned as reflux via line 527 and another portion is withdrawn via line 529 as a recovered hydrocarbon comprising high purity ethane typically containing greater than 98 mole % ethane. The bottoms liquid from the deethanizer via line 531 is partially vaporized in heat exchanger 533, boilup vapor is returned to the column via line 535, and the remaining stream flows via line 537 and valve 539 into depropanizer column 505. High purity propane vapor is withdrawn from the column via line 541 and is condensed in overhead condenser 543. A portion of the condensed liquid is returned as reflux via line 545 and another portion is withdrawn via line 547 as a recovered hydrocarbon comprising high purity propane typically containing greater than 98 mole % propane.
The bottoms liquid from the depropanizer via line 549 is partially vaporized in heat exchanger 551, boilup vapor is returned to the column via line 553, and the remaining stream flows via line 555 and valve 557 into debutanizer column 507. High purity butane (plus isobutane if present) vapor is withdrawn from the column via line 559 and is condensed in overhead condenser 561. A portion of the condensed liquid is returned as reflux via line 563 and another portion is withdrawn via line 565 as a recovered hydrocarbon comprising high purity butane (plus isobutane if present) typically containing greater than 98 mole % butane plus isobutane. The bottoms liquid from the debutanizer is withdrawn via line 567 and partially vaporized in heat exchanger 569, boilup vapor is returned to the column via line 571, and the remaining stream is withdrawn via line 573 as a recovered hydrocarbon comprising pentane (plus isopentane if present) and heavier hydrocarbons.
In this illustration, propane and butane liquid streams may be withdrawn as unrecovered liquid hydrocarbons via lines 575 and 577, respectively, and mixed in line 579. The mixed unrecovered liquid hydrocarbon stream is cooled to temperature of vaporizing propane refrigerant in heat exchanger 581, is pumped to scrub column pressure in pump 583, and flows via line 138 to the scrub column in any of the embodiments of
Scrub column 618 separates the pretreated pressurized natural gas feed stream in line 600 into a bottoms liquid in line 634 that is enriched in hydrocarbons heavier than methane and a first overhead vapor in line 620 that is enriched in methane. A portion of the bottoms liquid may be withdrawn via line 630 and vaporized in reboiler 632 to provide boilup for the scrub column 618. The reboiler 632 may cool a portion (not shown) of the pretreated pressurized natural gas feed stream in line 600 to provide heat therein for vaporizing the liquid in line 630. The scrub column 618 may also have an intermediate reboiler (not shown) above the bottom of the scrub column 618 and below the location of line 600, and this reboiler also may be heated by a portion of the pretreated pressurized natural gas feed stream in line 600.
The bottoms liquid in line 634 may flow to a NGL fractionation system 636, which for example may be a NGL fractionation system as described above with reference to
The scrub column 618 is refluxed using a reflux drum 611. The first overhead vapor stream of line 620, or optionally, the combined stream of line 662 of unrecovered liquid hydrocarbons in line 638 and the first overhead vapor stream of line 620 is cooled in cooler 664, by vaporizing propane or another suitable refrigerant, to a temperature preferably between −20 and −70° F. to form a cooled overhead stream enriched in methane in line 666. As with the optional precooling of natural gas feed 600 prior to introduction thereof into scrub column 618, other suitable refrigerants may, for example, include other single component refrigerants (such as other hydrocarbons, HFCs, CFCs, or CO2) or multicomponent refrigerants.
Preferably, cooler 664 and precooler 610 utilize the same refrigerant, such as where cooler 664 and precooler 610 are supplied with refrigerant by the same closed or open loop refrigerant system. For example, cooler 664 and precooler 610 may be supplied with a single component refrigerant by the same closed loop refrigerant system. Closed loop refrigerant systems are well known in the art, and any suitable refrigerant system may be used to supply refrigerant to the cooler 664 and precooler 610.
Referring now to
Referring back to
As one skilled in the art may now recognize, when utilizing a two bundle main exchanger 624, stream 626 exits the main exchanger 624 at a temperature far lower or colder than is required to be used as reflux for scrub column 618. Thus, it would be inefficient to use LNG reflux stream 626 (that then becomes stream 668) on its own for reflux because such a cold or refrigerated stream is not required.
Instead, in the embodiment depicted in
Referring back to
Importantly, the configuration of the embodiment disclosed in
Optionally, an economizer heat exchanger similar to 114 in
Refrigeration to main heat exchanger 624 may be provided by any known refrigeration system used in the production of LNG. For example, as shown in
The refrigerant streams are completely vaporized and leave main heat exchanger 624 as refrigerant vapor via line 650. The mixed refrigerant vapor flows to a refrigeration system (not shown) where it is compressed, cooled by multiple stages of vaporizing propane or other suitable refrigerant, and separated to provide liquid refrigerant 652 and lighter vapor refrigerant 656.
Although in the embodiment depicted in Figure the LNG reflux stream in line 668 is obtained solely from LNG product withdrawn via line 626 from the main heat exchanger 624 between the warm and cold bundles, other sources of LNG can additionally and/or alternatively be used to provide the LNG reflux stream. For example,
While using a portion of the subcooled LNG product, as shown in
Optionally, reinjection stream 638 can be introduced directly into the reflux drum 611, cooled in a separate circuit in the warm bundle of the MCHE and then put into the reflux drum 611, or introduced directly into the scrub column 618 (not shown).
In the above described embodiments of the invention, other NGL fractionation systems may be used depending on the particular hydrocarbons to be recovered. For example, the system may utilize a depentanizer column to recover high purity pentanes and a residual product containing hydrocarbons heavier than pentane. A portion of the pentanes may be returned as an unrecovered hydrocarbon to scrub column 118/618. In another alternative, the demethanizer is not used and the deethanizer is operated to withdraw the ethane liquid product at an intermediate stage and to withdraw a mixture of methane and ethane vapor from the reflux drum as a recovered hydrocarbon product. A portion of this vapor may be withdrawn as an unrecovered hydrocarbon product and dissolved in the unrecovered liquid hydrocarbon mixture as described above.
The following Examples illustrate an embodiment of the present invention but do not limit embodiments of the invention to any of the specific details described therein.
A process simulation was carried out to illustrate the embodiment of
The scrub column bottoms stream is withdrawn via line 134 at a flow rate of 1862 lbmol/hr and is sent to NGL fractionation system 136, which is a series of distillation columns as shown in
Unrecovered liquid propane and butane in lines 575 and 577 are combined in line 138, cooled by propane refrigeration to −32.3° F. in heat exchanger 581, and pumped to the scrub column pressure in pump 583. The unrecovered propane in line 575 is 50% of the overhead stream in depropanizer overhead line 541 and the unrecovered butane in line 577 butane is 60% of the overhead stream in debutanizer overhead line 559. The combined unrecovered hydrocarbon stream in line 579 has a flow rate of 1116 lbmol/hr and a composition (in mole %) of 39% propane, 60% butane plus isobutanes, and 1% components heavier than butane. The pumped unrecovered liquid hydrocarbon is combined with the liquefied methane-containing reflux stream from pump 127 and the combined stream is introduced into the top of scrub column 118.
Additional process simulations were carried out to compare the embodiment of
In both cases, the LNG plant was set to produce about 5 million metric tons per annum of LNG. Referring to the configuration of
The overhead vapor product 720 leaves the top of the column at −7.1° F. The second stage of the column is at 0.8° F. Stream 720 is combined with the reinjection stream 638 and cooled by propane in a kettle-type heat exchanger to −28.2° F. Resulting stream 778 is further cooled and partially liquefied in the warm bundle of the MCHE to −60.0° F. Two-phase stream 782, 786 enters the reflux drum 611 where it is separated into the liquid stream 613 and the second overhead vapor product 788, 760. No bypass is assumed. About 45% of liquid stream 613, stream 728, is re-injected into stream 760.
The remaining 55%, about 6% of feed 600, is used as reflux. Stream 760, including the re-injected stream 728, about 99.5% of the feed 600, still at −60.0° F., is introduced into the middle bundle of the MCHE and fully liquefied and subcooled in the MCHE to produce subcooled LNG product 628. The scrub column bottoms product 634, about 0.7% of the feed stream 600, at −230.0° F., is fractionated into NGL products, part of it re-injected as stream 638.
The scrub column operation is determined by the allowable concentration of benzene in LNG product, kept at one part per million.
Referring to
The first overhead vapor stream 620 leaves the top of the column at −1.3° F. (close to the temperature of the second stage in the previous example). It is combined with a reinjected stream 638 and cooled by vaporizing propane in a kettle-type heat exchanger 664 to −29.4° F. Resulting stream 666 is combined with LNG reflux stream 626, 668 which is at −193.5° F. Resulting stream 670 enters the reflux drum 611 at −32.7° F. Stream 626 is only about 1.4% of the combined stream 670 or the feed stream 600. It provides a bit of additional cooling required for optimum operation. Stream 670 is separated into the second overhead vapor stream 660 and the liquid reflux stream 613 which is used as reflux for the scrub column 618. The reflux is about 2.5% of the feed stream 600. Stream 660 is introduced into the warm bundle of the two-bundle MCHE and fully liquefied in the warm bundle to produce a fully condesned LNG product. A portion of the fully-condensed LNG product is withdrawn between the warm and cold bundles and used as LNG reflux stream 626 to contribute to the reflux for the scrub column 618 as discussed above. The remainder of the fully-condensed LNG product is subcooled in the cold bundle of the two bundle MCHE to produce subcooled LNG product stream 628. The scrub column bottoms product 634, about 0.7% of the feed 600, at −217.4° F., is fractionated into NGL products, and part of it re-injected as stream 638.
As before, the scrub column operation is determined by the allowable concentration of benzene in LNG product, kept at one part per million.
Table 1 compares the two cases. Compared to prior art, the configuration shown on
This application is a Continuation-In-Part of Ser. No. 11/491,329, which was filed on Jul. 21, 2006, and which is incorporated herein by reference.
Number | Date | Country | |
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Parent | 11491329 | Jul 2006 | US |
Child | 13669539 | US |