Pretreatment, Pre-Cooling, and Condensate Recovery of Natural Gas By High Pressure Compression and Expansion

Abstract

A method and apparatus for producing liquefied natural gas (LNG) from a natural gas stream. Heavy hydrocarbons are removed from the natural gas stream in a separator to generate a bottom stream and a separated natural gas stream, which is used as a coolant in a heat exchanger to generate a pretreated natural gas stream. The pretreated natural gas stream is compressed and cooled to form a chilled pretreated natural gas stream, part of which forms a recycle stream to exchange heat with the separated natural gas stream in the heat exchanger, thereby generating a cooled recycle stream. The temperature and pressure of the cooled recycle stream are reduced. The cooled recycle stream is then separated into an overhead stream and a reflux stream, which is directed to the separator. The chilled pretreated gas stream is liquefied to form LNG.

Claims

1. A method of producing liquefied natural gas (LNG) from a natural gas stream, the method comprising: removing heavy hydrocarbons from the natural gas stream in a first separator to thereby generate a separated natural gas stream and a separator bottom stream; using the separated natural gas stream as a coolant in a heat exchanger to thereby generate a pretreated natural gas stream; compressing and cooling the pretreated natural gas stream to form a chilled pretreated to natural gas stream; recycling a portion of the chilled pretreated natural gas stream as a recycle stream to exchange heat, in the heat exchanger, with the separated natural gas stream, thereby generating a cooled recycle stream; reducing a temperature and a pressure of the cooled recycle stream; separating the cooled recycle stream into a gaseous separator overhead stream and a reflux stream; directing the reflux stream to a top portion of the first separator; and liquefying the chilled pretreated gas stream to form LNG.

2. The method of claim 1, wherein liquefying the chilled pretreated gas stream is performed in one of one or more single mixed refrigerant (SMR) liquefaction units, at least three parallel SMR liquefaction units, and one or more expander-based liquefaction modules comprising one or more nitrogen gas expander-based liquefaction modules or one or more feed gas expander-based liquefaction modules.

3. The method of claim 1, further comprising: separating liquids from the separator bottom stream in a second separator to form an overhead stream; and cooling the overhead stream and separating liquids therefrom in a third separator to form a gas product stream.

4. The method of claim 3, further comprising: combining at least a part of the product gas stream with the pretreated natural gas stream upstream of the at least one compressor.

5. The method of claim 1, wherein compressing and cooling the pretreated natural gas stream comprises: compressing the pretreated natural gas stream in at least one compressor to a pressure of at least 1,500 psia to form a compressed natural gas stream; cooling the compressed natural gas stream to form a cooled compressed natural gas stream; and expanding, in at least one work producing natural gas expander, the cooled compressed natural gas stream to a pressure that is less than 2,000 psia and no greater than the pressure to which the at least one compressor compresses the pretreated natural gas stream, to thereby form the chilled pretreated gas stream.

6. The method of claim 5, wherein the at least one compressor comprises at least two serially arranged compressors, and wherein one of the at least two serially arranged compressors is driven by the natural gas expander.

7. The method of claim 1, wherein compressing and cooling the natural gas stream comprises: compressing the pretreated natural gas stream in at least one compressor to a pressure of at least 1,500 psia to form the compressed natural gas stream; and cooling the compressed natural gas stream to form the chilled pretreated gas stream.

8. The method of claim 1, further comprising: combining the gaseous separator overhead stream with the column overhead stream upstream of the heat exchanger.

9. The method of claim 1, further comprising: directing the gaseous separator overhead stream to the heat exchanger; and after passing through the heat exchanger, combining the gaseous separator overhead stream with the pretreated natural gas stream.

10. The method of claim 1, further comprising: cooling a portion of the natural gas stream in the heat exchanger to generate a cooled natural gas stream; combining the cooled natural gas stream with the natural gas stream upstream of the first separator.

11. The method of claim 1, further comprising: cooling the natural gas stream in the heat exchanger upstream of the first separator.

12. An apparatus for the liquefaction of a natural gas stream, comprising: a first heat exchanger that cools at least a portion of the natural gas stream to generate a cooled natural gas stream, said portion of the natural gas stream combined with the natural gas stream; a first separation device configured to remove heavy hydrocarbons from the natural gas stream to thereby generate a separated natural gas stream and a separator bottom stream, wherein the separated natural gas stream is directed to the first heat exchanger to act as a coolant therein, thereby generating a pretreated natural gas stream; a compression and cooling unit that compresses and cools the pretreated natural gas stream to form a chilled pretreated stream; wherein a portion of the chilled pretreated gas stream is recycled to the first heat exchanger as a recycle stream to exchange heat with one or more process streams comprising at least one of the portion of the natural gas stream and the separated natural gas stream, thereby generating a cooled recycle stream; a temperature and pressure reducing device configured to reduce a temperature and a pressure of the cooled recycle stream; a fourth separation device that separates the cooled recycle stream into a gaseous separator overhead stream and a reflux stream, and wherein the reflux stream is directed to a top portion of the first separator; and at least one liquefaction unit configured to liquefy the chilled pretreated gas stream.

13. The apparatus of claim 12, wherein the at least one liquefaction unit comprises one or more single mixed refrigerant (SMR) liquefaction units, at least three parallel SMR liquefaction units, or one or more expander-based liquefaction modules comprising one or more nitrogen gas expander-based liquefaction modules or one or more feed gas expander-based liquefaction modules.

14. The apparatus of claim 12, further comprising: a second separation device that separates liquids from the separator bottom stream to form an overhead stream; and a second heat exchanger and a third separation device that cool and separate the overhead stream, respectively, to form a gas product stream.

15. The apparatus of claim 12, wherein at least a part of the product gas stream is combined with the pretreated natural gas stream upstream of the compression and cooling unit.

16. The apparatus of claim 12, wherein the compression and cooling unit comprises: at least one compressor that compresses the pretreated natural gas stream to a pressure of at least 1,500 psia, to thereby form a compressed natural gas stream; a third heat exchanger that cools the compressed natural gas stream to form a cooled compressed natural gas stream; and at least one work producing natural gas expander that expands the cooled compressed natural gas stream to a pressure that is less than 2,000 psia and no greater than the pressure to which the at least one compressor compresses the pretreated natural gas stream, to thereby form the chilled pretreated gas stream.

17. The apparatus of claim 16, wherein the at least one compressor comprises at least two serially arranged compressors, and wherein one of the at least two serially arranged compressors is driven by the natural gas expander.

18. The apparatus of claim 12, wherein the compression and cooling unit comprises: at least one compressor that compresses the pretreated natural gas stream to a pressure of at least 1,500 psia to form a compressed natural gas stream; and a third heat exchanger that cools the compressed natural gas stream to form a chilled pretreated gas stream.

19. The apparatus of claim 12, wherein the gaseous separator overhead stream is combined with the column overhead stream upstream of the heat exchanger.

20. The apparatus of claim 12, wherein the gaseous separator overhead stream is directed to pass through the heat exchanger and is combined with the pretreated natural gas stream.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0021] FIG. 1 is a schematic diagram of a SMR process with an integrated scrub column for heavy hydrocarbon removal according to known principles.

[0022] FIG. 2 is a schematic diagram of a high pressure compression and expansion (HPCE) module with heavy hydrocarbon removal according to disclosed aspects.

[0023] FIG. 3 is a schematic diagram showing an arrangement of single-mixed refrigerant (SMR) liquefaction modules according to known principles.

[0024] FIG. 4 is a schematic diagram showing an arrangement of SMR liquefaction modules according to disclosed aspects.

[0025] FIG. 5 is a graph showing a heating and cooling curve for an expander-based refrigeration process.

[0026] FIG. 6 is a schematic diagram of an HPCE module with heavy hydrocarbon removal according to disclosed aspects.

[0027] FIG. 7 is a schematic diagram of an HPCE module with heavy hydrocarbon removal and a feed gas expander-based liquefaction module according to disclosed aspects.

[0028] FIG. 8 is a flowchart of a method of liquefying natural gas to form LNG according to disclosed aspects.

[0029] FIG. 9 is a flowchart of a method of liquefying natural gas to form LNG according to disclosed aspects.

[0030] FIG. 10 is a schematic diagram of a natural gas pretreatment apparatus according to known principles.

[0031] FIG. 11 is a schematic diagram of a natural gas pretreatment apparatus according to disclosed aspects.

[0032] FIG. 12 is a schematic diagram of a natural gas pretreatment apparatus according to disclosed aspects.

[0033] FIG. 13 is a flowchart depicting a method of producing liquefied natural gas according to disclosed aspects.

DETAILED DESCRIPTION

[0034] Various specific aspects, embodiments, and versions will now be described, including definitions adopted herein. Those skilled in the art will appreciate that such aspects, embodiments, and versions are exemplary only, and that the invention can be practiced in other ways. Any reference to the invention may refer to one or more, but not necessarily all, of the embodiments defined by the claims. The use of headings is for purposes of convenience only and does not limit the scope of the present invention. For purposes of clarity and brevity, similar reference numbers in the several Figures represent similar items, steps, or structures and may not be described in detail in every Figure.

[0035] All numerical values within the detailed description and the claims herein are modified by about or approximately the indicated value, and take into account experimental error and variations that would be expected by a person having ordinary skill in the art.

[0036] As used herein, the term compressor means a machine that increases the pressure of a gas by the application of work. A compressor or refrigerant compressor includes any unit, device, or apparatus able to increase the pressure of a gas stream. This includes compressors having a single compression process or step, or compressors having multi-stage compressions or steps, or more particularly multi-stage compressors within a single casing or shell. Reference herein to more than one compressor includes more than one single-stage compressor, one or more multi-stage compressors, and any combination thereof. Evaporated streams to be compressed can be provided to a compressor at different pressures. Some stages or steps of a cooling process may involve two or more compressors in parallel, series, or both. The present invention is not limited by the type or arrangement or layout of the compressor or compressors, particularly in any refrigerant circuit.

[0037] As used herein, cooling broadly refers to lowering and/or dropping a temperature and/or internal energy of a substance by any suitable, desired, or required amount. Cooling may include a temperature drop of at least about 1 C., at least about 5 C., at least about 10 C., at least about 15 C., at least about 25 C., at least about 35 C., or least about 50 C., or at least about 75 C., or at least about 85 C., or at least about 95 C., or at least about 100 C. The cooling may use any suitable heat sink, such as steam generation, hot water heating, cooling water, air, refrigerant, other process streams (integration), and combinations thereof. One or more sources of cooling may be combined and/or cascaded to reach a desired outlet temperature. The cooling step may use a cooling unit with any suitable device and/or equipment. According to some embodiments, cooling may include indirect heat exchange, such as with one or more heat exchangers. In the alternative, the cooling may use evaporative (heat of vaporization) cooling and/or direct heat exchange, such as a liquid sprayed directly into a process stream.

[0038] As used herein, the term environment refers to ambient local conditions, e.g., temperatures and pressures, in the vicinity of a process.

[0039] As used herein, the term expansion device refers to one or more devices suitable for reducing the pressure of a fluid in a line (for example, a liquid stream, a vapor stream, or a multiphase stream containing both liquid and vapor). Unless a particular type of expansion device is specifically stated, the expansion device may be (1) at least partially by isenthalpic means, or (2) may be at least partially by isentropic means, or (3) may be a combination of both isentropic means and isenthalpic means. Suitable devices for isenthalpic expansion of natural gas are known in the art and generally include, but are not limited to, manually or automatically, actuated throttling devices such as, for example, valves, control valves, Joule-Thomson (J-T) valves, or venturi devices. Suitable devices for isentropic expansion of natural gas are known in the art and generally include equipment such as expanders or turbo expanders that extract or derive work from such expansion. Suitable devices for isentropic expansion of liquid streams are known in the art and generally include equipment such as expanders, hydraulic expanders, liquid turbines, or turbo expanders that extract or derive work from such expansion. An example of a combination of both isentropic means and isenthalpic means may be a Joule-Thomson valve and a turbo expander in parallel, which provides the capability of using either alone or using both the J-T valve and the turbo expander simultaneously. Isenthalpic or isentropic expansion can be conducted in the all-liquid phase, all-vapor phase, or mixed phases, and can be conducted to facilitate a phase change from a vapor stream or liquid stream to a multiphase stream (a stream having both vapor and liquid phases) or to a single-phase stream different from its initial phase. In the description of the drawings herein, the reference to more than one expansion device in any drawing does not necessarily mean that each expansion device is the same type or size.

[0040] The term gas is used interchangeably herein with vapor, and is defined as a substance or mixture of substances in the gaseous state as distinguished from the liquid or solid state. Likewise, the term liquid means a substance or mixture of substances in the liquid state as distinguished from the gas or solid state.

[0041] A heat exchanger broadly means any device capable of transferring heat energy or cold energy from one medium to another medium, such as between at least two distinct fluids. Heat exchangers include direct heat exchangers and indirect heat exchangers. Thus, a heat exchanger may be of any suitable design, such as a co-current or counter-current heat exchanger, an indirect heat exchanger (e.g. a spiral wound heat exchanger or a plate-fin heat exchanger such as a brazed aluminum plate fin type), direct contact heat exchanger, shell-and-tube heat exchanger, spiral, hairpin, core, core-and-kettle, printed-circuit, double-pipe or any other type of known heat exchanger. Heat exchanger may also refer to any column, tower, unit or other arrangement adapted to allow the passage of one or more streams therethrough, and to affect direct or indirect heat exchange between one or more lines of refrigerant, and one or more feed streams.

[0042] As used herein, the term heavy hydrocarbons refers to hydrocarbons having more than four carbon atoms. Principal examples include pentane, hexane and heptane. Other examples include benzene, aromatics, or diamondoids.

[0043] As used herein, the term indirect heat exchange means the bringing of two fluids into heat exchange relation without any physical contact or intermixing of the fluids with each other. Core-in-kettle heat exchangers and brazed aluminum plate-fin heat exchangers are examples of equipment that facilitate indirect heat exchange.

[0044] As used herein, the term natural gas refers to a multi-component gas obtained from a crude oil well (associated gas) or from a subterranean gas-bearing formation (non-associated gas). The composition and pressure of natural gas can vary significantly. A typical natural gas stream contains methane (C.sub.1) as a significant component. The natural gas stream may also contain ethane (C.sub.2), higher molecular weight hydrocarbons, and one or more acid gases. The natural gas may also contain minor amounts of contaminants such as water, nitrogen, iron sulfide, wax, and crude oil.

[0045] As used herein, the term separation device or separator refers to any vessel configured to receive a fluid having at least two constituent elements and configured to produce a gaseous stream out of a top portion and a liquid (or bottoms) stream out of the bottom of the vessel. The separation device/separator may include internal contact-enhancing structures (e.g. packing elements, strippers, weir plates, chimneys, etc.), may include one, two, or more sections (e.g. a stripping section and a reboiler section), and/or may include additional inlets and outlets. Exemplary separation devices/separators include bulk fractionators, stripping columns, phase separators, scrub columns, and others.

[0046] As used herein, the term scrub column refers to a separation device used for the removal of heavy hydrocarbons from a natural gas stream.

[0047] Certain embodiments and features have been described using a set of numerical upper limits and a set of numerical lower limits. It should be appreciated that ranges from any lower limit to any upper limit are contemplated unless otherwise indicated. All numerical values are about or approximately the indicated value, and take into account experimental error and variations that would be expected by a person having ordinary skill in the art.

[0048] All patents, test procedures, and other documents cited in this application are fully incorporated by reference to the extent such disclosure is not inconsistent with this application and for all jurisdictions in which such incorporation is permitted.

[0049] Aspects disclosed herein describe a process for pretreating and pre-cooling natural gas to a liquefaction process for the production of LNG by the addition of a high pressure compression and high pressure expansion process prior to liquefying the natural gas. A portion of the compressed and expanded gas is used to cool one or more process streams associated with pretreating the feed gas. More specifically, the invention describes a process where heavy hydrocarbons are removed from a natural gas stream to form a pretreated natural gas stream. The pretreated natural gas is compressed to pressure greater than 1,500 psia (10,340 kPa), or more preferably greater than 3,000 psia (20,680 kPa). The hot compressed gas is cooled by exchanging heat with the environment to form a compressed pretreated gas. The compressed pretreated gas is near-isentropically expanded to a pressure less than 3,000 psia (20,680 kPa), or more preferably to a pressure less than 2,000 psia (13,790 kPa) to form a first chilled pretreated gas, where the pressure of the first chilled pretreated gas is less than the pressure of the compressed pretreated gas. The first chilled pretreated gas is separated into at least one refrigerant stream and a non-refrigerant stream. The at least one refrigerant stream is directed to at least one heat exchanger where it acts to cool a process stream and form a warmed refrigerant stream. The warmed refrigerant stream is mixed with the non-refrigerant stream to form a second chilled pretreated gas. The second chilled pretreated gas may be directed to one or more SMR liquefaction trains, or the second chilled pretreated gas may be directed to one or more expander-based liquefaction trains where the gas is further cooled to form LNG.

[0050] FIG. 2 is an illustration of a pretreatment apparatus 200 for pretreating and pre-cooling a natural gas stream 201, followed by a high pressure compression and expansion (HPCE) process module 212. A natural gas stream 201 may flow into a separation device, such as a scrub column 202, where the natural gas stream 201 is separated into a column overhead stream 203 and a column bottom stream 204. The column overhead stream 203 may flow through a first heat exchanger 205, known as a cold box, where the column overhead stream 203 is partially condensed to form a two-phase stream 206. The two-phase stream 206 may flow into another separation device, such as a separator 207, to form cold pretreated gas stream 208 and a liquid stream 209. The cold pretreated gas stream 208 may flow through the first heat exchanger 205 where the cold pretreated gas stream 208 is warmed by indirectly exchanging heat with the column overhead stream 203, thereby forming a pretreated natural gas stream 210. The liquid stream 209 may be pressurized within a pump 211 and then directed to the scrub column 202 as a column reflux stream.

[0051] The HPCE process module 212 may comprise a first compressor 213 which compresses the pretreated natural gas stream 210 to form an intermediate pressure gas stream 214. The intermediate pressure gas stream 214 may flow through a second heat exchanger 215 where the intermediate pressure gas stream 214 is cooled by indirectly exchanging heat with the environment to form a cooled intermediate pressure gas stream 216. The second heat exchanger 215 may be an air cooled heat exchanger or a water cooled heat exchanger. The cooled intermediate pressure gas stream 216 may then be compressed within a second compressor 217 to form a high pressure gas stream 218. The pressure of the high pressure gas stream 218 may be greater than 1,500 psia (10,340 kPa), or more preferably greater than 3,000 psia (20,680 kPa). The high pressure gas stream 218 may flow through a third heat exchanger 219 where the high pressure gas stream 218 is cooled by indirectly exchanging heat with the environment to form a cooled high pressure gas stream 220. The third heat exchanger 219 may be an air cooled heat exchanger or a water cooled heat exchanger. The cooled high pressure gas stream 220 may then be expanded within an expander 221 to form a first chilled pretreated gas stream 222. The pressure of the first chilled pretreated gas stream 222 may be less than 3,000 psia (20,680 kPa), or more preferably less than 2,000 psia (13,790 kPa), and the pressure of the first chilled pretreated gas stream 222 is less than the pressure of the cooled high pressure gas stream 220. In a preferred aspect, the second compressor 217 may be driven solely by the shaft power produced by the expander 221, as indicated by the dashed line 223. The first chilled pretreated gas stream 222 may be separated into a refrigerant stream 224 and a non-refrigerant stream 225. The refrigerant stream 224 may flow through the first heat exchanger 205 where the refrigerant stream 224 is partially warmed by indirectly exchanging heat with the column overhead stream 203, thereby forming a warmed refrigerant stream 226. The warmed refrigerant stream 226 may mix with the non-refrigerant stream 225 to form a second chilled pretreated gas stream 227. The second chilled pretreated gas stream 227 may then be liquefied in, for example, an SMR liquefaction train 240 through indirect heat exchange with an SMR refrigerant loop 228 in a fourth heat exchanger 229. The resultant LNG stream 230 may then be stored and/or transported as needed.

[0052] It should be noted that the refrigerant stream 224 may be used to cool or chill any of the process streams associated with the pretreatment apparatus 200. For example, one or more of the column overhead stream 203, the two-phase stream 206, the cold pretreated gas stream 208, the liquid stream 209, and the pretreated natural gas stream 210 may be configured to exchange heat with the refrigerant stream 224. Furthermore, other process streams not associated with the pretreatment apparatus 200 may be cooled through heat exchange with the refrigerant stream 224. The refrigerant stream 224 may be split into two or more sub-streams that are used to cool various process streams.

[0053] In an aspect, the SMR liquefaction process may be enhanced by the addition of the HPCE process upstream of the SMR liquefaction process. More specifically, in this aspect, pretreated natural gas may be compressed to a pressure greater than 1,500 psia (10,340 kPa), or more preferably greater than 3,000 psia (20,680 kPa). The hot compressed gas is then cooled by exchanging heat with the environment to form a compressed pretreated gas. The compressed pretreated gas is then near-isentropically expanded to pressure less than 3,000 psia (20,680 kPa), or more preferably to a pressure less than 2,000 psia (13,790 kPa) to form a first chilled pretreated gas, where the pressure of the first chilled pretreated gas is less than the pressure of the compressed pretreated gas. The first chilled pretreated gas stream is separated into a refrigerant stream and a non-refrigerant stream. The refrigerant stream is warmed by exchanging heat with a column overhead stream in order to help partially condense the column overhead stream and produce a warmed refrigerant stream. The warmed refrigerant stream is mixed with the non-refrigerant stream to produce a second chilled pretreated gas. The second chilled pretreated gas may then be directed to multiple SMR liquefaction trains, arranged in parallel, where the chilled pretreated gas is further cooled therein to form LNG.

[0054] The combination of the HPCE process with pretreatment of the natural gas and liquefaction within multiple SMR liquefaction trains has several advantages over the conventional SMR process where natural gas is sent directly to the SMR liquefaction trains for both heavy hydrocarbon removal (final pretreatment step) and liquefaction. For example, the pre-cooling of the natural gas using the HPCE process allows for an increase in LNG production rate within the SMR liquefaction trains for a given horsepower within the SMR liquefaction trains. FIGS. 3 and 4 demonstrate how the disclosed aspects provide such an LNG production increase. FIG. 3 is an illustration of an arrangement of liquefaction modules or trains, such as SMR liquefaction trains, on an LNG production facility such as an FLNG unit 300 according to known principles. A natural gas stream 302 that is pretreated to remove sour gases and water to make the natural gas suitable for cryogenic treatment may be distributed between five identical or nearly identical SMR liquefaction trains 304, 306, 308, 310, 312 arranged in parallel. As an example, each SMR liquefaction train may receive approximately 50 megawatts (MW) of compression power from either a gas turbine or an electric motor (not shown) to drive the compressors of the respective SMR liquefaction train. Each SMR liquefaction module comprises an integrated scrub column to remove heavy hydrocarbons from the natural gas stream and to recover a sufficient amount of natural gas liquids to provide refrigerant make-up. Each SMR liquefaction module may produce approximately 1.5 million tons per year (MTA) of LNG for a total stream production of approximately 7.5 MTA for the entire FLNG unit 300.

[0055] In contrast, FIG. 4 schematically depicts an LNG liquefaction facility such as an FLNG unit 400 according to disclosed aspects. FLNG unit 400 includes four SMR liquefaction trains 406, 408, 410, 412 arranged in parallel. Unlike the SMR liquefaction trains shown in FIG. 3, none of the SMR liquefaction trains 406, 408, 410, 412 include a scrub column. Instead, a natural gas stream 402, which is pretreated to remove sour gases and water to make the gas suitable for cryogenic treatment, may be directed to a HPCE module 404 to produce a chilled pretreated gas stream 405. As previously explained, the HPCE module is integrated with a heavy hydrocarbon removal process therein (including a scrub column or similar separator) to remove any hydrocarbons that may form solids during the liquefaction of the natural gas stream 402. The HPCE module 404 may receive approximately 55 MW of compression power, for example, from either a gas turbine or an electric motor (not shown) to drive one or more compressors within the HPCE module 404. The chilled pretreated gas stream 405 may be distributed between the SMR liquefaction modules 406, 408, 410, 412. Each SMR liquefaction module may receive approximately 50 MW of compression power from either a gas turbine or an electric motor (not shown) to drive the compressors of the respective SMR liquefaction modules. Each SMR liquefaction module may produce approximately 1.9 MTA of LNG for a total production of approximately 7.6 MTA of LNG for the FLNG unit 400. If the FLNG unit 400 uses the disclosed HPCE process module integrated with a single scrub column and cold box (referred to collectively as the HPCE process module 404), only a single scrub column is required to remove heavy hydrocarbons from the natural gas stream 402. The replacement of one SMR liquefaction train with the disclosed HPCE module 404 is advantageous since the HPCE module is expected to be smaller, of less weight, and having significantly lower cost than the replaced SMR liquefaction train. Like the replaced SMR liquefaction train, the HPCE module 404 may have an equivalent size gas turbine to provide compression power, and it will also have an equivalent amount of air or water coolers. Unlike the replaced SMR liquefaction train, however, the HPCE module 404 does not have an expensive main cryogenic heat exchanger. The vessels and pipes associated with the refrigerant flow within an SMR module are eliminated in the replaced HPCE liquefaction train. Furthermore, the amount of expensive cryogenic pipes in the HPCE module 404 is significantly reduced.

[0056] The disclosed HPCE module comprises a single scrub column used to remove the heavy hydrocarbons from the natural gas that is then fed to all the liquefaction trains. This design increases the required power of the HPCE module by 10 to 15% compared to a design where heavy hydrocarbon removal is not included. However, integrating the heavy hydrocarbon removal within the HPCE module instead of within each SMR liquefaction train reduces the weight of each SMR liquefaction train and may result in a total reduction in equipment count and overall topside weight of an FLNG system. Another advantage is that the liquefaction pressure can be greater than the cricondenbar of the feed gas, which results in increased liquefaction efficiency. Furthermore, the proposed design is more flexible to feed gas changes than the integrated scrub column design.

[0057] Another advantage of the disclosed HPCE module is that the required storage of refrigerant is reduced since the number of SMR liquefaction trains has been reduced by one. Also, since a large fraction of the warm temperature cooling of the gas occurs in the HPCE module, the heavier hydrocarbon components of the mixed refrigerant can be reduced. For example, the propane component of the mixed refrigerant may be eliminated without any significant reduction in efficiency of the SMR liquefaction process.

[0058] Another advantage is that for a SMR liquefaction process which receives chilled pretreated gas from the disclosed HPCE module, the volumetric flow rate of the vaporized refrigerant of the SMR liquefaction process can be more than 25% less than that of a conventional SMR liquefaction process receiving warm pretreated gas. The lower volumetric flow of refrigerant may reduce the size of the main cryogenic heat exchanger and the size of the low pressure mixed refrigerant compressor. The lower volumetric flow rate of the refrigerant is due to its higher vaporizing pressure compared to that of a conventional SMR liquefaction process.

[0059] Known propane-precooled mixed refrigeration processes and dual mixed refrigeration (DMR) processes may be viewed as versions of an SMR liquefaction process combined with a pre-cooling refrigeration circuit, but there are significant differences between such processes and aspects of the present disclosure. For example, the known processes use a cascading propane refrigeration circuit or a warm-end mixed refrigerant to pre-cool the gas. Both these known processes have the advantage of providing 5% to 15% higher efficiency than the SMR liquefaction process. Furthermore, the capacity of a single liquefaction train using these known processes can be significantly greater than that of a single SMR liquefaction train. The pre-cooling refrigeration circuit of these technologies, however, comes at the cost of added complexity to the liquefaction process since additional refrigerants and a substantial amount of extra equipment is introduced. For example, the DMR liquefaction process's disadvantage of higher complexity and weight may outweigh its advantages of higher efficiency and capacity when deciding between a DMR liquefaction process and an SMR liquefaction process for an FLNG application. The known processes have considered the addition of a pre-cooling process upstream of the SMR liquefaction process as being driven principally by the need for higher thermal efficiencies and higher LNG production capacity for a single liquefaction train. The disclosed HPCE process combined with the SMR liquefaction process has not been realized previously because it does not provide the higher thermal efficiencies that the refrigerant-based pre-cooling process provides. As described herein, the thermal efficiency of the HPCE process with the SMR liquefaction is about the same as a standalone SMR liquefaction process. The disclosed aspects are believed to be novel based at least in part on its description of a pre-cooling process that aims to reduce the weight and complexity of the liquefaction process rather than increase thermal efficiency, which in the past has been the biggest driver for the addition of a pre-cooling process for onshore LNG applications. As an additional point, the integrated scrub column design is traditionally seen as the lowest cost option for heavy hydrocarbon removal of natural gas to liquefaction. However, the integration of heavy hydrocarbon removal with a HPCE process, as disclosed herein, provides a previously unrealized advantage of potentially reducing total equipment count and weight when multiple liquefaction trains is the preferred design methodology. For the newer applications of FLNG and remote onshore application, footprint, weight, and complexity of the liquefaction process may be a bigger driver of project cost. Therefore the disclosed aspects are of particular value.

[0060] In an aspect, an expander-based liquefaction process may be enhanced by the addition of an HPCE process upstream of the expander-based process. More specifically, in this aspect, a pretreated natural gas stream may be compressed to pressure greater than 1,500 psia (10,340 kPa), or more preferably greater than 3,000 psia (20,680 kPa). The hot compressed gas may then be cooled by exchanging heat with the environment to form a compressed pretreated gas. The compressed pretreated gas may be near-isentropically expanded to a pressure less than 3,000 psia (20,680 kPa), or more preferably to a pressure less than 2,000 psia (13,790 kPa) to form a first chilled pretreated gas, where the pressure of the first chilled pretreated gas is less than the pressure of the compressed pretreated gas. The first chilled pretreated gas stream is separated into refrigerant stream and a non-refrigerant stream. The refrigerant stream is warmed by exchanging heat with a column overhead stream in order to help partially condense the column overhead stream and produce a warmed refrigerant stream. The warmed refrigerant stream is mixed with the non-refrigerant stream to produce a second chilled pretreated gas. The second chilled pretreated gas is directed to an expander-based process where the gas is further cooled to form LNG. In a preferred aspect, the second chilled pretreated gas may be directed to a feed gas expander-based process.

[0061] FIG. 5 shows a typical temperature cooling curve 500 for an expander-based liquefaction process. The higher temperature curve 502 is the temperature curve for the natural gas stream. The lower temperature curve 504 is the composite temperature curve of a cold cooling stream and a warm cooling stream. The natural gas is liquefied at pressure above its cricondenbar which allows for the close matching of the natural gas cooling curve (shown at 502) with the composite temperature curve of the cold and warm cooling streams (shown at 504) to maximize thermal efficiency. As illustrated, the cooling curve is marked by three temperature pinch-points 506, 508, and 510. Each pinch point is a location within the heat exchanger where the combined heat capacity of the cooling streams is less than that of the natural gas stream. This imbalance in heat capacity between the streams results in a reduction of the temperature difference between the cooling stream to the minimally acceptable temperature difference which provides effective heat transfer rate. The lowest temperature pinch-point 506 occurs where the colder of the two cooling streams, typically the cold cooling stream, enters the heat exchanger. The intermediate temperature pinch-point 508 occurs where the second cooling stream, typically the warm cooling stream, enters the heat exchanger. The warm temperature pinch-point 510 occurs where the cold and warm cooling streams exit the heat exchanger. The warm temperature pinch-point 510 causes a need for a high mass flow rate for the warmer cooling stream, which subsequently increases the power demand of the expander-based process.

[0062] One proposed method to eliminate the warm temperature pinch-point 510 is to pre-cool the feed gas with an external refrigeration system such as a propane cooling system or a carbon dioxide cooling system. For example, U.S. Pat. No. 7,386,996 eliminates the warm temperature pinch-point by using a pre-cooling refrigeration process comprising a carbon dioxide refrigeration circuit in a cascade arrangement. This external pre-cooling refrigeration system has the disadvantage of significantly increasing the complexity of the liquefaction process since an additional refrigerant system with all its associated equipment is introduced. Aspects disclosed herein reduce the impact of the warm temperature pinch-point 510 by pre-cooling the feed gas stream by compressing the feed gas to a pressure greater than 1,500 psia (10,340 kPa), cooling the compressed feed gas stream, and expanding the compressed gas stream to a pressure less than 2,000 psia (20,690 kPa), where the expanded pressure of the feed gas stream is less than the compressed pressure of the feed gas stream. This process of cooling the feed gas stream results in a significant reduction in the in the required mass flow rate of the expander-based process cooling streams. It also improves the thermodynamic efficiency of the expander-based process without significantly increasing the equipment count and without the addition of an external refrigerant. This process may also be integrated with heavy hydrocarbon removal in order to remove the heavy hydrocarbon upstream of the liquefaction process. Since the gas is now free of heavy hydrocarbons that would form solids, the pretreated gas can be liquefied at a pressure above its cricondenbar in order to improve liquefaction efficiency.

[0063] In a preferred aspect, the expander-based process may be a feed gas expander-based process. This feed gas expander process comprises a first closed expander-based refrigeration loop and a second closed expander-based refrigeration loop. The first expander-based refrigeration loop may be principally charged with methane from a feed gas stream. The first expander-based refrigeration loop liquefies the feed gas stream. The second expander-based refrigeration loop may be charged with nitrogen as the refrigerant. The second expander-based to refrigeration loop sub-cools the LNG streams. Specifically, a produced natural gas stream may be treated to remove impurities, if present, such as water, and sour gases, to make the natural gas suitable for cryogenic treatment. The treated natural gas stream may be directed to a scrub column where the treated natural gas stream is separated into a column overhead stream and a column bottom stream. The column overhead stream may be partially condensed within a first heat exchanger by indirectly exchanging heat with a cold pretreated gas stream and a refrigerant stream to thereby form a two phase stream. The two phase stream may be directed to a separator where the two phase stream is separated into the cold pretreated gas stream and a liquid stream. The cold pretreated gas stream may be warmed within the first heat exchanger by exchanging heat with the column overhead stream to form a pretreated natural gas stream. The liquid stream may be pressurized within a pump and then directed to the scrub column to provide reflux to the scrub column. The pretreated natural gas stream may be directed to an HPCE process as disclosed herein, where it is compressed to a pressure greater than 1,500 psia (10,340 kPa), or more preferably greater than 3,000 psia (20,680 kPa). The hot compressed gas stream may then be cooled by exchanging heat with the environment to form a compressed treated natural gas stream. The compressed treated natural gas stream may be near-isentropically expanded to a pressure less than 3,000 psia (20,680 kPa), or more preferably to a pressure less than 2,000 psia (12,790 kPa) to form a first chilled treated natural gas stream, where the pressure of the first chilled treated natural gas stream is less than the pressure of the compressed treated natural gas stream. The first chilled natural gas stream may be separated into the refrigerant stream and a non-refrigerant stream. The refrigerant stream may be partially warmed within the first heat exchanger by exchanging heat with the column overhead stream to form a warmed refrigerant stream. The warmed refrigerant stream may mix with the non-refrigerant stream to form a second chilled natural gas stream. The second chilled treated natural gas may be directed to the feed gas expander process where the first expander-based refrigeration loop acts to liquefy the second chilled treated natural gas to form a pressurized LNG stream. The second expander refrigeration loop then acts to subcool the pressurized LNG stream. The subcooled pressurized LNG stream may then be expanded to a lower pressure in order to form an LNG stream.

[0064] The combination of the HPCE process with pretreatment of the natural gas and liquefaction of the pretreated gas within an expander-based process has several advantages over a conventional expander-based process. Including the HPCE process therewith may increase the efficiency of the expander-based process by 5 to 25% depending of the type of expander-based process employed. The feed gas expander process described herein may have a liquefaction efficiency similar to that of an SMR process while still providing the advantages of no external refrigerant use, ease of operation, and reduced equipment count. Furthermore, the refrigerant flow rates and the size of the recycle compressors are expected to be significantly lower for the expander-base process combined with the HPCE process. For these reasons, the production capacity of a single liquefaction train according to disclosed aspects may be greater than 30 to 50% above the production capacity of a similarly sized conventional expander-based liquefaction process. The combination of HPCE process with heavy hydrocarbon removal upstream of an expander-based liquefaction process has the additional benefit of providing the option to liquefy the gas at pressures above its cricondenbar to improve liquefaction efficiency. Expander-based liquefaction processes are particularly sensitive to liquefaction pressures. Therefore, the HPCE process described herein is well suited for removing heavy hydrocarbons while also increasing the liquefaction efficiency and production capacity of expander-based liquefaction processes.

[0065] FIG. 6 is an illustration of an aspect of an HPCE module 600 with an integrated scrub column according to another aspect of the disclosure. A natural gas stream 601, which has been pretreated to remove sour gases and water to make the gas suitable for cryogenic treatment, is fed into a separation device, such as a scrub column 602, where the natural gas stream 601 is separated into a column overhead stream 603 and a column bottom stream 604. The column overhead stream 603 may flow through a first heat exchanger 605 where the column overhead stream 603 is partially condensed to form a two-phase stream 606. The two-phase stream 606 may be directed to another separation device, such as a separator 607, to form a cold pretreated gas stream 608 and a liquid stream 609. The cold pretreated gas stream 608 may flow through the first heat exchanger 605 where the cold pretreated gas stream 608 is warmed by indirect heat exchange with the column overhead stream 603 to form a pretreated natural gas stream 610 therefrom. The liquid stream may be pressurized within a pump 611 and then directed to the scrub column 602 as a column reflux stream. The pretreated natural gas stream 610 is directed to a first compressor 612 and compressed therein to form a first intermediate pressure gas stream 613. The first intermediate pressure gas stream 613 may flow through a second heat exchanger 614 where the first intermediate pressure gas stream 613 is cooled by indirect heat exchange with the environment to form a cooled first intermediate pressure gas stream 615. The second heat exchanger 614 may be an air cooled heat exchanger or a water cooled heat exchanger. The cooled first intermediate pressure gas stream 615 may then be compressed within a second compressor 616 to form a second intermediate pressure gas stream 617. The second intermediate pressure gas stream 617 may flow through a third heat exchanger 618 where the second intermediate pressure gas stream 617 is cooled by indirect heat exchange with the environment to form a cooled second intermediate pressure gas stream 619. The third heat exchanger 618 may be an air cooled heat exchanger or a water cooled heat exchanger. The cooled second intermediate pressure gas stream 619 may then be compressed within a third compressor 620 to form a high pressure gas stream 621. The pressure of the high pressure gas stream 621 may be greater than 1,500 psia (10,340 kPa), or more preferably greater than 3,000 psia (20,680 kPa). The high pressure gas stream 621 may flow through a fourth heat exchanger 622 where the high pressure gas stream 621 is cooled by indirectly exchanging heat with the environment to form a cooled high pressure gas stream 623. The fourth heat exchanger 622 may be an air cooled heat exchanger or a water cooled heat exchanger. The cooled high pressure gas stream 623 may then be expanded within an expander 624 to form a first chilled pretreated gas stream 625. The pressure of the first chilled pretreated gas stream 625 may be less than 3,000 psia (20,680 kPa), or more preferably less than 2,000 psia (13,790 kPa), and the pressure of the first chilled pretreated gas stream 625 may be less than the pressure of the cooled high pressure gas stream 623. In an aspect, the third compressor 620 may be driven solely by the shaft power produced by the expander 624, as illustrated by line 624a. The first chilled pretreated gas stream 625 may be separated into a refrigerant stream 626 and a non-refrigerant stream 627. The refrigerant stream 626 may flow through the first heat exchanger 605 where the refrigerant stream 626 is partially warmed by indirectly exchanging heat with the column overhead stream 603 to form a warmed refrigerant stream 628 therefrom. The warmed refrigerant stream 628 may mix with the non-refrigerant stream 627 to form a second chilled pretreated gas stream 629, which may then be liquefied by an SMR liquefaction process as previously explained. As with pretreatment apparatus 200, the refrigerant stream 626 may be used to cool any process stream associated or not associated with the HPCE module 600.

[0066] FIG. 7 is an illustration of an HPCE module 700 with an integrated scrub column and combined with a feed gas expander-based LNG liquefaction process according to disclosed aspects. A natural gas stream 701, which has been pretreated to remove sour gases and water to make the gas suitable for cryogenic treatment, is fed into a separation device, such as a scrub column 702, where the treated natural gas stream 701 is separated into a column overhead stream 703 and a column bottom stream 704. The column overhead stream 703 may flow through a first heat exchanger 705 where the column overhead stream 703 is partially condensed to form a two-phase stream 706. The two-phase stream 706 may be directed to another separation device, such as a separator 707, to form a cold pretreated gas stream 708 and a liquid stream 709. The cold pretreated gas stream 708 may flow through the first heat exchanger 705 where the cold pretreated gas stream 708 is warmed by indirect heat exchange with the column overhead stream 703 to form a pretreated natural gas stream 710 therefrom. The liquid stream 709 may be pressurized within a pump 711 and then directed to the scrub column 702 as a column reflux. The pretreated natural gas stream 710 is directed to a first compressor 713 and compressed therein to form an intermediate pressure gas stream 714. The intermediate pressure gas stream 714 may flow through a second heat exchanger 715 where the intermediate pressure gas stream 714 is cooled by indirect heat exchange with the environment to form a cooled intermediate pressure gas stream 716. The second heat exchanger 715 may be an air cooled heat exchanger or a water cooled heat exchanger. The cooled intermediate pressure gas stream 716 may then be compressed within a second compressor 717 to form a high pressure gas stream 718. The pressure of the high pressure gas stream 718 may be greater than 1,500 psia (10,340 kPa), or more preferably greater than 3,000 psia (20,680 kPa). The high pressure gas stream 718 may flow through a third heat exchanger 719 where the high pressure gas stream 718 is cooled by indirect heat exchange with the environment to form a cooled high pressure gas stream 720. The third heat exchanger 719 may be an air cooled heat exchanger or a water cooled heat exchanger. The cooled high pressure gas stream 720 may then be expanded within an expander 721 to form a first chilled pretreated gas stream 722. The pressure of the first chilled pretreated gas stream 722 is less than 3,000 psia (20,680 kPa), or more preferably less than 2,000 psia (13,790 kPa), and where the pressure of the first chilled pretreated gas stream 722 is less than the pressure of the cooled high pressure gas stream 720. In an aspect, the second compressor 717 may be driven solely by the shaft power produced by the expander 721, as represented by the dashed line 723. The first chilled pretreated gas stream 722 may be separated into a refrigerant stream 724 and a non-refrigerant stream 725. The refrigerant stream 724 may flow through the first heat exchanger 705 where the refrigerant stream 724 is partially warmed by indirect heat exchange with the column overhead stream 703 to form a warmed refrigerant stream 726 therefrom. The warmed refrigerant stream 726 may mix with the non-refrigerant stream 725 to form a second chilled pretreated gas stream 727. As with pretreatment apparatus 200 and HPCE module 600, the refrigerant stream 724 may be used to cool any process stream associated or not associated with the HPCE module 700.

[0067] As illustrated in FIG. 7, the second chilled pretreated gas stream 727 is directed to a feed gas expander-based LNG liquefaction process 730. The feed gas expander-based process 730 includes a primary cooling loop 732, which is a closed expander-based refrigeration loop that may be charged with components from the feed gas stream. The liquefaction system also includes a subcooling loop 734, which is also a closed expander-based refrigeration loop preferably charged with nitrogen as the sub-cooling refrigerant. Within the primary cooling loop 732, an expanded, cooled refrigerant stream 736 is directed to a first heat exchanger zone 738 where it exchanges heat with the second chilled pretreated gas stream 727 to form a first warm refrigerant stream 740. The first warm refrigerant 740 is directed to a second heat exchanger zone 742 where it exchanges heat with a compressed, cooled refrigerant stream 744 to additionally cool the compressed, cooled refrigerant stream 744 and form a second warm refrigerant stream 746 and a compressed, additionally cooled refrigerant stream 748. The second heat exchanger zone 742 may comprise one or more heat exchangers where the one or more heat exchangers may be of a printed circuit heat exchanger type, a shell and tube heat exchanger type, or a combination thereof. The heat exchanger types within the second heat exchanger zone 742 may have a design pressure of greater than 1,500 psia, or more preferably, a design pressure of greater than 2,000 psia, or more preferably, a design pressure of greater than 3,000 psia.

[0068] The second warm refrigerant stream 746 is compressed in one or more compression units 750, 752 to a pressure greater than 1,500 psia, or more preferably, to a pressure of approximately 3,000 psia, to thereby form a compressed refrigerant stream 754. The compressed refrigerant stream 754 is then cooled against an ambient cooling medium (air or water) in a cooler 756 to produce the compressed, cooled refrigerant stream 744. The compressed, additionally cooled refrigerant stream 748 is near isentropically expanded in an expander 758 to produce the expanded, cooled refrigerant stream 736. The expander 758 may be a work expansion device, such as a gas expander, which produces work that may be extracted and used for compression.

[0069] The first heat exchanger zone 738 may include a plurality of heat exchanger devices, and in the aspects shown in FIG. 7, the first heat exchanger zone includes a main heat exchanger 760 and a sub-cooling heat exchanger 762. These heat exchangers may be of a brazed aluminum heat exchanger type, a plate fin heat exchanger type, a spiral wound heat exchanger type, or a combination thereof.

[0070] Within the sub-cooling loop 734, an expanded sub-cooling refrigerant stream 764 (preferably comprising nitrogen) is discharged from an expander 766 and drawn through the sub-cooling heat exchanger 762 and the main heat exchanger 760. The expanded sub-cooling refrigerant stream 764 is then sent to a compression unit 768 where it is re-compressed to a higher pressure and warmed. After exiting compression unit 768, the resulting recompressed sub-cooling refrigerant stream 770 is cooled in a cooler 772. After cooling, the recompressed to sub-cooling refrigerant stream 770 is passed through the main heat exchanger 760 where it is further cooled by indirect heat exchange with the expanded, cooled refrigerant stream 736 and the expanded sub-cooling refrigerant stream 764. After exiting the first heat exchanger area 738, the re-compressed and cooled sub-cooling refrigerant stream is expanded through the expander 766 to provide the expanded sub-cooling refrigerant stream 764 that is re-cycled through the first heat exchanger zone as described herein. In this manner, the second chilled pretreated gas stream 727 is further cooled, liquefied and sub-cooled in the first heat exchanger zone 738 to produce a sub-cooled gas stream 774. The sub-cooled gas stream 774 may be expanded to a lower pressure to produce the LNG stream (not shown).

[0071] FIG. 8 illustrates a method 800 of producing LNG according to disclosed aspects. At block 802 heavy hydrocarbons are removed from the natural gas stream to thereby generate a separated natural gas stream. At block 804 the separated natural gas stream is partially condensed in a first heat exchanger to thereby generate a partially condensed natural gas stream. At block 806 liquids are separated from the partially condensed natural gas stream to thereby generate a pretreated natural gas stream. At block 808 the pretreated natural gas stream is compressed in at least two serially arranged compressors to a pressure of at least 1,500 psia to form a compressed natural gas stream. At block 810 the compressed natural gas stream is cooled to form a cooled compressed natural gas stream. At block 812 the cooled natural gas stream is expanded to a pressure that is less than 2,000 psia and no greater than the pressure to which the at least two serially arranged compressors compress the pretreated natural gas stream, to thereby form a chilled natural gas stream. At block 814 the chilled natural gas stream is separated into a refrigerant stream and a non-refrigerant stream. At block 816 the refrigerant stream is warmed through heat exchange with one or more process streams comprising the natural gas stream, the separated natural gas stream, the partially condensed natural gas stream, and the pretreated natural gas stream, thereby generating a warmed refrigerant stream. At block 818 the warmed refrigerant stream and the non-refrigerant stream are liquefied.

[0072] FIG. 9 illustrates a method 900 of producing LNG according to disclosed aspects. At block 902 the natural gas stream is pretreated to generate a pretreated natural gas stream. At block 904 the pretreated natural gas stream is compressed in at least two serially arranged compressors to a pressure of at least 1,500 psia. At block 906 the compressed natural gas stream is cooled. At block 908 the cooled compressed natural gas stream is expanded in at least one work producing natural gas expander to a pressure that is less than 2,000 psia and no greater than the pressure to which the at least two serially arranged compressors compress the pretreated to natural gas stream, to thereby form a chilled natural gas stream. At block 910 the chilled natural gas stream is separated into a refrigerant stream and a non-refrigerant stream. At block 912 the refrigerant stream is warmed in a heat exchanger through heat exchange with one or more process streams associated with pretreating the natural gas stream, thereby generating a warmed refrigerant stream. At block 914 the warmed refrigerant stream and the non-refrigerant stream are liquefied.

[0073] FIG. 11 depicts a pretreatment apparatus 1100 for pretreating and pre-cooling a natural gas stream 1102, followed by a high pressure compression and expansion (HPCE) process module 1150, according to another aspect of the disclosure. A side stream 1104 of the natural gas stream 1102 may be directed to a first heat exchanger 1106 to be cooled therein and form a cooled natural gas stream 1108. The cooled natural gas stream 1108 is combined with the natural gas stream 1102 to produce a combined natural gas stream 1110. The side stream may comprise 1% to 100%, or 10% to 90%, or 25% to 75%, or 40% to 60% of the natural gas stream 1102, depending on the temperature of the natural gas stream 1102 and the desired input temperature of the combined natural gas stream 1110 into a scrub column 1112, into which the combined natural gas stream is directed. Inside the scrub column 1112, the combined natural gas stream 1110 is separated into a column overhead stream 1114 (which may be called a separated natural gas stream) and a column bottom stream 1116. The column bottom stream 1116 is directed to a stabilizer 1118. The stabilizer 1118 removes light hydrocarbons from the column bottom stream 1116, and is thereby separated into a stabilizer overhead stream 1120 and a stabilized hydrocarbons liquid stream 1122. The stabilized hydrocarbons liquid stream 1122 is stable at normal storage conditions and is salable as stabilized condensate. The stabilizer overhead stream 1120 is cooled in a reflux cooler 1124 and directed to a reflux separator 1126, where it is separated into a reflux liquid stream 1128 and a gas product stream 1130. The gas product stream 1130 may be used as a fuel gas or liquefied using an end flash gas (not shown) in a liquefaction unit. Alternatively, part or all of the gas product stream 1130 may be compressed and then combined, using line 1131, with a pretreated natural gas stream 1140, which is further described herein. The reflux liquid stream 1128 may be pumped by pump 1132 to be returned to the stabilizer 1118, where it functions to wash down any heavy hydrocarbons from upflowing gas in the stabilizer. A stripping gas stream 1134 for the scrub column may be sourced from the natural gas stream 1102; alternatively, a reboiler (not shown) may be used to provide the stripping gas for the scrub column.

[0074] The column overhead stream 1114 flows through first heat exchanger 1106, thereby forming a pretreated natural gas stream 1140. Prior to flowing through the first heat exchanger 1106, the pressure and temperature of the column overhead stream 1114 may be reduced using a pressure-reducing device such as a Joule-Thomson valve 1142. The pretreated natural gas stream 1140 is sent to a compression and cooling unit, which in an aspect may comprise a high pressure compression and expansion (HPCE) process module 1150. The HPCE process module 1150 may comprise a first compressor 1152 which compresses the pretreated natural gas stream 1140 to form an intermediate pressure gas stream 1154. The intermediate pressure gas stream 1154 may flow through a second heat exchanger (not shown) where the intermediate pressure gas stream 1154 is cooled by indirectly exchanging heat with an ambient environment. The second heat exchanger may be an air cooled heat exchanger or a water cooled heat exchanger. The intermediate pressure gas stream 1154 may then be compressed within a second compressor 1156 to form a high pressure gas stream 1158. The pressure of the high pressure gas stream 1158 may be greater than 1,500 psia (10,340 kPa), or more preferably greater than 3,000 psia (20,680 kPa). The high pressure gas stream 1158 may flow through a third heat exchanger 1160 where the high pressure gas stream 1158 is cooled by indirectly exchanging heat with an ambient environment, thereby forming a cooled high pressure gas stream 1162. The third heat exchanger 1160 may be an air cooled heat exchanger or a water cooled heat exchanger. The cooled high pressure gas stream 1162 may then be expanded within an expander 1164 to form a chilled pretreated gas stream 1166. Chilled pretreated gas stream 1166 may also be referred to herein as a cooled pretreated gas stream. The pressure of the chilled pretreated gas stream 1166 may be less than 3,000 psia (20,680 kPa), or more preferably less than 2,000 psia (13,790 kPa), and the pressure of the chilled pretreated gas stream 1166 is less than the pressure of the cooled high pressure gas stream 1162. In a preferred aspect, the second compressor 1156 may be driven solely by shaft power produced by the expander 1164. In other disclosed aspects, including those aspects in which the HPCE process module 1150 includes only one compressor, the expander 1164 may be connected to a generator (not shown) to generate power.

[0075] A portion of the chilled pretreated gas stream is directed to the first heat exchanger 1106 as a recycle stream 1168, where it and side stream 1104 are cooled by column overhead stream 1114 and/or a gaseous separator drum overhead stream 1176 as described below. The resulting cooled recycle stream 1170 passes through a pressure and temperature reducing device, such as a Joule-Thomson valve 1172, and is directed into a separator drum 1174. The separator drum separates the cooled recycle stream 1170 into the gaseous separator drum overhead stream 1176 and a scrub column reflux stream 1178. Gaseous separator drum overhead stream 1176 may be combined with the column overhead stream 1114 (i.e., upstream of the first heat exchanger). Alternatively, the gaseous separator drum overhead stream 1176 may be combined with the pretreated natural gas stream 1140 (i.e., downstream of the first heat exchanger), such that the gaseous separator drum overhead stream passes through the first heat exchanger as a separate stream from the column overhead stream. This alternative scenario may provide more flexibility in matching cooling curves within the first heat exchanger, while passing the combined two streams through the first heat exchanger reduces complexity of the system. The scrub column reflux stream 1178 is directed to a top portion of the scrub column 1112, where it provides sufficient cooling to liquefy and separate heavy hydrocarbons within the scrub column. The remainder of the chilled pretreated gas stream 1166 is directed to further processing, which in a preferred aspect is a natural gas liquefaction module 1180. The liquefaction module 1180 may employ any type of liquefaction technology, such as single mixed refrigerant (SMR), dual mixed refrigerant (DMR), expander-based technologies using nitrogen and/or methane, or other liquefaction techniques. Such liquefaction techniques are considered to be within the scope of the disclosed aspects.

[0076] FIG. 12 depicts a pretreatment apparatus 1200 for pretreating and pre-cooling a natural gas stream 1202 according to another aspect of the disclosure. A valve 1203 (or another pressure-reducing device such as an expander) reduces the temperature and pressure of the natural gas stream, which is directed to a first heat exchanger 1206 to be cooled therein, thereby forming a cooled natural gas stream 1208. The cooled natural gas stream 1208 is directed into a scrub column 1212. Inside the scrub column 1212, the cooled natural gas stream 1208 is separated into a column overhead stream 1214 (which may be called a separated natural gas stream) and a column bottom stream 1216. The column bottom stream 1216 is directed to a stabilizer 1218, which removes light hydrocarbons from the column bottom stream 1216, and is thereby separated into a stabilizer overhead stream 1220 and a stabilized hydrocarbons liquid stream 1222. The stabilized hydrocarbons liquid stream 1222 is stable at normal storage conditions and is salable as stabilized condensate. The stabilizer overhead stream 1220 is cooled in a reflux cooler 1224 and directed to a reflux separator 1226, where it is separated into a reflux liquid stream 1228 and a gas product stream 1230. The gas product stream 1230 may be used as a fuel gas or liquefied using an end flash gas (not shown) in a liquefaction unit. Alternatively, part or all of the gas product stream 1230 may be compressed in a gas product compressor 1231a and then combined, using line 1231, with a pretreated natural gas stream 1240, which is further described herein. The reflux liquid stream 1228 may be pumped by pump 1232 to be returned to the stabilizer 1218, where it functions to wash down any heavy hydrocarbons from upflowing gas in the stabilizer. A stripping gas stream 1234 for the scrub column may be sourced from the natural gas stream 1202; alternatively, a reboiler (not shown) may be used to provide the stripping gas for the scrub column.

[0077] The column overhead stream 1214 flows through first heat exchanger 1206, thereby forming a pretreated natural gas stream 1240. The pretreated natural gas stream 1240 is sent to a feed compressor 1252 which compresses the pretreated natural gas stream 1240 to form an intermediate pressure gas stream 1254. The intermediate pressure gas stream 1254 may flow through a second heat exchanger 1255 where the intermediate pressure gas stream 1254 is cooled by indirectly exchanging heat with an ambient environment, thereby forming a chilled or cooled pretreated gas stream 1266. The second heat exchanger may be an air cooled heat exchanger or a water cooled heat exchanger. The pressure of the cooled pretreated gas stream 1266 may be less than 3,000 psia (20,680 kPa), or more preferably less than 2,000 psia (13,790 kPa).

[0078] A portion of the cooled pretreated gas stream 1266 is directed to the first heat exchanger 1206 as a recycle stream 1268, where it and the natural gas stream are cooled by the column overhead stream 1214 and/or a gaseous separator drum overhead stream 1276 as described below. The resulting cooled recycle stream 1270 passes through a pressure and temperature reducing device, such as a Joule-Thomson valve 1272, and is directed into a separator drum 1274. The separator drum separates the cooled recycle stream 1270 into the gaseous separator drum overhead stream 1276 and a scrub column reflux stream 1278. Gaseous separator drum overhead stream 1276 may be combined with the column overhead stream 1214 (i.e., upstream of the first heat exchanger). Alternatively, as depicted in FIG. 12, the gaseous separator drum overhead stream 1276 may be combined with the pretreated natural gas stream 1240 downstream of the first heat exchanger such that the gaseous separator drum overhead stream passes through the first heat exchanger as a separate stream from the column overhead stream. This alternative scenario may provide more flexibility in matching cooling curves within the first heat exchanger, while passing the combined two streams through the first heat exchanger reduces complexity of the system. The scrub column reflux stream 1278 is directed to a top portion of the scrub column 1212, where it provides sufficient cooling to liquefy and separate heavy hydrocarbons within the scrub column. The remainder of the cooled pretreated gas stream 1266 is directed to further processing, which in a preferred aspect is a natural gas liquefaction module 1280. The liquefaction module 1280 may employ any type of liquefaction technology, such as single mixed refrigerant (SMR), dual mixed refrigerant (DMR), expander-based technologies using nitrogen and/or methane, or other liquefaction techniques. Such liquefaction techniques are considered to be within the scope of the disclosed aspects.

[0079] The aspects disclosed in FIGS. 11-12 provide several advantages over known gas pretreating or conditioning processes. For example, the gaseous separator drum overhead stream 1176/1276 and the column overhead stream 1114/1214 have acceptably low levels of heavy hydrocarbons, and the scrub column reflux stream 1178/1278 provides sufficient cooling for heavy hydrocarbon separation in the scrub column 1112/1212. As a result, enhanced recovery of heavy hydrocarbons is achieved when compared with known gas pretreatment technologies. Additionally, the energy required for gas pretreatment is reduced, as is the overall cost of gas pretreatment.

[0080] An advantage of the gas pretreatment process of the disclosed aspects is that it is more applicable to a wide range of feed gas compositions.

[0081] Another advantage is that because of the enhanced heavy hydrocarbons recovery from the stabilizer 1118/1218, the condensate stream at 1122/1222 is greater. This enables a processor to take advantage of favorable price or demand conditions for condensate sale. Therefore, the disclosed aspects provide a flexible approach to gas processing to be responsive to changes in commodity price and demand.

[0082] Additionally, the aspects disclosed herein can be used in any LNG liquefaction location, they have especial utility in circumstances where space is at a premium for LNG liquefaction, such as offshore liquefaction, onshore remote facilities, and the like.

[0083] FIG. 13 is a flowchart showing a method 1300 of producing liquefied natural gas (LNG) from a natural gas stream according to disclosed aspects. At block 1302 heavy hydrocarbons are removed from the natural gas stream in a first separator to thereby generate a separated natural gas stream and a separator bottom stream. At block 1304 the separated natural gas stream is used as a coolant in a heat exchanger to thereby generate a pretreated natural gas stream. At block 1306 the pretreated natural gas stream is compressed and cooled to form a chilled pretreated natural gas stream. At block 1308 a portion of the chilled pretreated gas stream forms a recycle stream to exchange heat with the separated natural gas stream in the heat exchanger, thereby generating a cooled recycle stream. At block 1310 a temperature and a pressure of the cooled recycle stream are reduced. At block 1312 the cooled recycle stream is separated into a gaseous separator overhead stream and a reflux stream. At block 1314 the reflux stream is directed to a top portion of the first separator. At block 1316 the chilled pretreated gas stream is liquefied to form LNG.

[0084] While the foregoing is directed to aspects of the present disclosure, other and further aspects of the disclosure may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.