The present invention relates generally to systems and methods for processing gases and, more particularly, to a system and method for removing freezing components from a feed gas.
There are several aspects of the present subject matter which may be embodied separately or together in the methods, devices and systems described and claimed below. These aspects may be employed alone or in combination with other aspects of the subject matter described herein, and the description of these aspects together is not intended to preclude the use of these aspects separately or the claiming of such aspects separately or in different combinations as set forth in the claims appended hereto.
In one aspect, a system for removing freezing components from a feed gas includes a scrub column having a feed gas inlet, a reflux liquid inlet and a vapor outlet, where the feed gas inlet is configured to receive at least a portion of the feed gas. A heat exchanger includes a reflux cooling passage and a return vapor passage, with the return vapor passage and the reflux cooling passage of the heat exchanger configured so that fluid flowing through the reflux cooling passage of the heat exchanger is cooled by return fluid flowing through the return vapor passage of the heat exchanger. The reflux cooling passage of the heat exchanger is configured to receive and cool a reflux vapor stream that is at least a portion of the feed gas, prior to any portion of the reflux vapor stream flowing through the return vapor passage of the heat exchanger, so that a reflux fluid stream is formed and to direct at least a portion of the reflux fluid stream to the reflux liquid inlet of the scrub column. A return vapor expansion device has an inlet in fluid communication with the vapor outlet of the scrub column. The return vapor expansion device also has an outlet in communication with an inlet of the return vapor passage of the heat exchanger and the return vapor expansion device is configured so that a pressure and a temperature of at least a portion of the return vapor stream from the vapor outlet of the scrub column are lowered and directed into the return vapor passage of the heat exchanger. A processed feed gas line is in communication with an outlet of the vapor return passage of the heat exchanger.
In another aspect, a system for removing freezing components from a feed gas includes a scrub device having a scrub column having a feed gas inlet, a reflux liquid inlet and a vapor outlet, where the feed gas inlet is configured to receive at least a portion of the feed gas. The scrub device also includes a reflux separation device, where the reflux separation device includes a mixed phase inlet, a reflux liquid outlet that is in fluid communication with the reflux liquid inlet of the scrub column, and a reflux separation device vapor outlet that is in fluid communication with the vapor outlet of the scrub column. A heat exchanger includes a reflux cooling passage and a return vapor passage, with the return vapor passage and the reflux cooling passage of the heat exchanger configured so that fluid flowing through the reflux cooling passage of the heat exchanger is cooled by return fluid flowing through the return vapor passage of the heat exchanger. The reflux cooling passage of the heat exchanger is configured to receive and cool a reflux vapor stream that is at least a portion of the feed gas, prior to any portion of the reflux vapor stream flowing through the return vapor passage of the heat exchanger, so that a mixed phase reflux stream is formed and to direct at least a portion of the mixed phase reflux stream to the mixed phase inlet of the reflux separation device of the scrub device. A return vapor expansion device has an inlet in fluid communication with the vapor outlet of the scrub column. The return vapor expansion device also has an outlet in communication with an inlet of the return vapor passage of the heat exchanger. The return vapor expansion device is configured so that a pressure and a temperature of at least a portion of the return vapor stream from the vapor outlet of the scrub column are lowered and directed into the return vapor passage of the heat exchanger. A processed feed gas line is in communication with an outlet of the vapor return passage of the heat exchanger.
In yet another aspect, a method for removing freezing components from a feed gas includes the steps of: providing a heat exchanger, a scrub column and a return vapor expansion device; directing at least a portion of the feed gas to a feed gas inlet of the scrub column; directing a reflux vapor stream that is at least a portion of the feed gas to a reflux cooling passage of the heat exchanger; cooling the reflux vapor stream, prior to any portion of the reflux vapor stream flowing through a return vapor passage of the heat exchanger, so that a reflux fluid stream is formed; directing the reflux fluid stream to a reflux liquid inlet of the scrub device; vaporizing the reflux fluid stream in the scrub device so that the freezing components are condensed and removed from the feed gas in the scrub device; directing a return vapor stream from the scrub column to the return vapor expansion device; lowering a temperature and a pressure of the return vapor stream in the expansion device to form a return fluid stream; directing the return fluid stream to a return vapor passage of the heat exchanger and warming the return fluid stream in the return vapor passage of the heat exchanger.
Embodiments of a mixed refrigerant liquefaction system and method are illustrated in
The basic liquefaction process and mixed refrigerant compressor system are described in commonly owned U.S. Pat. No. 9,411,877, to Gushanas et al., the contents of which are hereby incorporated by reference. Generally, with reference to
The system of
The removal of heat is accomplished in the heat exchanger using a mixed refrigerant, that is processed and reconditioned using a mixed refrigerant compressor system indicated in general at 22. The mixed refrigerant compressor system includes a high pressure accumulator 43 that receives and separates a mixed refrigerant (MR) mixed-phase stream 11 after a last compression and cooling cycle. While an accumulator drum 43 is illustrated, alternative separation devices may be used, including, but not limited to, another type of vessel, a cyclonic separator, a distillation unit, a coalescing separator or mesh or vane type mist eliminator. High pressure vapor refrigerant stream 13 exits the vapor outlet of the accumulator 43 and travels to the warm side of the heat exchanger 10.
High pressure liquid refrigerant stream 17 exits the liquid outlet of accumulator 43 and also travels to the warm end of the heat exchanger. After cooling in the heat exchanger 10, it travels as mixed phase stream 47 to mid-temp stand pipe 128.
After the high pressure vapor stream 13 from the accumulator 43 is cooled in the heat exchanger 10, mixed phase stream 19 flows to cold vapor separator 21. A resulting vapor refrigerant stream 23 exits the vapor outlet of the separator 21 and, after cooling in the heat exchanger 10, travels to cold temperature stand pipe 27 as mixed-phase stream 29. Vapor and liquid streams 41 and 45 exit the cold temperature stand pipe 27 and feed into the primary refrigeration passage 125 on the cold side of the heat exchanger 10.
The liquid stream 25 exiting the cold vapor separator 21 is cooled in heat exchanger 10 and exits the heat exchanger as mixed phase stream 122, which is handled in the manner described below.
The systems of
The system shown in
In the system of
The system of
Once the cooled high pressure MR stream from the cold recovery heat exchanger 38 is received by the mid-standpipe 48 or the mid-temperature liquid expander separator 52, it is delivered to the refrigeration passage 55 of the liquefying heat exchanger 44 by lines 57a and 57b (of
The EFG cold recovery options of
The system of
In alternative embodiments, with reference to
In the system of
As illustrated in
Returning to
Alternatively, with reference to
The mid-temperature liquid expanders of
A system and method for removing freezing components from the feed gas stream before liquefaction in the main heat exchanger will now be described with reference to
As illustrated at 182 in
The refrigeration required to reflux the column 154 via reflux stream 155 is provided by a combination of the return vapor 156 from the column, which is warmed in the heat exchanger 146, and a mixed refrigerant (MR) stream 158 from the liquefaction compressor system (indicated in general at 162) that is also directed to the heat exchanger 146. The stream 153 exiting the scrub column, while preferably all vapor, contains components that liquefy at a higher temperature (as compared to the vapor stream 156 exiting the top of the column). As a result, the stream 155 entering the column 154 after passing through heat exchanger 146 is two-phase and the liquid component stream performs the reflux. The liquid component stream flows through a reflux liquid component passage that may include, as examples only, a reflux liquid component line that may be external (157) or internal to the scrub device or a downcomer or other internal liquid distribution device within the scrub device 154. As noted above, operation of the liquefaction compressor system may be as described in commonly owned U.S. Pat. No. 9,411,877, to Gushanas et al. After the MR is initially cooled in the heavy hydrocarbon heat exchanger via passage 164, it is flashed across a JT valve 166 to provide a cold mixed refrigerant stream 168 to the heavy hydrocarbon removal heat exchanger.
The temperature of the mixed refrigerant can be controlled by controlling the boiling pressure of the mixed refrigerant.
The components removed from the bottom of the scrub column 154 via stream 172 are returned to the heat exchanger 146 to recover refrigeration and then sent to additional separation steps such as a condensate stripping system, indicated in general at 174 or sent to fuel or other disposal methods.
The feed gas stream 176 exiting the heat exchanger 146, with freezing components removed, is then sent to the main liquefaction heat exchanger 178, or in the case of incorporating an expander/compressor, is first compressed, then sent to the main heat exchanger 178.
An alternative system and method for removing freezing components from a feed gas stream before liquefaction in the main heat exchanger 208 will now be described with reference to
In the system and method of
Optionally, the feed gas may be heated before the expander 212 via a heating device 222 to increase the energy recovered by the expander, and therefore, provide additional compression power. The heating device may be a heat exchanger or any other heating device known in the art.
As in the embodiment of
The temperature of the mixed refrigerant can be controlled by controlling the boiling pressure of the mixed refrigerant.
The removed components, after traveling through a freezing components outlet in the scrub column bottom, may be returned to the heat exchanger 216 to recover cold refrigeration via line 234 and then sent to additional separation steps such as a condensate stripping system 238 via line 236 as shown in
The feed gas stream, with freezing components removed, 244 is then sent to the main heat exchanger 208 of the liquefaction system, after being compressed in the compressor 214 of the expander/compressor. If additional compression is required, the expander/compressor may be replaced with a compander which can be fitted with the expander, additional compression stages if needed and another driver such as an electric motor 246 or steam turbine, etc. Another option is to simply add a booster compressor in series with the compressor driven by the expander. In all cases, the increased feed gas pressure lowers the energy required for liquefaction and improves liquefaction efficiency, which in turn, can increase liquefaction capacity.
An alternative embodiment of a system and method for removing freezing components from the feed gas stream before liquefaction in the main heat exchanger will now be described with reference to
As shown in
The exit stream 316 is then reduced in pressure via a JT valve 318, or other expansion device known in the art, and the scrub column inlet stream 320, which is primarily vapor, is fed to the bottom portion of a scrub column 322, which may be a column, drum or other scrub or stripping device known in the art. A reflux separation device 324, which may be a drum, column or other separation device known in the art, along with the scrub column 322 forms the scrub device of the system.
A stream 326 optionally branches off of stream 316 and be directed to secondary feed cooling passage 328 of the heat exchanger 312 for additional cooling. As a result, a secondary feed stream 332 is formed and delivered to the scrub column 322.
As illustrated in
A temperature sensor 342 monitors and compares the temperature of secondary feed stream 332 with a set point temperature and opens compensation valve 344 to divert some of the flow in bypass line 338 to secondary feed stream 332 to raise the temperature of stream 332 if it is below the set point. Conversely, valve 344 may be closed (or partially closed) if the temperature detected by sensor 342 is above the set point.
Stream 320 enters the bottom of the scrub column 322. The vapor from stream 320 rises within the column and encounters primary and secondary reflux liquid streams 352 and 372 so that the freezing components are condensed. The resulting liquid drops to the bottom of the scrub column 322 and is removed as stream 354. The components removed from the bottom of the scrub column 322 via stream 354 are sent to additional separation steps such as a condensate stripping system, fuel or other disposal methods. The components removed from the bottom of the scrub column as stream 354 may also be returned to the heat exchanger 322 to recover refrigeration, as illustrated for the systems of
Refrigeration required to reflux the column 322 via reflux streams 352 and 372 is provided by the return vapor 356 from the reflux separation device 324, which is warmed in passage 357 of the heat exchanger 312. More specifically, a stream 358 exits the top of the scrub column 322 and is cooled in the heat exchanger 312. While preferably all vapor, stream 358 contains components that liquefy at a higher temperature (as compared to the vapor stream 356 exiting the top of the scrub device 324). As a result, the stream 362 entering the reflux separation device 324, after passing through passage 360 of the heat exchanger 312, is two-phase. Stream 362 is separated into vapor and liquid components within the reflux separation device 324, with the liquid components exiting the device as liquid stream 364. This stream may be pumped via pump 366 and an associated reflux liquid component line, including a reflux liquid component passage, to the top of the scrub column 322 as primary reflux stream 352.
After entering the scrub column 322 the primary reflux stream 352 refluxes vapor in the top portion of the column. A secondary reflux stream, also for refluxing or condensing vapor in the column, may flow through a secondary reflux liquid distribution passage that may include, as examples only, a secondary reflux line 372 that may be external or internal to the scrub device or a downcomer or other internal liquid distribution device within the scrub column 322.
As noted above, the return vapor 356 exiting the top of reflux separation device 324, thus exiting the scrub device of the system, is warmed in passage 357 of the heat exchanger 312 so as to provide refrigeration for passages 308, 328 and 360. As illustrated in
The warm gas stream 378 exiting the heat exchanger 146, with freezing components removed, may then sent to the liquefier via lines 382 (illustrated in phantom) and 384.
As described above, the system of
In an alternative embodiment, a second stage of compression of the gas exiting compressor 388 may be provided, as indicated in phantom block 394. Lines 382 and 392 may be omitted in this embodiment. The gas exiting the compressor 388 travels to second stage compressor 396 and is compressed, with the resulting stream being cooled in cooling device 398, which may, as examples only, utilize ambient air cooling or liquid cooling. The resulting stream 402 is sent to the main liquefaction heat exchanger via line 384.
While the preferred embodiments of the invention have been shown and described, it will be apparent to those skilled in the art that changes and modifications may be made therein without departing from the spirit of the invention, the scope of which is defined by the appended claims.
This application is a continuation of prior U.S. application Ser. No. 16/297,971, filed Mar. 11, 2019, which is a continuation-in-part of prior U.S. application Ser. No. 15/702,271, filed Sep. 12, 2017, which is a continuation application of prior U.S. application Ser. No. 15/095,631, filed Apr. 11, 2016, now U.S. Pat. No. 10,060,671, which claims the benefit of U.S. Provisional Application No. 62/145,929, filed Apr. 10, 2015, and U.S. Provisional Application No. 62/215,511, filed Sep. 8, 2015, the contents of each of which are hereby incorporated by reference.
Number | Date | Country | |
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62145929 | Apr 2015 | US | |
62215511 | Sep 2015 | US |
Number | Date | Country | |
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Parent | 16297971 | Mar 2019 | US |
Child | 16843508 | US | |
Parent | 15095631 | Apr 2016 | US |
Child | 15702271 | US |
Number | Date | Country | |
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Parent | 15702271 | Sep 2017 | US |
Child | 16297971 | US |