The present invention relates to the sphere of natural gas liquefaction.
Natural gas is often produced far away from the sites where it is intended to be used. A method used for transporting it consists in liquefying the natural gas around −160° C. and in transporting it by ship in liquid form at atmospheric pressure.
Prior to being liquefied, the natural gas has to undergo various treatments in order, on the one hand, to adjust its composition with a view to sale (sulfur and carbon dioxide content, calorific value) and, on the other hand, to allow liquefaction thereof. In particular, natural gas fractionation carried out by distillation allows to remove the heavier hydrocarbons likely to clog, through crystallization, the lines and the heat exchangers of the liquefaction plant. Furthermore, fractionation by distillation allows to separately recover compounds such as ethane, propane or butane that can be upgraded separately, for example for sale or as cooling fluids used in the liquefaction process.
Liquefaction is generally carried out at a pressure approximately equal to the operating pressure of the fractionating column.
The present invention aims to modify the fractionation stage by increasing the fractionation operating pressure and, consequently, by increasing the pressure at which the natural gas is liquefied so as to improve the overall efficiency of the liquefaction method.
In general terms, the invention defines a natural gas liquefaction method wherein the following stages are carried out:
a) cooling the natural gas,
b) feeding the cooled natural gas into a fractionating column so as to separate a methane-rich gas phase and a liquid phase rich in compounds heavier than ethane,
c) withdrawing said liquid phase at the bottom of the fractionating column and discharging said gas phase at the top of the separation column,
d) partly liquefying said gas phase so as to produce a condensate and a gas stream, said condensate being recycled to the top of the fractionating column as reflux,
e) liquefying said gas stream,
and wherein the operating conditions in the fractionating column are so selected that said liquid phase comprises a molar proportion of methane ranging between 10% and 150% of the molar proportion of ethane in said phase.
According to the invention, the operating conditions in the fractionating column can be so selected that said liquid phase comprises a molar proportion of methane ranging between 40% and 70% of the molar proportion of ethane. The molar proportion of methane of said liquid phase can be adjusted by modifying the power of a reboiler arranged in the bottom of the fractionating column.
According to the invention, the following stages can also be carried out
f) feeding said liquid phase into a separation column to separate a methane-rich gas fraction and a liquid fraction comprising hydrocarbons heavier than ethane,
g) withdrawing a liquid portion from the separation column,
h) extracting from said liquid portion a liquid stream comprising more than 95% by mole of ethane.
In stage g), the liquid portion can be withdrawn at a level located between the supply point and the top of the separation column.
In stage h), part of said liquid portion can be vaporized so as to obtain said liquid stream comprising more than 95% by mole of ethane, said vaporized part being fed into the separation column.
A liquid reflux can be fed into the top of the separation column at a temperature ranging between −10° C. and −40° C.
In stage a), the natural gas can be cooled by heat exchange with a cooling fluid circulating in a cooling circuit and said methane-rich gas fraction obtained in stage f) can be partly condensed by heat exchange with a portion of said cooling fluid, so as to obtain said liquid reflux fed to the top of the separation column.
The cooling fluid portion can be subcooled by heat exchange with a liquid withdrawn from the fractionating column.
In stage e), the gas stream can be cooled by heat exchange at a pressure above 50 bars.
Other features and advantages of the invention will be clear from reading the description hereafter, with reference to the accompanying figures wherein:
In
The natural gas partly liquefied in E1 is fed through line 1 into fractionating column 2, rebelled by means of heat exchanger 9. The vapour discharged at the top of column 2 through line 3 is partly condensed in heat exchanger E1 prior to being fed into reflux drum 4.
The gas fraction discharged at the top of drum 4 is sent through line 5 to heat exchanger E2 to be liquefied. The liquid natural gas is discharged from E2 through line 5′. In E2, cooling is carried out by means of closed cooling circuit 200 that works by compression and expansion of a cooling fluid, consisting for example of a mixture of nitrogen, of methane and of ethane.
The liquid obtained at the bottom of drum 4 is fed through pump 6 and line 7 to the top of column 2 as reflux. The liquid obtained in the bottom of column 2 is discharged through line 8.
The liquid obtained in the bottom of column 2 through line 8 is cooled in exchanger 10, for example by water or air, then expanded in expansion device V. The cooled and expanded liquid is fed into deethanization column 11, reboiled by heat exchanger 16. In general, column 11 works at a pressure ranging between 20 and 35 bars. The gas fraction obtained at the top of column 11 is partly condensed at a temperature ranging between 0° C. and 10° C. in heat exchanger 12, by heat exchange with a portion of a liquid withdrawn laterally from column 2.
The condensates are separated from the gas phase in drum 13. The gas phase discharged at the top of drum 13 mainly consists of methane and ethane. It can be sent to the fuel gas network or to liquefaction through line 5. The condensates collected in the bottom of separation drum 13 are sent, at a temperature preferably ranging between 0° C. and 10° C., through pump 14, to the top of column 11 as reflux. A fraction of the condensates that mainly consist of ethane is withdrawn through line 30 to be used for example in the composition of the cooling fluids circulating in circuits 100 or 200.
The hydrocarbons heavier than methane are discharged in liquid form at the bottom of column 11 through fine 17.
According to the invention, in connection with
Sending a substantial amount of methane to the bottom of column 2 allows to have a lower specific mass of vapour for an identical pressure, and therefore a higher specific mass ratio. Consequently, sending a substantial amount of methane to the bottom of column 2 according to the invention allows to achieve liquefaction at a higher pressure, which reduces the power required for liquefaction.
According to the invention, considering that the liquid discharged at the bottom of column 2 comprises a substantial amount of methane, particular operating conditions are applied to separation column 11. Column 11 can be a distillation column equipped with trays. A relatively low temperature, preferably ranging between −10° C. and −40° C., can be applied at the top of column 11 so as to improve separation between the methane and the hydrocarbons heavier than ethane. In connection with
A portion of the cooling fluid of first cooling circuit 100 can be used for low-temperature cooling in exchanger 12. In connection with
According to the invention, in connection with
A liquid enriched in hydrocarbons heavier than ethane that can be sent through line 17 to a depropanization column is discharged at the bottom of column 11. A propane-enriched cut that can be used for making up the cooling mixtures used in circuits 100 and 200 can thus be extracted.
The numerical examples given hereafter allow to illustrate the operating mode of the method according to the invention.
The scheme illustrated by
The pretreated and dried natural gas circulates in line 1′ at a flow rate of 35,000 kmol/h, with the following composition:
The gas is cooled in E1 to a temperature of −30° C., than fed into fractionating column 2.
Distillation of the gas in column 2 requires remaining sufficiently below the critical conditions. A criterion commonly used by the person skilled in the art is that the ratio of the specific masses of the liquid and vapour phases in the bottom of column 2 must remain above a certain value to be able to operate. Values between 3 and 6 are used by the person skilled in the art. A value of 4.5 is used in Example 1.
Column 2 works at 40.5 bars, condenser 4 at −60° C., and the C1/C2 ratio in the bottom of column 2 is 1%.
Under such conditions, a specific mass of liquid of 404.8 kg/m3 and a specific mass of vapour of 88.95 kg/m3 are obtained in the bottom of column 2. Thus, the ratio of the specific masses of the liquid and vapour phases in the bottom of column 2 is 4.55.
Liquefaction is thus carried out in E2 at a pressure of 40 bars. For the whole liquefaction process, a total power of 162.4 MW is necessary for the compressors of the two cooling-mixture cycles.
In Example 1, deethanization column 11 comprises no lateral column. Furthermore, the stream obtained at the top of column 1 is cooled only by heat exchange with lateral withdrawal from fractionating column 2, and it does therefore not increase the refrigerating power required for operation of the process.
Scheme 2 according to the invention is carried out.
The composition and the flow rate of the gas to be treated are identical to those given in Example 1.
The gas is cooled in E1 to a temperature of −30° C., then fed into fractionating column 2.
Column 2 works at 53.5 bars, condenser 4 at −60° C., and the C1/C2 ratio in the bottom of column 2 is 55%.
Under such conditions, a specific mass of liquid of 405.6 kg/m3 and a specific mass of vapour of 87.7 kg/m3 are obtained in the bottom of column 2. Thus, the ratio of the specific masses of the liquid and vapour phases in the bottom of column 2 is 4.6.
Liquefaction is thus carried out in E2 at a pressure of 53 bars. For the whole liquefaction process, a total power of 148.3 MW is necessary for the compressors of the two cooling-mixture cycles, i.e. a gain of about 9% in relation to Example 1.
On the other hand, this efficiency gain involves difficulty in recovering an ethane-enriched stream necessary for the heat carrier makeup of cooling circuits 100 and 200. In fact, a simple distillation in separation column 11 allows to obtain, at the top, a mixture of C1 and C2 that can be used in second cooling cycle 200, but not in first cycle 100 that uses a mixture of C2 and C3. The invention aims to use in example 2 lateral stripping column 20.
The stream at the top of column 11 is cooled to a temperature of −20° C. by heat exchange with a portion of the heat-carrying fluid from first cooling circuit 100. Furthermore, the effluent discharged at the top of drum 13 has to be liquefied. These additional heat exchanges lead to an efficiency loss of about 1% in relation to Example 1.
Finally, the operating mode according to the invention of Example 2 is much more attractive than the operating mode of Example 1: it allows to save approximately 8% energy or to increase the liquefaction capacity by about 8% with the same gas turbines.
Number | Date | Country | Kind |
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07 07829 | Oct 2007 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FR2008/001462 | 10/17/2008 | WO | 00 | 10/26/2010 |
Publishing Document | Publishing Date | Country | Kind |
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WO2009/087308 | 7/16/2009 | WO | A |
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6662589 | Roberts et al. | Dec 2003 | B1 |
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Number | Date | Country | |
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20110048067 A1 | Mar 2011 | US |